JP3637607B2 - Air conditioner - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an air conditioner in which atomized water obtained by atomizing water is blown out, and the temperature of the blown air is lowered by the evaporation of the atomized water taking away latent heat in the air.
[0002]
[Prior art]
An air conditioner disclosed in Japanese Patent Laid-Open No. 6-115347 is known as a technique for lowering the blowing temperature with atomized water. This air conditioner is provided with a humidified air outlet that blows humidified air containing white fog around the cooling air outlet that blows out the cooling air, and the surrounding humidified air suppresses the temperature rise of the internal cooling air, Is given to the human body efficiently.
[0003]
[Problems to be solved by the invention]
Atomized water adheres to the inner wall of the humidified air passage through which the humidified air flows, and condensed water is generated. This condensed water grows to form water droplets, and then blows out from the outlet through the flow of humidified air. Water droplets blown out from the air outlet may wet the floor or reach the human body and cause discomfort.
[0004]
OBJECT OF THE INVENTION
This invention is made | formed in view of said situation, The objective is to provide the air conditioning apparatus which can blow out humidified air from which a water droplet is not blown off from a blower outlet.
[0005]
[Means for Solving the Problems]
The air conditioning apparatus of the present invention employs the following technical means.
[Means of Claim 1]
Air conditioner
(A) a blowing means for generating an air flow;
(B) atomizing means for generating atomized water obtained by atomizing water; (c) humidified air for blowing humidified air in which the atomized water generated by the atomizing means is mixed into the air flow generated by the blowing means. A passage,
(D) a normal air passage that blows out normal air in which the atomized water generated by the atomizing means is not mixed into the air flow generated by the air blowing means;
(E) It is arranged in the vicinity of the outlet of the normal wind passage and is arranged so as to be able to supply condensed water generated in the humidified air passage, and the supplied condensed water is supplied by the normal wind flowing through the normal wind passage. Evaporating material to evaporate ,
(F) The evaporating material (24) is disposed in the normal air passage (23), and
The passage area of the normal air passage (23) where the evaporating material (24) is arranged is larger than the passage area of the humidified air passage (22),
(G) The humidified air passage (22) and the normal air passage (23) are provided by a double duct (21) in which normal air in the normal air passage (23) flows around the humidified air passage (22). becomes, outlet of the double duct (21) is humidified air from the central portion is blown, which usually air from the surroundings is blown out,
(H) The double duct (21) includes the normal air passage (23) and the humidified air passage (22) extending in the axial direction in the normal air passage (23). The humid air is blown out from the part and the normal air is blown out from the surroundings.
(I) A plurality of the evaporating materials (24) are arranged in the normal air passage (23), and the plurality of evaporating materials (24) are plate-shaped having excellent water absorption and evaporating properties. It is arranged radially between the normal air passage (23) and the humidified air passage (22),
(J) The plurality of evaporating materials (24) communicate with the inside of the humidified air passage (22), and condensed water is supplied from the inside of the humidified air passage (22) to the evaporating material (24). Features.
[0006]
[Means of claim 2]
The air conditioner of claim 1,
In the humidified air passage (22), a plurality of notches (25) communicating with the inside of the normal air passage (23) are formed,
The evaporating material (24) is disposed in each notch (25), and the evaporating material (24) communicates with the inside of the humidified air passage (22), so that the inside of the humidified air passage (22). Condensed water is supplied to the evaporating material (24).
[0007]
[Means of claim 3]
In the air conditioning apparatus of Claim 1 or Claim 2 ,
The humidified air passage (22) and the evaporating material (24) are integrally formed of a material having excellent water absorption and evaporating properties.
[0008]
[Means of claim 4]
In the air conditioning apparatus of Claim 3,
The double duct has flexibility.
[0009]
[Means of claim 5]
The air conditioner according to claim 4,
At least the normal air passage of the double duct is provided so that air cooled by a cooling means for cooling air can be supplied.
[0010]
[Operation and effect of the invention]
[Operation and effect of claim 1]
When the blower is activated and the atomizing means is activated, the humidified air containing the atomized water is blown out from the humidified air passage, and the normal wind containing no atomized water is blown out from the normal air passage. The
The atomized water in the humidified air mixed in the humidified air takes heat away from the surrounding wind and evaporates, and the wind is deprived of latent heat and becomes cold.
