JP2016188723A - Humidification air-conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidification air-conditioning system capable of humidifying locally.SOLUTION: A humidification air-conditioning system comprises: a mist generator 10 for generating a mist; a first fan body 6 for feeding air containing the mist generated by the mist generator, to an object space to be humidified; and a second fan body 7 for feeding air which does not contain the mist generated by the mist generator and has a temperature lower than that of the mist generated by the mist generator, upper than the air containing the mist generated by the mist generator.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a humidification air conditioning system.

  Patent document 1 discloses a humidification air-conditioning system. The humidification air-conditioning system sends warm air so as to prevent mist from spreading to positions other than the position where the user exists.

JP 2006-68130 A

  However, in the humidification air conditioning system, the air humidified by the mist rises with warm air. For this reason, it cannot humidify locally.

  The present invention has been made to solve the above-described problems. The objective of this invention is providing the humidification air conditioning system which can humidify locally.

  The humidifying air conditioning system according to the present invention includes a mist generating device that generates mist, a first blower that sends air containing mist generated by the mist generating device to a humidification target space, and the mist generating device generates the mist. And a second blower that sends air at a lower temperature than the mist generated by the mist generator without the mist generated above the air including the mist generated by the mist generator.

  According to these inventions, the second blower includes the mist generated by the mist generator that is lower in temperature than the mist generated by the mist generator without including the mist generated by the mist generator. Send it above the air. At this time, the rise of the air containing the mist generated by the mist generator is suppressed to cooler air. For this reason, the low position can be locally humidified.

It is a longitudinal cross-sectional view of the division area where the humidification air-conditioning system in Embodiment 1 of this invention was applied. It is a longitudinal cross-sectional view of the mist generator of the humidification air conditioning system in Embodiment 1 of this invention. It is a longitudinal cross-sectional view of the mist generating part of the humidification air conditioning system in Embodiment 1 of this invention. It is a longitudinal cross-sectional view of the division area where the humidification air-conditioning system in Embodiment 2 of this invention was applied. It is a longitudinal cross-sectional view of the division area where the humidification air-conditioning system in Embodiment 3 of this invention was applied. It is a longitudinal cross-sectional view of the division area where the humidification air-conditioning system in Embodiment 4 of this invention was applied. It is a longitudinal cross-sectional view of the division area where the humidification air-conditioning system in Embodiment 5 of this invention was applied.

  A mode for carrying out the invention will be described with reference to the accompanying drawings. In addition, the same code | symbol is attached | subjected to the part which is the same or it corresponds in each figure. The overlapping description of the part is appropriately simplified or omitted.

Embodiment 1 FIG.
FIG. 1 is a longitudinal sectional view of a partitioned area to which a humidifying air conditioning system according to Embodiment 1 of the present invention is applied.

  In FIG. 1, a partitioned area 1 is composed of a building room or the like. The partitioned area 1 includes a floor 2, a wall 3, and a ceiling 4.

  For example, the duct 5 is disposed along the upper side of the ceiling 4 and the outer side of the wall 3. The duct 5 may be embedded in the ceiling 4 and the wall 3. The duct 5 may be suspended from the ceiling 4.

  A part of the duct 5 forms a first blower 6. The first blower 6 penetrates the lower part of the wall 3 in the horizontal direction. The 1st ventilation body 6 has the 1st blower outlet 6a. The 1st blower outlet 6a is exposed in the lower part of the division area | region 1. FIG. The first air outlet 6a opens in the horizontal direction.

  A part of the duct 5 forms a second blower 7. The second blower 7 penetrates the upper part of the wall 3 in the horizontal direction. The 2nd ventilation body 7 has the 2nd blower outlet 7a. The 2nd blower outlet 7a is exposed in the upper part of the division area | region 1. FIG. The 2nd blower outlet 7a is arrange | positioned upwards rather than the 1st blower outlet 6a. The second outlet 7a opens in the horizontal direction.

  The blower 8 is arranged above the ceiling 4. The blower 8 is arranged on the most upstream side of the duct 5. The blower 8 is connected outdoors or to an air conditioner (not shown).

