JP2018021752A - Air conditioning method and air conditioning system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning method capable of reducing the infection risk of infectious disease when performing air conditioning while performing air ventilation with forced exhaustion using air blowing means regarding an indoor space of relatively high airtightness such as a railway vehicle, ship, hospital, movie theater or theater hall in which a number of persons are received, and an air conditioning system.SOLUTION: The present invention relates to an air conditioning method for obtaining air for ventilation by mixing fresh air for ventilation taken in from the outside for air ventilation with purified air for re-circulation obtained by purifying a part of air present within an air conditioning target space through processing using a filter and/or an adsorption material and following ultraviolet sterilization processing, and supplying the obtained air for ventilation into the air conditioning target space. At least one kind selected from among the fresh air for ventilation, the purified air for re-circulation and the air for ventilation is heated or cooled, thereby adjusting a temperature within the air conditioning target space.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air-conditioning method and an air-conditioning system for air-conditioning a relatively highly sealed indoor space that accommodates a large number of people such as railway vehicles, ships, hospitals, movie theaters, and theater halls.

  An air conditioner using a chlorofluorocarbon refrigerant has a feature that a high COP heat cycle can be realized, the refrigerant is easy to handle and safe, and the pressure in the heat cycle is low. For this reason, it is widely used as a general indoor air conditioning system.

  However, in recent years, from the viewpoint of preventing global warming, the use of natural refrigerants instead of chlorofluorocarbons has begun to be sought because the use of chlorofluorocarbons with ozone depleting effects and greenhouse effects has been reduced. As one of such air conditioning methods, an air conditioning system using an air cycle type air conditioning apparatus using air used in an aircraft as a refrigerant has been proposed (see Patent Document 1).

  That is, Patent Document 1 separates an air cycle apparatus that cools air that is directed from the outside to the room after compression and then expands and then cools the air, and moisture in the air condensed by the cooling after the compression. A water separation means, a drying device having a moisture adsorption function and dehumidifying with a moisture adsorbent regenerated by being heated, and the amount of heat of the air heated by the compression, An air conditioning system including a mechanism used for agent regeneration is disclosed.

JP 2004-226033 A

  In the conventional air conditioning system described in Patent Document 1, the line is switched between cooling and heating, and air taken from outside or outside the vehicle during cooling (hereinafter also referred to as “fresh air for ventilation”). The air recirculated from the room or vehicle during heating (hereinafter also referred to as “recirculation air”) is compressed by heat exchange with the cooling air after being compressed by the air cycle device, and heat exchange is performed. The adsorbent is regenerated using cooling air (also adsorbent regeneration air) heated by the above. At the time of cooling, the fresh air for ventilation cooled by the air cycle device is mixed with the recirculation air and supplied to the room. In heating, mixed air of fresh ventilation air and recirculation air used for cooling and adsorbent regeneration is supplied indoors.

  At this time, the recirculation air mainly contains contaminants caused by personnel, food and drinks, unavoidable insects and small animals that are present indoors or in the vehicle, so a HEPA filter, an adsorbent filter, etc. It is common to remove or reduce these contaminants depending on the air filter process used.

  However, the virus itself cannot be completely removed even with the HEPA filter. For example, even in an aircraft adopting an air conditioning system using an air cycle device having a HEPA filter, examples of in-flight infection with respect to SARS, measles, etc. Has also been reported.

  As described above, in the air conditioning system described in Patent Document 1, recirculation air that is not compressed by the air cycle device (becomes high temperature due to heat generated thereby) is supplied to the room during cooling. Therefore, it is thought that harmful microorganisms such as viruses are also circulating. Moreover, depending on the temperature of the cooling air heated by heat exchange during heating, there is a concern that harmful microorganisms may circulate.

  Therefore, an object of the present invention is to provide an air conditioning method using an air conditioning system and an air conditioning system used for the method, which can further reduce the risk of infection with an infectious disease.