[0011]
Since air containing atomized water flows in the cooling air passage, the atomized water may condense on the inner wall of the humidified air passage, and the condensed water may be guided to the outlet by the flow of the humidified air. The condensed water led to the vicinity of the outlet is supplied to the evaporating material arranged near the outlet of the normal wind passage. The condensed water supplied to the evaporating material is evaporated by the normal wind blown from the normal wind passage.
[0012]
In this way, the dew condensation water generated in the humidified air passage is supplied to the evaporating material and evaporated by the normal wind, so that the dew condensation water is not blown out from the outlet. For this reason, it is prevented that the condensed water wets the floor or the condensed water adheres to the human body, and the user is not uncomfortable.
In addition, since condensed water takes latent heat from normal wind when it evaporates from an evaporating material, the temperature of normal wind can be lowered | hung and a user's cold wind feeling can be increased.
[0013]
Place the steam Hatsuzai within the normal air passage, usually by greater than the passage area of the humidifying air passage a passage area of the air passage, it is possible to increase the area of the evaporation material. Thus, by increasing the area of the evaporating material, the contact area between the evaporating material and the normal wind is increased, and the amount of condensation water evaporated by the evaporating material can be increased.
[0014]
The humidified air is blown out from the central part of the double duct, and the humidified air is blown out in a state covered with the normal air by blowing out the normal air from the surroundings. Accordingly, it is possible to prevent the humid air having a low temperature from diffusing to the surroundings before reaching the distant place, and the humid air having a low temperature can efficiently reach the far place.
[Operation and effect of claim 3]
The humidified air passage (22) and the evaporating material (24) are integrally formed of a material excellent in water absorption and evaporability, so that the dew condensation water generated in the humidified air passage (22) is surely supplied to the humidified air passage ( 22) and the evaporating material (24) and is evaporated by the normal wind flowing through the normal wind passage (23).
[0015]
[Operation and effect of claim 4]
By making the double duct constituting the humidified air passage and the normal air passage flexible, the direction of the blown air blown out from the air outlet can be changed according to the user's preference, and it is easy to use. .
[0016]
[Operation and effect of claim 5]
By cooling the cool air cooled by the cooling means from at least the normal air passage, the cooling capacity of the air conditioner is increased by the cool air blown from the humid air passage and the cold air blown from the normal air passage. can do.
[0017]
【Example】
Next, the air conditioning apparatus of the present invention will be described based on the embodiments shown in the drawings.
[Configuration of the first embodiment]
1 to 8 show a first embodiment in which the present invention is applied to a stationary spot cooler, and FIG. 1 is a sectional view of the spot cooler.
The spot chiller 1 according to the present embodiment gives a cool spot to a user, and is roughly classified into a refrigeration cycle 3 provided with an evaporator 2 (corresponding to a cooling means) for cooling air sent to the user. Atomization means 4 for atomizing water to generate atomized water, a blowout air passage 6 for sending air that has passed through the evaporator 2 from the blowout port 5 to the user, and a condenser 7 of the refrigeration cycle 3 A discharge air passage 8 that discharges air from a discharge port (not shown) different from that of the user and an air flow that sends the air that has passed through the evaporator 2 in the blowout air passage 6 to the user are generated. Generated in the evaporator 2, the air blowing means 9 for generating an air flow for sending the air passing through the condenser 7 to the discharge port, the water tank (not shown) for supplying water to the atomizing means 4, and the evaporator 2. A drain tank 10 for storing the drain water is constituted from a control device (not shown) for energizing controlling each electric functional component.
[0018]
The refrigeration cycle 3 includes a compressor 12 for sucking, compressing and discharging refrigerant, a condenser 7 for condensing and liquefying high-temperature and high-pressure gas refrigerant discharged from the compressor 12, and an expansion valve (not shown) for decompressing and expanding the liquefied refrigerant liquefied by the capacitor 7 The evaporator 12 is composed of an evaporator 2 that removes latent heat from the air to evaporate the refrigerant atomized by the expansion valve and is connected to each other by a refrigerant pipe (not shown). The compressor 12 is, for example, an electric motor (not shown) Driven by rotation.