  The heating device 9 is arranged at the lower part outside the wall 3. The heating device 9 is disposed in the middle of the first blower 6. The mist generator 10 is disposed at the lower part outside the wall 3.

  The mist generator 10 is disposed at the lower part outside the wall 3. The mist generator 10 is disposed in the middle of the first blower 6. The mist generator 10 is adjacent to the heating device 9. The mist generating device 10 is disposed closer to the wall 3 than the heating device 9.

  The temperature measuring device 11 is arranged at the lower part of the partition region 1. For example, the temperature measuring device 11 is provided on the wall 3 on the opposite side to the wall 3 on the side of the first blower 6 and the second blower 7. For example, the temperature measuring device 11 is a thermistor.

  The input unit of the control device 12 is connected to the output unit of the temperature measuring device 11. The output unit of the control device 12 is connected to the input unit of the blower 8, the input unit of the heating device 9, and the input unit of the mist generator 10.

  The user of the partition area 1 exists in the lower part of the partition area 1. The space of the area is a humidification target space. When the humidification target space is humidified and heated, the control device 12 controls the blower device 8, the heating device 9, and the mist generating device 10 based on the temperature of the air measured by the temperature measuring device 11.

  As a result, the blower 8 sends air into the duct 5. Part of the air flows inside the first blower 6. Part of the air flows inside the second blower 7.

  The heating device 9 heats the air flowing inside the first blower 6. The mist generating device 10 generates mist from moisture contained in the air heated by the heating device 9. The 1st ventilation body 6 sends warm air containing the mist which the mist generator 10 generated toward the lower part of the humidification object space. The 1st blower outlet 6a blows off the said air toward the lower part of humidification object space.

  The 2nd ventilation body 7 sends the air sent from the air blower 8 toward the upper direction of humidification object space. The 2nd blower outlet 7a blows off air lower in temperature than the air containing the mist which the mist generating apparatus 10 generated without including the mist which the mist generating apparatus 10 generated toward the humidification object space.

  In the humidification target space, the air from the first air outlet 6a tends to rise due to buoyancy. On the other hand, the air from the second outlet 7a is less likely to rise at a lower temperature above the humidification target space. For this reason, the rise of the air from the 1st blower outlet 6a is suppressed by the air from the 2nd blower outlet 7a. As a result, the humid warm air remains in the humidification target space.

Next, an example of the mist generator 10 will be described with reference to FIG.
FIG. 2 is a longitudinal sectional view of the mist generator of the humidification air conditioning system according to Embodiment 1 of the present invention.

  FIG. 2A shows a heater-type mist generator 10. In FIG. 2A, the water tank 13 is provided directly below the first blower 6. The heater 14 is provided directly below the water tank 13.

  The water tank 13 is supplied with water from a supply device (not shown). The heater 14 heats the water tank 13. Due to the heating of the heater 14, the temperature of the water rises inside the water tank 13. As a result, water vapor is generated. The water vapor is cooled by the air flowing through the first blower 6. As a result, humid air and water droplet mist are generated. Part of the mist returns to the water tank 13.

  FIG. 2B shows the ultrasonic mist generator 10. In FIG. 2B, the water tank 13 is provided directly below the first blower 6. The ultrasonic transducer 15 is provided directly below the water tank 13.

  The water tank 13 is supplied with water from a supply device (not shown). The ultrasonic transducer 15 vibrates at a frequency corresponding to the wavelength of the ultrasonic wave. Due to the vibration of the ultrasonic vibrator 15, fine water droplets are sprayed from the inside of the water tank 13 to the inside of the first blower 6. The difference between the temperature of the water droplet and the temperature of the water inside the water tank 13 is small. The water droplet is vaporized by the air flowing through the first blower 6. As a result, slightly cooled air and mist are generated.

  FIG. 2C shows a spray-type mist generator 10. In FIG. 2C, the water tank 13 is provided directly below the first blower 6. The lower part of the rotating body 16 of the spraying device is disposed inside the water tank 13. The upper part of the rotating body 16 is exposed inside the first blower 6. The crushing and collecting plate 17 surrounds the upper part of the rotating body 16.