  The present invention solves the above problems by sterilizing recirculation air with ultraviolet rays in a conventional air conditioning method and system.

Air conditioning method of the present invention is the air conditioning method for adjusting the temperature and ventilation of the air-conditioning target space while exhausting part of the air existing in the air-conditioning target space to the outside by using a blowing means And (A) a fresh air intake step for taking in fresh air for ventilation from outside to make fresh air for ventilation, and (B) for recirculation of a part of the air existing in the air conditioning target space. and air purifying recirculated air preparation step of obtaining purified to the purification recirculating air the recirculation air, the ventilation air is mixed with (C) the cleaning recirculation air and the fresh ventilating air A ventilation air supply step, and (D) a ventilation air supply step of supplying the ventilation air obtained in the ventilation air preparation step into the air-conditioning target space, (B) The recirculation in the purification air recirculation process The purification of the air is performed by treating the recirculation air with a filter and / or an adsorbent and then sterilizing the recirculation air that has been subjected to the treatment by irradiating with ultraviolet rays. The temperature of the ventilation air supplied into the air conditioning target space in the air supply process is adjusted by heating or cooling at least one selected from fresh ventilation air, purified recirculation air, and ventilation air , characterized in that.

  In the air conditioning method of the present invention, it is preferable that the fresh air for ventilation is cooled after being compressed and then expanded to cool the fresh air for ventilation. Further, in this method, before the fresh air for ventilation is cooled and expanded after compression, or before the expansion, the recirculation air is set to a pressure equal to or higher than the pressure of the compressed fresh air for ventilation. In the compressed state, ultraviolet irradiation in the (B) purification / recirculation air preparation step is performed, and the resulting purified purification / recirculation air is mixed with the compressed fresh air for ventilation. preferable. At this time, the compression ratio when compressing fresh air for ventilation is preferably 2.5 or more and less than 4.

In addition, the air conditioning system of the present invention includes a ventilation air supply port for supplying ventilation air into the air conditioning target space, an exhaust port for discharging air in the air conditioning target space; and for taking in fresh air from the outside inlet means and; air pressure-feeding means includes a filter apparatus and the ultraviolet irradiation apparatus, the recirculation air consisting part of the air discharged from the exhaust port after treatment by the filter device, re-received the treatment a recirculation flow path to purify by sterilized by irradiation with ultraviolet rays to obtain a cleaning recirculation air by using the ultraviolet irradiation device with respect to the circulating air; for ventilation, using blowing means air some air conditioning target space and a path for exhausting to the outside of the air-conditioning target space; the ventilation fresh air to obtain a ventilation fresh air of at least a portion of the fresh air taken by the intake unit A mixing vessel that mixes the purified recirculation air and the fresh ventilation air to obtain the ventilation air; and includes a compressor, a cooling heat exchanger, and a cooling turbine. The temperature of the ventilation air is adjusted by cooling using an air cycle system or heating using a heater. The compressor may be an intake means for taking in fresh air from the outside and / or an air pressure feeding means in the recirculation flow path.

  As a preferable aspect in the air conditioning system of the present invention, the following three aspects can be exemplified.

  1. The fresh air for ventilation in the air cycle system is cooled after being compressed and then expanded to cool the fresh air for ventilation, and the cooled fresh air for ventilation, the purified recirculation air, An air conditioning system for obtaining ventilation air by mixing with the mixer.

  2. A first compressor for compressing the ventilation fresh air, and a first cooling heat for cooling the ventilation fresh air heated by being compressed by the first compressor. An exchanger, a second compressor for compressing the recirculation air, and a second cooling heat exchanger for cooling the recirculation air heated by being compressed by the second compressor A cooling turbine, and the mixer is disposed upstream of the cooling turbine and downstream of the first cooling heat exchanger and the second cooling heat exchanger. Air conditioning system.

  3. An air conditioning system, wherein a heater is disposed on the mixer or downstream thereof to heat the ventilation air.