[0019]
The air blowing means 9 is a double-shaft fan, a motor 13 that rotates the shaft when energized, a centrifugal evaporator fan 14 attached to each shaft protruding on both sides of the motor 13, and an axial-flow condenser fan 15. Consists of When the evaporator fan 14 is driven to rotate, an air flow is generated in the blown air passage 6 and the air that has passed through the evaporator 2 is blown out from the blowout port 5. At this time, the condenser fan 15 is also rotationally driven, an air flow is generated in the discharge air passage 8, and the air that has passed through the condenser 7 is discharged from the discharge port.
[0020]
The atomizing means 4 of the present embodiment includes a water receiving tank 16 in which water is supplied from a water tank of a predetermined capacity and the water level is kept substantially constant, and a focus is set near the liquid surface of the water receiving water tank 16. Thus, an ultrasonic transducer 17 that generates ultrasonic waves is provided. The ultrasonic vibrator 17 is an electrostrictive vibrator in which electrodes are baked on both surfaces of, for example, a barium titanate-based piezoelectric element, and an electric signal from an ultrasonic wave generation circuit 20 disposed below the ultrasonic vibrator 17. A thin circular plate that generates supersonic vibration.
[0021]
The blowout air passage 6 includes a double duct 21 that directs the air flow generated by the rotation of the evaporator fan 14 toward the user on the downstream side, and the air outlet 6 at the downstream end of the double duct 21 faces the user. Airflow is blown out.
The inside of the double duct 21 is a humidified air passage 22 to which the air flow generated by the rotation of the evaporator fan 14 is guided and the atomized water generated by the atomizing means 4 is supplied. The air flow generated by the rotation of the evaporator fan 14 is guided, and the normal air passage 23 is supplied with no atomized water.
[0022]
Here, the reason why the humid air is blown out from the inner humid air passage 22 and the normal air is blown out from the outer normal air passage 23 will be described.
First, in contrast to the present embodiment, when normal air is blown out from the central portion and humidified air is blown out from the surrounding area (peripheral blowing type), the humidifying air diffuses from the blowout port 5 to the user. Cooling capacity by humidified air is very low. Further, even when the humidified air passage 22 is not distinguished from the normal air passage 23 and air containing humidified air is blown out from the common air outlet 5 (mixed air outlet type), the air outlet is not as large as the surrounding air outlet type. Part of the humidified air diffuses from 5 to the user, and the cooling capacity by the humidified air is low.
[0023]
On the other hand, as employed in the present embodiment, when the humidified air is blown out from the center and the normal air is blown out from the surroundings (center blowing type), the air around the humidified air is also directed to the user. Compared to other blowing types, the reachability of cooling air is the best, and the cooling capacity by humidified air is high.
Therefore, in this embodiment, a central blowing type having excellent cooling capability (reachability of cooling air) by humidified air is employed.
[0024]
As shown in FIGS. 2 to 6, the air outlet 23 of the double duct 21 absorbs condensed water in the humidified air passage 22 through the normal air passage 23 and communicates with the outlet end side of the humidified air passage 22. A plurality of evaporating materials 24 are arranged radially. The evaporating material 24 is a flat plate that is strong and has excellent water absorption and evaporating properties, such as non-woven fabric and water-resistant cardboard. The inner lower portion is inserted into a cutout portion 25 formed on the outlet end side of the humidified air passage 22. As a result, the evaporating material 24 communicates with the inside of the humidified air passage 22, and condensed water in the humidified air passage 22 is supplied to and absorbed by the evaporating material 24. The evaporating material 24 is held by a side guide 26 formed around the humidified air passage 22 along the flow direction of the wind, and from the outlet 5 side to the inside of the blowing ring 27 attached to the normal air passage 23. The end guide 28 formed is held radially between the humidified air passage 22 and the normal air passage 23.
[0025]
The control device of the present embodiment is an operation mode signal that can be set by the user for either the air blowing operation, only the cooling operation by the refrigeration cycle 3, only the humidified cold air operation by the atomizing means 4, or the cooling operation + humidified cold air operation. Spot cold wind is inputted by inputting a set temperature signal set by a user, an air volume setting signal set by a user, a suction temperature signal of a suction temperature sensor (not shown) for detecting the temperature of air sucked into the evaporator 2, and the like It controls energization of each electrical functional component of the machine 1 (for example, an electric motor that drives the compressor 12, a motor 13 that operates the air blowing means 9, an ultrasonic generation circuit 20 that operates the ultrasonic vibrator 17, etc.). .