  The water tank 13 is supplied with water from a supply device (not shown). The rotating body 16 sucks up the water inside the water tank 13 to the upper part of the inner wall by centrifugal force. The upper part of the rotator 16 sprays water droplets outside through a hole (not shown) on the side surface. The crushing and collecting plate 17 receives a collision of water droplets sprayed on the rotating body 16. At this time, most of the water droplets fall into the water tank 13. Among the water droplets, a water droplet having a small particle diameter is vaporized by the air flowing inside the first blower 6. As a result, similar to the phenomenon in the ultrasonic mist generator 10, slightly cooled air and mist are generated.

  (D) of FIG. 2 shows the vaporization type mist generator 10. In FIG. 2D, the water tank 13 is provided directly below the first blower 6. The lower part of the filter 18 is disposed inside the water tank 13. The upper part of the filter 18 is exposed inside the first blower 6. The mist generating unit 19 is provided on the downstream side of the upper portion of the filter 18.

  The water tank 13 is supplied with water from a supply device (not shown). The filter 18 sucks up water in the water tank 13. The filter 18 allows the air flowing through the first blower 6 to pass through. At this time, a part of the water evaporates in the filter 18. As a result, humidified air is generated. The air contains moisture such that the relative humidity becomes 100%. The moisture is generally a water molecule. The water molecules are likely to diffuse. The mist generating unit 19 generates mist that is easily transported from water molecules contained in the humidified air.

  The vaporization mist generator 10 is preferably provided with a device for removing large water droplets. With this device, it is possible to prevent water from adhering to the inside of the first blower 6. The mist generator 10 preferably has a structure in which the pressure loss of the air flowing inside the first blower 6 is further reduced. With this structure, the air inside the first blower 6 can be sent smoothly.

Next, an example of the mist generating unit 19 will be described with reference to FIG.
FIG. 3 is a longitudinal sectional view of a mist generating portion of the humidifying air conditioning system according to Embodiment 1 of the present invention.

  FIG. 3A shows the discharge type mist generating unit 19. In FIG. 3A, the plurality of ground electrodes 20 and the plurality of high voltage electrodes 21 are alternately arranged in a direction perpendicular to the direction in which air flows inside the first blower 6. The plurality of ground electrodes 20 and the plurality of high voltage electrodes 21 are arranged so as to be parallel to the direction in which air flows inside the first blower 6. The ground side of the high-voltage power supply 22 is connected to a plurality of ground electrodes 20. The high voltage side of the high voltage power supply 22 is connected to a plurality of high voltage electrodes 21.

  A space between the adjacent ground electrode 20 and the high-voltage electrode 21 forms a discharge space. Most of the air inside the first blower 6 passes smoothly through the discharge space. At this time, the discharged electrons ionize at least one of water molecules and dust contained in the air. Water molecules aggregate by being attracted to ionized material. As a result, mist is generated.

  FIG. 3B shows an ultraviolet irradiation type mist generating unit 19. In FIG. 3B, the ultraviolet light source 23 is provided in the center of the inside of the first blower 6 in the direction orthogonal to the direction in which air flows inside the first blower 6. One of the reflecting plates 24 is provided on one side inside the first blower 6 in a direction orthogonal to the direction in which air flows inside the first sending body. The other of the reflection plates 24 is provided on the other side of the first blower 6 in the direction orthogonal to the direction in which air flows in the first blower 6.

  The ultraviolet light source 23 emits light. The light is reflected by the reflecting plate 24. The space between the ultraviolet light source 23 and the reflector 24 forms an ultraviolet irradiation space. When the wavelength of the light is a wavelength corresponding to energy higher than the work function of water molecules contained in the air, the water molecules emit electrons in the ultraviolet irradiation space. The water molecules are ionized. When the wavelength of the light is a wavelength corresponding to energy higher than the work function of the dust contained in the air, the dust emits electrons in the ultraviolet irradiation space. The dust is ionized. At this time, the water molecules are aggregated by being attracted to the ionized substance, similarly to the phenomenon in the discharge type mist generating section 19. As a result, mist is generated.