  In the air conditioning method and the air conditioning system of the present invention, the air for recirculation is sterilized with ultraviolet rays, so that the risk of infection infection in the air conditioning target space can be further reduced. Further, when ultraviolet sterilization is performed, by using a deep ultraviolet light emitting diode (hereinafter sometimes abbreviated as “DUV-LED”), power consumption is small and fuel consumption for power generation can be reduced. Moreover, since the DUV-LED does not use mercury that has a bad influence on the human body, it can safely perform air conditioning.

This figure is the schematic of the typical air conditioning system of this invention. This figure is a schematic view of another representative air conditioning system of the present invention. This figure is the schematic of another typical air conditioning system of this invention. This figure is a schematic diagram of a sterilization chamber and an ultraviolet light source that can be used in the air conditioning system of the present invention. This figure is a diagram schematically showing the structure of the ultraviolet light source in FIG. This figure is a schematic view of another sterilization chamber that can be used in the air conditioning system of the present invention. This figure is a schematic diagram of still another sterilization chamber and ultraviolet light source that can be used in the air conditioning system of the present invention. This figure is a schematic diagram of still another ultraviolet light source that can be used in the air conditioning system of the present invention.

Air conditioning method of the present invention is the air conditioning method for adjusting the temperature and ventilation of the air-conditioning target space while exhausting part of the air existing in the air-conditioning target space to the outside by using a blowing means And (A) a fresh air intake step for taking in fresh air for ventilation from outside to make fresh air for ventilation, and (B) for recirculation of a part of the air existing in the air conditioning target space. and air purifying recirculated air preparation step of obtaining purified to the purification recirculating air the recirculation air, the ventilation air is mixed with (C) the cleaning recirculation air and the fresh ventilating air A ventilation air supply step, and (D) a ventilation air supply step of supplying the ventilation air obtained in the ventilation air preparation step into the air-conditioning target space, (B) The recirculation in the purification air recirculation process The purification of the air is performed by treating the recirculation air with a filter and / or an adsorbent and then sterilizing the recirculation air that has been subjected to the treatment by irradiating with ultraviolet rays. The temperature of the ventilation air supplied into the air conditioning target space in the air supply process is adjusted by heating or cooling at least one selected from fresh ventilation air, purified recirculation air, and ventilation air , characterized in that.

  Here, the air-conditioning target space is a space such as a railway car, a ship, a hospital, a movie theater, a theater hall, etc. that accommodates a large number of people and has a high airtightness. It means the space that needs to be air-conditioned.

  In the (A) fresh air intake for ventilation in the method of the present invention, fresh air for ventilation is taken in from the outside using a suction blower or a compressor.

  (B) In the purification recirculation air preparation step, a part of the air present in the air conditioning target space is extracted as recirculation air by using a suction blower or a compressor, and then treated with a filter and / or an adsorbent. Thereafter, the recirculation air is purified by irradiating the recirculation air with ultraviolet rays to purify the recirculation air to obtain purified recirculation air. Filters and / or adsorbents include pre-filters for removing or reducing dust and fibers, HEPA filters for removing or reducing fine particles, bacteria, etc., adsorption filters for removing or reducing odors, VOCs, etc. A solid-amine filter or the like for adsorbing carbon dioxide is used.

  In the present invention, in order to efficiently irradiate ultraviolet rays, it is preferable to use a compressor as the pneumatic feeding means and arrange a pressure adjusting outflow valve or a turbine downstream of the compressor to form a pressurized space. At this time, it is preferable to arrange the filter device upstream of the compressor.

  In the method of the present invention, in the step (B), preferably, after treatment with a filter and / or an adsorbent, sterilization is performed by irradiating the recirculation air with ultraviolet rays.