[0026]
The control device includes a refrigeration cycle only when the temperature of the air sucked into the evaporator 2 is equal to or higher than the set temperature set by the user when the user selects both the cooling operation and the humidified cold air operation. The temperature control means for operating 3 is provided.
[0027]
The operation of this temperature control means will be described with reference to the flowchart of FIG.
During operation (start), it is determined whether or not the operation mode signal operated by the user is cooling operation + humidified cold air operation (step S1). If the determination result is YES, it is determined whether or not the suction temperature of the air sucked into the evaporator 2 is equal to or higher than the set temperature (step S2).
[0028]
If the determination result in step S2 is YES, the electric motor for driving the compressor 12, the motor 13 for operating the air blowing means 9, and the ultrasonic wave generating circuit 20 for operating the ultrasonic vibrator 17 are all turned on, and the cooling operation + The humidified cold air operation is performed (step S3), and then the process returns.
On the other hand, if the judgment result in step S2 is NO, the motor 13 that operates the air blowing means 9 and the ultrasonic wave generation circuit 20 that operates the ultrasonic vibrator 17 are turned ON, and the electric motor that drives the compressor 12 is OFF. Then, only the humidified cold air operation is performed (step S4), and then the process returns.
[0029]
[Operation of Example]
(Description of the operation of the spot cooler 1)
Next, the simultaneous operation of the cooling operation and the humidified cold air operation will be described. In the simultaneous operation of the cooling operation and the humidified cold air operation, the electric motor that drives the compressor 12, the motor 13 that operates the air blowing means 9, and the ultrasonic wave generation circuit 20 that operates the ultrasonic vibrator 17 all operate. It is.
[0030]
By operating the refrigeration cycle 3, a low-temperature and low-pressure mist refrigerant is supplied into the evaporator 2, and the mist refrigerant in the evaporator 2 evaporates by taking latent heat from the air passing through the evaporator 2. For this reason, the air flow generated by the evaporator fan 14 of the air blowing means 9 is cooled to cool air when passing through the evaporator 2.
The cold air that has passed through the evaporator 2 flows in the blown air passage 6 and is divided into the humidified air passage 22 and the normal air passage 23.
[0031]
The cold air flowing through the humidified air passage 22 is supplied with atomized water from the atomizing means 4 to become humidified air, and is blown out from the center of the double duct 21. Further, the cold air flowing through the normal air passage 23 is blown out from the normal air passage 23 around the humidified air passage 22 as the cold air (normal air) without being supplied with the atomized water. That is, humid air based on cold air is blown out from the center of the air outlet 5, and cold air (normal air) is blown out from the surroundings toward the user.
[0032]
Since the atomized water contained in the humidified air evaporates by taking latent heat from the cold wind that flows with the atomized water, the temperature of the humidified air decreases. Then, the humidified air whose temperature has been lowered is covered with cold air (normal air) and blown out in a spot-like manner toward the user, so that the low-temperature humidified air is prevented from diffusing around before reaching the user. The humidified air with low temperature is delivered to the user. Thereby, a high cold wind feeling can be given to a user.
[0033]
This will be described with reference to FIG. The solid line A in FIG. 8 shows the relationship between the temperature reached by the user's cold air and the distance between the outlet 5 and the user only in the cooling operation of the refrigeration cycle 3, and the solid line B in FIG. The relationship between the temperature reached by the user's cold air and the distance between the air outlet 5 and the user in the + humidified cold air operation is shown.
As is apparent from this graph, by performing the humidified cool air operation together with the cooling operation, a temperature difference that cannot be obtained in the cooling operation can be given to the user. The data in FIG. 8 is the result of an experiment conducted under the conditions of a measurement environment temperature of 20 ° C. and a measurement environment humidity of 60%.