  In addition, you may provide the ultraviolet light source 23 in the one side inside the 1st ventilation body 6 in the direction orthogonal to the direction through which air flows in the inside of the 1st ventilation body 6. FIG. At this time, the reflecting plate 26 may be provided on the other side of the first blower 6 in the direction perpendicular to the direction of air flow inside the first blower 6. Again, water molecules aggregate by being attracted to the ionized material. As a result, mist is generated.

  FIG. 3C shows an ultrasonic irradiation type mist generator 19. 3C, the ultrasonic wave generation source 25 is provided on one side inside the first blower 6 in the direction perpendicular to the direction in which air flows inside the first blower 6. The reflection plate 26 is provided on the other side of the first blower 6 in the direction perpendicular to the direction in which air flows in the first blower 6.

  The ultrasonic wave generation source 25 vibrates at a frequency corresponding to the wavelength of the ultrasonic wave. As a result, ultrasonic waves are generated. The ultrasonic waves are reflected by the reflecting plate 26. The space between the ultrasonic wave generation source 25 and the reflection plate 26 forms an ultrasonic wave irradiation space. In the ultrasonic irradiation space, air density occurs. In the dense air portion, the density of water molecules is relatively high. The dust concentration is also relatively high. For this reason, water tends to aggregate in a portion where air is dense. As a result, mist is generated.

  Although not shown, mist may be generated from moisture contained in the humidified air by using the mist generating unit 19 that cools the air to make the temperature of the air below the dew point. A plurality of mist generating units 19 may be used. At this time, different types of mist generating units 19 may be used. In these cases, more appropriate mist can be generated in accordance with the required humidification amount.

  Note that even in a humidifier attached to an air conditioner (not shown), the humidified air contains moisture such that the relative humidity becomes 100%. The moisture is generally a water molecule. The water molecules are likely to diffuse. For this reason, you may apply these mist generating parts 19 with respect to the said humidification apparatus.

  According to Embodiment 1 demonstrated above, the 2nd ventilation body 7 does not contain the mist which the mist generator 10 generate | occur | produced, but mist generator is a mist generator lower than the mist which the mist generator 10 generated. 10 is sent above the air containing the mist generated. At this time, the rise of the air containing the mist generated by the mist generator 10 is suppressed to cooler air. For this reason, the low position can be locally humidified. Further, in winter, it is possible to suppress dew condensation in cold places such as the ceiling 4 and windows in the upper part of the partition region 1.

  The heating device 9 heats the air sent to the mist generating device 10. For this reason, humidified warm air can be reliably sent to humidification object space.

  Moreover, the 1st blower outlet 6a is provided in humidification object space. On the other hand, the 2nd blower outlet 7a is provided above the humidification object space. For this reason, a low position can be humidified more reliably.

  The mist gradually vaporizes while being transported together with air. As a result, the air near the mist is humidified until the relative humidity reaches 100%. At this time, the diameter of the mist is reduced. Therefore, depending on the temperature of the air blown from the first blower outlet 6a, the speed of the air blown from the first blower outlet 6a, the distance from the first blower outlet 6a to the humidifying target space, the temperature of the humidifying target space, etc. A device for controlling the diameter may be provided. In this case, the humidification target space can be humidified more reliably.

Embodiment 2. FIG.
FIG. 4 is a longitudinal sectional view of a partitioned area to which the humidification air conditioning system according to Embodiment 2 of the present invention is applied. In addition, the same code | symbol is attached | subjected to the part which is the same as that of Embodiment 1, or an equivalent part. The description of this part is omitted.

  In FIG. 4, the air conditioner 27 is provided on the wall 3 in the vicinity of the ceiling 4 in the partitioned area 1. The air conditioner 27 may be embedded in the wall 3. The air conditioner 27 includes a first blower 6, a second blower 7, a blower 8, a heating device 9, a mist generator 10, a temperature measuring device 11, and a control device 12.

  In the air conditioner 27, the 1st blower outlet 6a blows off air toward the downward direction. The 2nd blower outlet 7a blows off air toward the upper direction. The temperature measuring device 11 measures the temperature in a non-contact manner by detecting infrared rays. For example, the temperature measuring device 11 stores a program corresponding to an algorithm for determining the temperatures of the floor 2, the wall 3, the ceiling 4, the user, and the like. For example, the temperature measuring device 11 determines the temperatures of the floor 2, the wall 3, the ceiling 4, the user, and the like.