  At this time, as the ultraviolet light source, it is preferable to use a deep ultraviolet light emitting diode (DUV-LED) that emits ultraviolet light having a main peak in a wavelength region of 200 nm to less than 350 nm, particularly 200 nm to less than 300 nm. By irradiating ultraviolet rays having such a wavelength, the air to be irradiated can be sterilized. For example, it is known that influenza virus is inactivated 99.9% when irradiated with ultraviolet light of 254 nm at 6.6 mW sec / cm 2 (= mJ / cm 2).

  The ultraviolet irradiation device used when irradiating ultraviolet rays may be an apparatus that directly irradiates the irradiated object with ultraviolet rays (UV) emitted from a light source having a DUV-LED. It may include an optical transmission system in which ultraviolet light (UV) emitted from a light source is transmitted by a light guide unit and emitted from the emission unit. As a light source, it is preferable to use a DUV-LED or a DUV-LED package in which a plurality of DUV-LED packages are arranged and arranged. As such an example, for example, DUV-LED groups are arranged side by side on a metal heat dissipation substrate as described in FIG. 6 of JP-A-2015-91582, covered with a quartz glass package, and the quartz glass A plurality of DUVs are provided on a side surface of a cylindrical or polygonal column base as described in FIGS. 2 and 3 of JP 2014-89898 A and a light source including a module that emits ultraviolet rays from a package. -A bar-shaped light source or the like that is formed into a bar-shaped module so that the LEDs are arranged so that the optical axis of each DUV-LED passes through the central axis of the base, and ultraviolet rays are emitted radially with respect to the central axis. Can be mentioned. In the above-mentioned patent document, an exit-side reflecting mirror composed of an ellipse reflecting mirror, a condensing side reflecting mirror composed of an ellipse reflecting mirror, and an ultraviolet exit opening provided in the vicinity of the condensing axis of the exit-side reflecting mirror And, it is disclosed that the rod-shaped light source is arranged on the focal axis of the output-side reflection mirror of the apparatus main body having the collimating system arranged in the opening, thereby providing an ultraviolet irradiation device. The ultraviolet irradiation device itself can also be used as a light source.

  In the case where the light source itself is an ultraviolet irradiation device and the ultraviolet light emitted from the light source is directly irradiated, a quartz glass package (which serves as a light irradiation window) of a module as disclosed in JP-A-2015-91582 is used. What is necessary is just to perform ultraviolet irradiation, circulating air so that it may contact with the air used as a to-be-irradiated body. Further, light transmission combining a light source; a light guide unit including an optical transmission path such as an optical fiber, an optical waveguide, and a light guide plate; and an output unit such as an optical fiber collimator, a lens diffusion plate, a diffusion lens, and a light guide plate; It is good also as an ultraviolet irradiation device incorporating a system. As an ultraviolet irradiation device incorporating such an optical transmission system, for example, a light transmission layer (corresponding to a light guide portion) and a light emitting surface (corresponding to an emission portion) as disclosed in JP-A-2006-237563. A combination of a surface light emitting device (light guide plate) having a light source and a light source can be exemplified. When the light guide plate is used, the light source is usually arranged on the side surface of the light guide plate. However, when the ultraviolet irradiation device disclosed in JP-A-2014-89898 is used as the light source, the light source has high intensity. UV irradiation can be performed.

  Ultraviolet irradiation may be performed in a duct or piping through which air flows, or may be performed in an ultraviolet sterilization chamber provided. The duct, pipe, and inner surface of the ultraviolet sterilization chamber where ultraviolet irradiation is performed are preferably made of a material having a high reflectivity with respect to ultraviolet rays because the sterilization efficiency can be increased by reflection of ultraviolet rays. Examples of such materials include platinum group metals such as Ru, Rh, Pd, Os, Ir, and Pt, Al, Ag, Ti, alloys containing at least one of these metals, or magnesium oxide. it can. Among these, it is particularly preferable that it is formed of Al, a platinum group metal, an alloy containing a platinum group metal, or magnesium oxide because of its particularly high reflectance. When the surface is composed of these materials, it is preferable to coat the surface with an ultraviolet light transmissive material such as silicon dioxide or fluororesin.