[0034]
In addition, by increasing or decreasing the atomization amount by the atomization means 4, it becomes possible to adjust the reach distance of the atomized water (white mist), and it is possible to create cold air that matches the distance to the user. As an example of the means for increasing / decreasing the amount of atomization, there are means for increasing / decreasing the number of ultrasonic transducers 17 used, means for adjusting the output of the ultrasonic transducer 17, and the like. You may employ | adopt in an Example.
[0035]
(Explanation of the action of the evaporating material 24)
Next, the operation of the evaporating material 24 will be described.
Since the humidified air containing the atomized water flows in the humidified air passage 22 of the double duct 21, the atomized water comes into contact with the inner wall of the humidified air passage 22, and condensed water adheres in the humidified air passage 22. When the condensed water grows, the grown condensed water (water droplets) tends to blow out from the outlet 5 by the wind flowing through the humidified air passage 22.
[0036]
However, the dew condensation water that travels in the humidified air passage 22 toward the outlet 5 is supplied and absorbed from the notch 25 of the humidified air passage 22 to the evaporating material 24, as shown by the arrows in FIG. The condensed water absorbed by the evaporating material 24 evaporates by the normal wind flowing in the normal wind passage 23 and is blown out toward the user together with the normal wind.
[0037]
[Effects of Examples]
In this embodiment, as shown by the action of the evaporating material 24, the condensed water generated in the humidifying air passage 22 is absorbed by the evaporating material 24 and evaporates by normal air flowing through the normal air passage 23. Condensed water adhering to the air passage 22 is not blown out from the humidified air passage 22. Thus, since dew condensation water is not blown out from the blower outlet 5, dew condensation water does not wet a floor, or dew condensation water adheres to a user and does not give a user discomfort.
Further, when the condensed water evaporates from the evaporating material 24, the condensed water takes the latent heat from the normal wind and evaporates, so that the effect of lowering the temperature of the normal wind is also achieved.
[0038]
Here, although the spot cold air fan conventionally used was two modes, the air blowing operation and the air cooling operation, the spot air cooler 1 of the present embodiment uses the humidifying cold air means, In addition to the two modes of cooling operation, two modes of humidified cold air operation and cooling operation + humidified cold air operation were added.
For this reason, as shown by the action of the spot cooler 1, the cool air can reach far away workers by the cooling operation + humidified cool air operation.
[0039]
Moreover, only humidification cold wind operation can be performed and a cool wind can be given to an operator. Since the cold wind operation using only the humidified cold wind operation requires much less energy than the cooling operation, the cold wind operation can be performed with low power consumption. In addition, the cold air operation by only the humidified cold air operation has a lower cooling degree than the cold air by only the air cooling operation, so that it is possible to prevent overcooling.
As described above, the spot chiller 1 according to the present embodiment is very easy to use because the degree of cooling by the cold air can be widely selected.
[0040]
[Second Embodiment]
FIG. 9 is a cross-sectional view of the main part of a suspended spot cool air cooler 1 showing a second embodiment. The spot chiller 1 according to this embodiment is configured such that a main body 30 including a refrigeration cycle 3 and an air blowing unit 9 is installed or suspended on a lower surface of a ceiling, and in the middle of a blowing air passage 6 extending downward from the main body 30 The conversion means 4 is provided.
[0041]
The humidified air passage 22 of the present embodiment guides the atomized water generated upward by the atomizing means 4 once in the horizontal direction, and then guides it to the lower outlet 5, and humidifies downward from the horizontal direction. At a location where the direction of the wind is changed, a function 31 is raised so that the condensed water condensed in the humidified air passage 22 in the horizontal direction does not enter the humidified air passage 22 in the downward direction.
[0042]
As a means for supplying water to the water receiving tank 16 of the atomizing means 4, a water tank 32 for supplying water by the user may be used as shown in FIG. 10, or as shown in FIG. When the water level in the water tank 16 is detected by the water level sensor 33 and the water level detected by the water level sensor 33 falls below a predetermined water level, the control device 34 opens the electromagnetic valve 36 provided in the water supply 35 to receive water. You may provide so that the water level in the water tank 16 may be recovered to a predetermined water level.