  The control device 12 determines the temperature blown out from the first air outlet 6a and the temperature blown out from the second air outlet 7a. Based on the temperature blown out from the first air outlet 6a, the temperature blown out from the second air outlet 7a, and the temperature measured by the temperature measuring device 11, the control device 12 controls the heating device 9, the mist generating device 10, and the first. The direction of the 1st blower outlet 6a, the direction of the 2nd blower outlet 7a, the speed of the air blown off from the 1st blower outlet 6a, and the speed of the air blown off from the 2nd blower outlet 7a are controlled. As a result, an increase in air in the humidification target space is suppressed.

  In FIG. 4, the blower 8 sends air to the heating device 9. The heating device 9 heats the air. A part of the air is sent to the first blower 6. A part of the air is sent to the second blower 7. In the first blower 6, the temperature of a part of the air is lowered by the amount of heat of vaporization of water. For this reason, the temperature of the air which blows off from the 1st blower outlet 6a tends to become lower than the temperature of the air which blows off from the 2nd blower outlet 7a.

  At this time, the control device 12 increases the amount of heat generated on the first blower 6 side in the heating device 9. As a result, the temperature of the air blown out from the first air outlet 6a becomes higher than the temperature of the air blown out from the second air outlet 7a.

  Note that the amount of air flowing on the first blower 6 side may be less than the amount of air flowing on the second blower 7 side under the control of the control device 12. For example, under the control of the control device 12, the opening of the first outlet 6a may be narrowed to increase the ventilation resistance. Also in this case, the temperature of the air blown from the first air outlet 6a is higher than the temperature of the air blown from the second air outlet 7a.

  According to Embodiment 2 demonstrated above, the 1st blower outlet 6a blows off air toward humidification object space. On the other hand, the 2nd blower outlet 7a blows off air toward the upper direction rather than humidification object space. For this reason, even when the 1st blower outlet 6a and the 2nd blower outlet 7a are provided above the humidification object space, a low position can be humidified locally.

Embodiment 3 FIG.
FIG. 5 is a longitudinal sectional view of a partitioned region to which the humidification air conditioning system according to Embodiment 3 of the present invention is applied. In addition, the same code | symbol is attached | subjected to the part which is the same as that of Embodiment 2, or an equivalent part. The description of this part is omitted.

  In FIG. 5, the humidification heating device 28 is provided on the floor 2 in the vicinity of the wall 3 inside the partition region 1. The humidification heating device 28 includes a first blower 6, a second blower 7, a blower 8, a heating device 9, a mist generator 10, and a temperature measuring device 11.

  In FIG. 5, the second blower 7 is divided into two systems. One of the second outlets 7 a is provided on one upper part of the system of the second blower 7. The other of the second air outlets 7 a is provided on the other upper part of the system of the second blower 7.

  The blower 8 sucks air in the vicinity of the floor 2. One of the systems of the second blower 7 sends the air sent from the blower 8 as it is. One of the second outlets 7a blows out air sent from one of the systems of the second blower 7. The other of the systems of the second blower 7 sends the air sent from the blower 8 to the heating device 9. The other of the second air outlets 7a blows out air heated by the heating device 9.

  The control device 12 controls the amount of air flowing from both of the second air outlets 7a and the direction of the air flow by controlling the opening and closing of both of the second air outlets 7a.

  According to Embodiment 3 demonstrated above, one side of the 2nd blower outlet 7a blows off the air which is not heated by the heating apparatus 9. FIG. The other of the second air outlets 7a blows out air heated by the heating device 9. For this reason, control of the temperature of the air sent above the humidification target space can be performed with higher accuracy.

  The warm air moves toward the ceiling 4. On the other hand, cold air moves toward the floor 2. For this reason, in the second embodiment, the blower 8 sucks cooler air in the vicinity of the floor 2. As a result, cooler air is sent to the vicinity of the ceiling 4. In this case, an air flow from the vicinity of the ceiling 4 toward the floor 2 is formed. For this reason, it can suppress more reliably that the humid warm air rises.