  The DUV-LED is turned on (operated) by electric power supplied from a power source. The ultraviolet irradiation device preferably has a light emission control circuit using a step-up DC-DC converter or a charge pump for controlling the forward current of the UV-LED.

  When performing the ultraviolet irradiation, in order to suppress the temperature rise of the DUV-LED and to stabilize the output and improve the durability, the heat generated from the DUV-LED is radiated using the ultraviolet light emitting diode cooling means, It is preferable to control the operating temperature of the DUV-LED to be within a certain range. The ultraviolet light emitting diode cooling means includes a heat dissipation heat sink or radiator for dissipating the heat generated from the DUV-LED, and an ultraviolet light emitting diode cooling fluid flow path, and an ultraviolet light emitting diode cooling fluid; What cools DUV-LED by making a heat sink for heat dissipation or a heat radiator contact directly or indirectly can be used suitably. At this time, from the viewpoint of cooling efficiency, it is preferable to use fresh air taken from the outside, or cooled fresh air or a part of cooled ventilation air from the viewpoint of cooling efficiency.

  In order to distribute the ultraviolet light emitting diode cooling fluid to the ultraviolet light emitting diode cooling fluid flow path, the ultraviolet light emitting diode cooling fluid flow path is a fresh air flow path taken in separately from the main flow path, or the main flow path. What is necessary is just to make it flow in through the flow path branched from this flow path.

  The heat sink or radiator for heat radiation is usually integrated with the substrate on which the DUV-LED is mounted, and the heat generated by the DUV-LED is for cooling the ultraviolet light emitting diode via the substrate and the heat sink or radiator for heat radiation. Released into the fluid. At this time, the temperature of the DUV-LED can be kept constant by adjusting the flow rate of the cooling fluid in accordance with the temperature of the ultraviolet light emitting diode cooling fluid while detecting the temperature of the DUV-LED with a sensor.

  As an example in which the heat sink or heat radiator for heat dissipation and the DUV-LED mounting substrate are integrated, for example, a rod-shaped module disclosed in Japanese Patent Application Laid-Open No. 2014-89898 (groove processing is performed on the inner wall surface of the cooling medium flow path). The groove processing when applied corresponds to the radiation fin.), A plurality of DUVs as described in JP-A-2015-91582, JP-A-2005-354067, and JP-A-2009-4688. -What connected the heat conductive board | substrate which mounts LED or some packaged DUV-LED, and the heat sink which has the fin for heat radiation, and the heat radiation fin integrated with the heat pipe etc. can be mentioned. When cooling the DUV-LED, these heat dissipating fins and the ultraviolet light emitting diode cooling fluid may be brought into contact (directly), or the ultraviolet light emitting diode cooling fluid is used as the refrigerant cooling means of the vapor cycle system. The system refrigerant may be in contact with a heat sink or heat radiator for heat dissipation.

  Further, from the viewpoint of sterilization efficiency, it is preferable to perform the ultraviolet irradiation in a pressurized space. Since the volume of air can be greatly reduced by pressurizing it, if ultraviolet irradiation is performed under pressure, a large amount of air can be efficiently irradiated with a certain amount of ultraviolet rays in a short time. It is. The pressure is not particularly limited as long as it is higher than the atmospheric pressure, but considering the energy required for pressurization, the pressure is 2.5 to 4 times, especially 2.5 to 3 times the atmospheric pressure. Is preferred.

  In order to form a pressurized space in the recirculation system flow path, for example, a compressor as a pneumatic feeding means may be used, and a pressure adjusting outflow valve or a turbine may be disposed downstream of the compressor. In the case where a turbine is provided, it is more preferable to use a turbine because energy when pressure is released can be recovered and used as electric power for causing the DUV-LED to emit light.