[0043]
In the case where the water replenishing means using the water tank 32 shown in FIG. 10 is adopted, drain water generated by an evaporator (not shown) in the main body 30 may be provided so as to be supplied into the water tank 32. When water supply means using the water supply 35 shown in FIG. 11 is adopted, a pipe (water supply 35) is provided for leading drain water generated by an evaporator (not shown) in the main body 30 to the water receiving tank 16. The pipe may be provided so as to be opened and closed by the electromagnetic valve 36.
[0044]
[Third embodiment]
FIG. 12 is a cross-sectional view of a suspended humidifying cooler showing a third embodiment.
The present embodiment is a hanging type humidifying cooler 40 that eliminates the refrigeration cycle and includes only the blowing air passage 6 including the air blowing means 9, the atomizing means 4, the humidified air passage 22, and the normal air passage 23.
Since this humidification cool air fan 40 is not equipped with a refrigeration cycle, it can be very miniaturized, and cool air is blown out quickly compared to the operation of the refrigeration cycle, and power consumption can be reduced.
For this reason, it is very suitable as a spot cold air blower for people such as toilets, washrooms and telephone boxes.
[0045]
[Fourth embodiment]
FIG. 13 is a cross-sectional view of the main part of the double duct 21 showing the fourth embodiment.
The humidified air passage 22 of the present embodiment uses a flexible rubber hose 41 that can be deformed in a direction perpendicular to the flow direction of the humidified air. The rubber hose 41 constituting the humidified air passage 22 has a smooth inner peripheral surface at least. The normal air passage 23 uses a bellows-shaped resin flexible duct 42 that can be deformed in a direction perpendicular to the flow direction of the room temperature air and that maintains the deformed state.
[0046]
As in this embodiment, by forming the humidified air passage 22 using the rubber hose 41 and the normal air passage 23 using the flexible duct 42, the blowing direction of the normal air and the humidified air blown from the air outlet 5 can be changed. Can do. That is, by adopting the present embodiment, the blowing direction of the humidified air and the normal wind can be changed depending on the position and preference of the user.
Further, in this embodiment, since the inner peripheral surface of the rubber hose 41 is smooth, the dew condensation water generated in the humidified air passage 22 can be suppressed as compared with the case where the rubber hose 41 is replaced with a flexible duct. .
[0047]
[Fifth embodiment]
FIG. 14 is a schematic cross-sectional view of a vehicle air conditioner 50 showing a fifth embodiment.
In the present embodiment, the atomizing means 4 is mounted on the vehicle air conditioner 50 mounted on the vehicle, and the humidified air is blown out from the center of the air outlet 5 (for example, the face air outlet) of the air conditioning duct 51. is there. The atomizing means 4 is preferably operated during rapid cooling, such as when the engine is started, particularly in summer, and gives the passenger a feeling of cold wind more quickly than the cooling action of the vehicle evaporator 2. Then, after the operation of the evaporator 2 is stabilized, the amount of atomization is controlled to control the humidity in the passenger compartment. In the figure, reference numeral 52 denotes a heater core, and the upstream door 53 is an outlet temperature adjusting means for adjusting the outlet temperature.
[0048]
[Sixth embodiment]
FIG. 15 is a cross-sectional view of the double duct 21 in the vicinity of the air outlet showing the sixth embodiment.
In the above embodiment, the example in which the evaporating material 24 is formed in a flat plate shape is shown. However, the evaporating material 24 of the present embodiment is formed in a circular arc shape in cross section so that the evaporation area of the evaporating material 24 is increased and condensed water is formed. The evaporation capacity is increased.
[0049]
[Seventh embodiment]
FIG. 16 is a perspective view of the humidified air passage 22 and the evaporating material 24 showing the seventh embodiment. In the above embodiment, the humidified air passage 22 and the evaporating material 24 in the vicinity of the air outlet are provided separately, and the evaporating material 24 is attached around the humidifying air passage 22. The humidified air passage 22 and the evaporating material 24 in the vicinity of the outlet are integrally formed of a strong material excellent in water absorption and evaporability. As a result, the dew condensation water generated in the humidified air passage 22 is reliably absorbed by the humidified air passage 22 and the evaporating material 24 and is evaporated by the normal wind flowing through the normal air passage.
[Brief description of the drawings]
FIG. 1 is a sectional view of a stationary spot cooler (first embodiment).
FIG. 2 is a front view of the air outlet (first embodiment).