Embodiment 4 FIG.
FIG. 6 is a longitudinal sectional view of a partitioned area to which the humidification air conditioning system according to Embodiment 4 of the present invention is applied. In addition, the same code | symbol is attached | subjected to the part which is the same as that of Embodiment 1, or an equivalent part. The description of this part is omitted.

  In FIG. 6, the first blower 6 penetrates the ceiling 4 in the vicinity of the wall 3. The second blower 7 penetrates the ceiling 4 at a position farther from the wall 3 than the first blower 6. One of the heating devices 9 is provided in the middle of the duct 5 between the second blower 7 and the blower 8. The other of the heating devices 9 is provided on the upstream side of the mist generating device 10 in the middle of the first blower 6.

  The blower 8 sends air toward the inside of the duct 5. The air is heated by passing through one of the heating devices 9. The air branches into the first blower 6 and the second blower 7. The 1st blower outlet 6a blows off the air which passed the other side of the heating apparatus 9, and the mist generator 10 toward the downward direction. The 2nd blower outlet 7a blows off the air heated by one side of the heating apparatus 9 toward the downward direction.

  The control device 12 performs control so that the speed of the air blown from the first air outlet 6a is higher than the speed of the air blown from the second air outlet 7a. By this control, the air blown out from the first air outlet 6a is sent below the air blown out from the second air outlet 7a. As a result, humidified warm air reaches the humidification target space.

  At this time, the control device 12 determines the first air outlet 6a based on the distance from the first air outlet 6a to the humidifying target space, the temperature of the air in the humidifying target space, the temperature of the air blown from the first air outlet 6a, and the like. Controls the speed of air blown from. As a result, an air flow without a draft feeling is generated in the humidification target space. For this reason, user comfort is maintained.

  According to Embodiment 4 demonstrated above, the speed of the air which blows off from the 1st blower outlet 6a becomes higher than the speed of the air which blows off from the 2nd blower outlet 7a. For this reason, even when the 1st blower outlet 6a and the 2nd blower outlet 7a are provided in the very near position, a low position can be humidified locally.

  In this case, it can design without impairing an external appearance so that the area | region which the 1st blower outlet 6a and the 2nd blower outlet 7a occupy may become small. For example, it can be designed such that the first air outlet 6a and the second air outlet 7a gather in one place in appearance. For example, it can design so that the 1st blower outlet 6a and the 2nd blower outlet 7a may be arrange | positioned concentrically.

Embodiment 5 FIG.
FIG. 7 is a longitudinal sectional view of a partitioned area to which the humidification air conditioning system according to Embodiment 5 of the present invention is applied. In addition, the same code | symbol is attached | subjected to the part which is the same as that of Embodiment 1, or an equivalent part. The description of this part is omitted.

  In FIG. 7, one of the ducts 5 is arranged along the outside of the wall 3. The other side of the duct 5 is disposed along the upper side of the ceiling 4. The first blower 6 is formed at one lower portion of the duct 5. The first air outlet 6a opens in the horizontal direction. The second blower 7 is formed on the other side of the duct 5. The second air outlet 7a opens downward.

  The first intake body 29 penetrates the upper part of the wall 3. The intake port of the first intake body 29 is disposed in the upper part of the partition region 1. The intake port of the first intake body 29 opens in the horizontal direction. The air outlet of the first intake body 29 is connected to one upper portion of the duct 5. The second intake body 30 is provided outside the wall 3. The intake port of the second intake body 30 is disposed outside the wall 3. The discharge port of the second intake body 30 is connected to the middle of the first intake body 29.

  One of the blower devices 8 is provided on the downstream side of the first intake body 29. The other side of the blower 8 is provided on the other upstream side of the duct 5. One of the heating devices 9 is provided in the middle of the first blower 6. The other of the heating device 9 is provided in the middle of the other of the duct 5 between the other of the blower 8 and the second blower 7.

  The humidifier 31 is disposed in the middle of the second intake body 30. The humidifier 31 may be provided on the second blower 7.