  In addition, from the viewpoint of facilitating maintenance of the ultraviolet irradiation device and easily ensuring the degree of freedom in selecting the installation location and sterilization location of the ultraviolet irradiation device, the ultraviolet irradiation device includes a light source having an ultraviolet light emitting diode and the pressure space. An ultraviolet light emitting optical member, the ultraviolet light emitting diode is disposed outside the pressurizing space, and the ultraviolet light emitted from the ultraviolet light emitting diode is emitted from the ultraviolet light emitting optical member and is added. It is preferable that the air flowing in the pressure space is irradiated with ultraviolet rays. At this time, as the ultraviolet ray emitting optical member, an emitting portion in the optical transmission system, specifically, an optical fiber collimator, a lens diffusion plate, a diffusion lens, a light guide plate, or the like can be used.

  (C) In the ventilation air preparation step, fresh ventilation air taken in step (A) and purified recirculation air obtained in step (B) pass through ducts or pipes, respectively, The fresh air inlet for ventilation and the air inlet for purification recirculation are introduced and mixed into the mixer to obtain ventilation air.

  Furthermore, in the method of the present invention, at least one selected from fresh ventilation air, purified recirculation air, and ventilation air is heated or cooled, and the air conditioning target space in the (D) ventilation air supply step is performed. Adjust the temperature of the ventilation air supplied to the.

  That is, in the air conditioning method of the present invention, when cooling is performed, it is preferable to perform the temperature adjustment using an air cycle system (ACS) using a compressor, a heat exchanger, and a turbine. At this time, the compression ratio when compressing fresh air for ventilation is preferably 2.5 or more and less than 4.

  In the above preferred embodiment, the fresh air for ventilation may be cooled after being compressed and then expanded to cool the fresh air for ventilation, and further, the fresh air for ventilation may be cooled after the compression. Before the expansion or before the expansion, the recirculation air is separately pressured above the pressure of the compressed fresh air for ventilation (preferably 1 to 1.2 times, more preferably 1-1. (1) pressure and less than 4 times the atmospheric pressure) In the compressed state (B) purifying and recirculating air preparation step, the resulting purified state is purified. Preferably, the recirculation air is mixed with compressed fresh air for ventilation. In addition, when ultraviolet irradiation is performed after separately compressing the recirculation air, cooling is performed before the ultraviolet irradiation and the temperature rises due to compression because it is easy to perform stable and effective ultraviolet irradiation. It is preferable to perform ultraviolet irradiation after lowering the temperature.

  When heating is performed, it is preferable to adjust the temperature of the ventilation air by heating using a heater.

  When adjusting these temperatures, based on information such as temperature, pressure, and flow rate detected by various sensors, by controlling various control valves such as temperature control valves, pressure regulating valves, check valves, and various devices such as electric compressors, Further, the temperature can be controlled by controlling the heater output.

  The present invention will be further described below with reference to the drawings.

  The air conditioning system 10 of the present invention shown in FIG. 1 is a system for cooling, and fresh air 70 is taken into the flow path while being compressed by the electric compressor 33 in the fresh air system flow path 30 for ventilation. Then, the compressed fresh air is cooled as the ventilation fresh air by the cooling heat exchanger 31 using the fresh air taken in by the suction blower 60 of another path as a cooling fluid. Then, the temperature and pressure are adjusted by adiabatic expansion by the cooling turbine 34, and fresh air for ventilation is obtained. Subsequent to cooling in the cooling heat exchanger 31 in the ventilation fresh air flow path 30, it is a so-called ACS, and may include a reheater, a condenser, and a water separator (all not shown). Moreover, the fresh air taken in by the suction blower 60 of another path is branched, and the temperature adjustment valve 61 is used as temperature adjustment air (which is also part of the ventilation fresh air) for warming the air in the mixer. It is supplied to the mixer 50 as needed. The fresh ventilation air 72 cooled by passing through the cooling compressor is branched and used as a fluid 73 for cooling the ultraviolet light emitting diode. At this time, the flow rate is controlled by the temperature control valve 62 in order to control the temperature of the DUV-LED 451 in the ultraviolet light source 45.