FIG. 3 is a cross-sectional view taken along line AA in FIG. 2 (first embodiment).
4 is a cross-sectional view taken along the line BB in FIG. 2 (first embodiment).
FIG. 5 is a cross-sectional view taken along line XX of FIG. 3 (first embodiment).
6 is a cross-sectional view taken along line YY of FIG. 3 (first embodiment).
FIG. 7 is a flowchart showing the operation of the temperature control means (first embodiment).
FIG. 8 is a graph showing the relationship between the temperature reached by cold air and the distance to the user (first embodiment).
FIG. 9 is a cross-sectional view of a suspended spot cool air fan (second embodiment).
FIG. 10 is a cross-sectional view of a suspended spot cool air cooler that supplies water using a water tank (second embodiment).
FIG. 11 is a cross-sectional view of a suspended spot cool air cooler that supplies water using water (second embodiment).
FIG. 12 is a cross-sectional view of a hanging type humidifying cooler (third embodiment).
FIG. 13 is a sectional view of a double duct (fourth embodiment).
FIG. 14 is a sectional view of a vehicle air conditioner (fifth embodiment).
FIG. 15 is a sectional view of a double duct containing an evaporating material (sixth embodiment).
FIG. 16 is a perspective view of a humidified air passage and an evaporating material (seventh embodiment).
[Explanation of symbols]
1 Spot chiller (air conditioner)
2 Evaporator (cooling means)
4 Atomizing means 5 Air outlet 9 Air blowing means 21 Double duct 22 Humidified air passage 23 Normal air passage 24 Evaporating material to be evaporated

Claims (5)

(A) a blowing means for generating an air flow;
(B) atomizing means for generating atomized water obtained by atomizing water; (c) humidified air for blowing humidified air in which the atomized water generated by the atomizing means is mixed into the air flow generated by the blowing means. A passage,
(D) a normal air passage that blows out normal air in which the atomized water generated by the atomizing means is not mixed into the air flow generated by the air blowing means;
(E) It is arranged in the vicinity of the outlet of the normal wind passage and is arranged so as to be able to supply condensed water generated in the humidified air passage, and the supplied condensed water is supplied by the normal wind flowing through the normal wind passage. Evaporating material to evaporate ,
(F) The evaporating material (24) is disposed in the normal air passage (23), and
The passage area of the normal air passage (23) where the evaporating material (24) is arranged is larger than the passage area of the humidified air passage (22),
(G) The humidified air passage (22) and the normal air passage (23) are provided by a double duct (21) in which normal air in the normal air passage (23) flows around the humidified air passage (22). becomes, outlet of the double duct (21) is humidified air from the central portion is blown, which usually air from the surroundings is blown out,
(H) The double duct (21) includes the normal air passage (23) and the humidified air passage (22) extending in the axial direction in the normal air passage (23). The humid air is blown out from the part and the normal air is blown out from the surroundings.
(I) A plurality of the evaporating materials (24) are arranged in the normal air passage (23), and the plurality of evaporating materials (24) are plate-shaped having excellent water absorption and evaporating properties. It is arranged radially between the normal air passage (23) and the humidified air passage (22),
(J) The plurality of evaporating materials (24) communicate with the inside of the humidified air passage (22), and condensed water is supplied from the inside of the humidified air passage (22) to the evaporating material (24). An air conditioner characterized . The air conditioner of claim 1,
In the humidified air passage (22), a plurality of notches (25) communicating with the inside of the normal air passage (23) are formed,
The evaporating material (24) is arranged in each notch (25), and the evaporating material (24) communicates with the inside of the humidified air passage (22) so that the inside of the humidified air passage (22). Condensed water is supplied to the evaporating material (24) from the air conditioner. In the air conditioning apparatus of Claim 1 or Claim 2 ,
The air conditioning apparatus, wherein the humidified air passage (22) and the evaporating material (24) are integrally formed of a material having excellent water absorption and evaporating properties . In the air conditioning apparatus of Claim 3,
The air conditioner characterized in that the double duct has flexibility. The air conditioner according to claim 4,
An air conditioner characterized in that air cooled by a cooling means for cooling air is provided in at least the normal wind passage of the double duct.

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