  For example, the first intake body 29 sucks humidified air in the upper part of the partition region 1. For example, the humidifier 31 humidifies the air sucked from the outside and sends it to the first intake body 29. The first intake body 29 mixes the humidified air in the upper part of the partition region 1 and the air humidified by the humidifying device 31. The first intake body 29 sends the air to one side of the duct 5. The heating device 9 heats the air. The mist generating device 10 generates mist by aggregating moisture contained in the air.

  According to the fifth embodiment described above, the mist generating device 10 supplies the moisture contained in the air in which the air present in the space above the humidifying target space and the air humidified by the humidifying device 31 are mixed. Mist is generated by agglomeration. For this reason, the freedom degree of piping design, such as duct 5, can be raised. For example, air using the humidifying device 31 can be supplied so that a minimum humidity can be secured in most spaces in the entire building, and a higher humidity space can be provided only in a specific room. For example, in a commercial facility having a large space, moisture can be prevented from diffusing into the atrium space. At this time, construction of water piping or the like is unnecessary in an additional portion for generating mist. For this reason, construction of a humidification air-conditioning system can be performed easily. Moreover, waste of energy and water can be suppressed.

  In the humidification air-conditioning system according to the first to fifth embodiments, when warmed air is supplied when the temperature of the humidification target space is low, the humidified warm air is mixed with the surrounding air. To do. For this reason, the rise in the temperature of the humidification target space is not large. On the other hand, if the humidified warm air is supplied when the temperature of the humidifying target space is already high, the temperature of the humidifying target space further increases. For this reason, the air in the humidification target space is likely to diffuse upward. In this case, what is necessary is just to set the temperature of the air which blows off from the 1st blower outlet 6a to the low temperature by the control apparatus 12. FIG. At this time, the difference between the temperature of the air sent by the first blower 6 and the temperature of the air sent by the second blower 7 is reduced. As a result, an increase in air in the humidification target space can be suppressed.

  Moreover, in the humidification air conditioning system of Embodiment 1 to Embodiment 4, one air blower 8 sends air to the 1st air blower 6 and the 2nd air blower. In the humidification air-conditioning system, when the set heating temperature is reached, the blower 8 stops. In this case, it is preferable to set both temperature and humidity, and to perform independent feedback control on the heating device 9 and the mist generating device 10 based on the detection results of both the temperature and humidity. At this time, if the humidity does not reach the set humidity when the temperature reaches the set temperature, it is preferable to stop the heating device 9 and operate the blower 8 and the mist generating device 10.

  Moreover, the humidification air-conditioning system of Embodiment 1 to Embodiment 5 reduces the risk of causing problems such as condensation while humidifying an area where a user is present with a humidification capability that is smaller than when humidifying the entire space. For this reason, even if the temperature measured by the temperature measuring device 11 reaches the set temperature, the operation of the mist generating device 10 may be continued in a time zone where the user exists. If the user is detected by the human detection sensor, the operation of the mist generating device 10 may be continued. As a result, the temperature and humidity can be appropriately maintained according to the situation of the humidification target space.

  For example, a general residential air conditioning system is designed according to the heat load. In the said design, the airflow which makes the humid air reach the area | region where the user is sleeping is not assumed. Also, supplying air with a preset humidity does not supply humidity that is good for sleep. For this reason, when the humidification air-conditioning system of Embodiment 1 to Embodiment 5 is incorporated in the bedroom of an entire building air-conditioning system, etc., the combination of humidity, temperature, and wind speed, and noise are in sleep, sleeping throat, skin, etc. On the other hand, it is preferable to control so as to change within a preferable range. For example, it is preferable to perform control so that the mist reaches a position lower than a position where the user stands and sucks air in the vicinity of a bed, a futon or the like. For example, it is preferable to control the position so as not to get wet. For example, it is preferable to control the draft so as not to disturb sleep. For example, it is preferable to control so that condensation on the window is suppressed. As a result, a bedroom more suitable for sleeping can be provided.

  In the summer, it is preferable to suppress bedriddenness by blowing air and cooling with dry mist. For example, in a time zone when sleep is shallow, it is preferable to control the draft feeling and noise to be small. For example, it is preferable to perform control so that the draft feeling and noise are reduced when it is determined that sleep is shallow by a sensor that detects the depth of sleep. As a result, a bedroom more suitable for sleeping can be provided.