  On the other hand, indoor air (air in the air conditioning target space) 71 is exhausted from the indoor air exhaust ports 22 provided in each zone 23 of the air conditioning target space 20 by the action of the suction blower 46 serving as a blowing means, and recirculated. The air is introduced into the mixer 50 from the purification recirculation air inlet 52 via the recirculation flow path 40. Moreover, a part of room air 71 is discharged | emitted outside the air conditioning object space via the exhaust blower 24 for ventilation. In the recirculation system flow path 40, the recirculation air exhausted from each zone 23 is collected and passes through a filter device 41 installed downstream of the suction blower 46 to reduce or remove contaminants. An ultraviolet sterilization chamber 43 is provided on the downstream side of the filter device 41, and the ultraviolet light emitted from the ultraviolet light source 45 is radiated to the recirculation air in the chamber to be sterilized to be purified recirculation air. .

  In the mixer 50, the fresh air for ventilation, the air for purification recirculation sterilized with ultraviolet rays and the fresh air for ventilation for temperature adjustment as necessary are mixed to prepare and obtain the ventilation air having a predetermined temperature. The ventilating air is discharged from the ventilating air discharge port 53, branched through a duct, and supplied into the air conditioning target space 20 from the ventilating air supply port 21 provided in each zone 23 in the air conditioning target space.

  The air conditioning system 10 ′ of the invention shown in FIG. 2 is another system for performing cooling, and is an example in which ultraviolet ray sterilization of recirculation air is performed in a pressurized state. In this system, recirculation air is taken in while being compressed by the electric compressor 42 in the recirculation flow path 40. At this time, the filter device 41 is arranged on the upstream side of the electric compressor 42 so as to prevent coarse dust and the like from being mixed into the pressurization system. The recirculation air that is compressed by the electric compressor 42 and heated by the heat generated by the compression is cooled by heat exchange with fresh air 70 ″ in the cooling heat exchanger 31 and then introduced into the ultraviolet sterilization chamber 43. And UV sterilized under pressure. The purified recirculation air sterilized with ultraviolet rays is introduced into a mixer 50 provided between the cooling heat exchanger 31 and the cooling turbine 34 in the fresh air system flow path 30 for ventilation, and is compressed and cooled for ventilation. After being mixed with the fresh intake air, the air is expanded by passing through the cooling turbine 34, and the temperature of the ventilation air is adjusted. At this time, if the temperature of the air obtained by the expansion is too low, the air is warmed by mixing with fresh air for ventilation consisting of a part of the fresh air 70 ′ by the suction blower 60 of another path and adjusted to a predetermined temperature. Is done.

  The air conditioning system 10 ″ of the invention shown in FIG. 3 is another system for performing heating. In this system, the fresh air taken in by the suction blower 60 is directly introduced into the heat exchanger 50 as fresh air for ventilation, mixed with the purified recirculation air that has been sterilized by ultraviolet rays, and heated by the heater 63. It is warmed and used as ventilation air. The recirculation flow path 40 is basically the same as the system shown in FIG. 1, but fresh air 70 ′ introduced separately is used as the ultraviolet light emitting diode cooling fluid 73.