  Further, the humidification air conditioning system according to the first to fifth embodiments may be connected to a device outside the HEMS (home energy management system). In this case, the humidification air conditioning system should just interrupt | block the electric power to each apparatus based on the instruction | command which suppresses the electric power consumption from HEMS. At this time, priority may be given to the control of each device. Normally, users cannot tolerate lower temperatures than low humidity. For this reason, as the first stage power limitation, the power consumption may be reduced by stopping the mist generating device 10. As the second stage power limit, the power consumption may be reduced by lowering the temperature setting. As the power limitation at the third stage, the power consumption may be reduced by stopping the heating device 9 and the blower 8. In this case, it is possible to suppress power consumption while suppressing loss of comfort.

  DESCRIPTION OF SYMBOLS 1 division area, 2 floors, 3 walls, 4 ceiling, 5 duct, 6 1st air blower, 6a 1st blower outlet, 7 2nd blower, 7a 2nd blower outlet, 8 air blower, 9 heating device, 10 mist Generator, 11 temperature measuring device, 12 control device, 13 water tank, 14 heater, 15 ultrasonic vibrator, 16 rotating body, 17 crushing and collecting plate, 18 filter, 19 mist generating section, 20 ground electrode, 21 high voltage electrode, 22 High-voltage power supply, 23 Ultraviolet light source, 24 Reflector, 25 Ultrasonic wave generation source, 26 Reflector, 27 Air conditioner, 28 Humidification heating device, 29 First intake body, 30 Second intake body, 31 Humidifier

Claims (10)

A mist generator for generating mist,
A first blower for sending air containing mist generated by the mist generator to a humidification target space;
A second blower that sends air at a lower temperature than the mist generated by the mist generator without using the mist generated by the mist generator above the air containing the mist generated by the mist generator. When,
Humidification air conditioning system equipped with. A heating device for heating air sent to the mist generating device;
The humidification air conditioning system of Claim 1 provided with. The heating device heats air sent by the second blower,
The humidification air conditioning system according to claim 2 with which said 2nd blower sends air which is not heated by said heating device, and air heated by said heating device to said humidification object space. The first air blower has a first air outlet that is provided in the humidification target space and blows out air containing mist generated by the mist generator.
The second blower is provided above the humidification target space, and does not include the mist generated by the mist generator, and the air is lower in temperature than the mist generated by the mist generator. The humidification air-conditioning system of Claim 2 or 3 which had the 2nd blower outlet which blows upwards rather than the air which blown out. The first air blower has a first air outlet that is provided above the humidification target space and blows out air containing mist generated by the mist generating device downward.
The second blower is provided above the humidification target space, and does not include the mist generated by the mist generator, and the air is lower in temperature than the mist generated by the mist generator. The humidification air-conditioning system of Claim 2 or 3 which had the 2nd blower outlet which blows upwards rather than the air which blown out.   The two outlets do not include the mist generated by the mist generator and blow out air at a temperature lower than that of the mist generated by the mist generator at a higher speed than the speed of the air blown out by the first outlet. The humidification air conditioning system of Claim 5. A temperature measuring device for measuring the temperature of the air in the humidifying target space or the temperature of the floor provided in the humidifying target space;
A control device for controlling the difference between the temperature of the air sent by the first blower and the temperature of the air sent by the second blower based on the temperature measured by the temperature measuring device;
The humidification air conditioning system as described in any one of Claims 2-6 provided with these.   The mist generating device generates mist by aggregating moisture contained in air in which air existing in a space above the humidifying target space and air humidified by the humidifying device are mixed. The humidification air conditioning system as described in any one of Claims 7.   The humidification air conditioning system according to any one of claims 2 to 8, wherein the mist generating device forms a discharge space, an ultraviolet irradiation space, or an ultrasonic irradiation space in which moisture contained in air is aggregated. A blower for generating a flow of air to be sent to the first blower and the second blower,
With
The said mist generating apparatus reduces electric power consumption earlier than the said heating apparatus and the said air blower, when the instruction | command which suppresses electric power consumption from the outside is received. The humidification air conditioning system described.

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