  4 and 5 are schematic views of an ultraviolet sterilization chamber 43a and an ultraviolet light source 45a that can be used in the air conditioning system of the present invention. These can be used either under pressure or under normal pressure. The light guide plate 454 is disposed inside the chamber 43a, and the ultraviolet light source 45a having the DUV-LED 451 is disposed outside the chamber 43a. In the ultraviolet light source 45a, a plurality of DUV-LEDs 451, which may be packaged as necessary, are arranged and mounted in a row on a substrate 452, and sealed with a lid 455 made of an ultraviolet transmissive material such as sapphire or quartz. It has been stopped. The substrate 452 is integrated with a heat sink having heat radiation fins 453, and the heat radiation fins 453 are exposed in the ultraviolet light emitting diode cooling fluid flow path 456 and flow through the flow path 456. Thus, the heat generated by the DUV-LED 451 can be dissipated. And the ultraviolet-ray output surface of the ultraviolet light source 45a is arrange | positioned so that it may closely_contact | adhere to the upstream end surface of the light-guide plate 454. FIG. The light guide plate 454 is provided with a light polarizing element on one side to form a light emitting surface (emission unit 457), and UV emitted from the DUV-LED 451 enters from the end surface, passes through the light transmission layer (light guide unit 458), The recirculation air 74 is emitted from the light emitting surface and circulates in the chamber (passed through the filter device), and purified recirculation air 75 is obtained.

  In FIG. 6, the schematic diagram of another ultraviolet sterilization chamber 43b which can be used with the air conditioning system of this invention is shown. The ultraviolet sterilization chamber 43 b uses a metal pipe 80 as a chamber, and the inside is a pressurized space 84. Inside the metal pipe 80, a light guide plate 454 as an ultraviolet emitting part is disposed. The light guide plate 454 is optically connected on its side surface to an optical fiber extending into the pipe from a pressure-resistant connector 83 fixed to a hole provided in the pipe 80. The optical fiber extending from the pressure-resistant connector 83 to the outside of the pipe is optically connected to the light exit port of the optical fiber 81 of the light guide in the coupler 82. The optical fiber 81 extends to a light incident port (not shown) existing at the other end, and ultraviolet rays emitted from a light source (not shown) are taken in from the light incident port and inside the optical fiber 81. And is emitted as diffused light from the light guide plate 454 via the light output port and the pressure-resistant connector 83. The emitted ultraviolet light advances while being repeatedly reflected on the inner wall surface of the pipe 80 made of an ultraviolet reflective material, and is sterilized by being irradiated to the recirculation air 74 that circulates inside.

  FIG. 7 shows a schematic diagram of still another ultraviolet sterilization chamber 43c and an ultraviolet light source 45c that can be used in the air conditioning system of the present invention. The ultraviolet sterilization chamber 43c is configured to directly irradiate the recirculation air 74 with ultraviolet rays emitted from the ultraviolet light source 45c in a horizontally long (long in the flowing direction of the purification recirculation air) flat box-like chamber. ing. In the ultraviolet light source 45c, a plurality of DUV-LEDs 451, which may be packaged as necessary, in a rectangular substrate 452 having substantially the same shape as the upper surface of the chamber, are arranged and mounted on the substrate 452 in rows and columns. In addition, it is sealed with a lid 455 made of an ultraviolet transmissive material such as sapphire or quartz. The substrate 452 is integrated with a heat sink having heat radiation fins 453, and the heat radiation fins 453 are exposed in the ultraviolet light emitting diode cooling fluid flow path 456 and flow through the flow path 456. Thus, the heat generated by the DUV-LED 451 can be dissipated. The ultraviolet sterilization chamber 43c is preferably used at normal pressure because the ultraviolet light source 45c itself is disposed in the chamber.

  Finally, FIG. 8 shows a schematic diagram of still another ultraviolet light source 43d that can be used in the air conditioning system of the present invention. The ultraviolet light source 43d is the same as the ultraviolet light sterilizer 100 disclosed in Japanese Patent Application Laid-Open No. 2014-89898. The ultraviolet light source 43d (ultraviolet sterilizer 100) includes an output side casing 125 whose inner surface is an output side reflection mirror 120 made of an ellipse reflection mirror, and a condensing side reflection mirror 123 whose inner surface is an ellipse reflection mirror. And a main body 150 including a collimating optical system 140 disposed in the ultraviolet emission opening 130; and a side surface of the cylindrical substrate 111. A plurality of DUV-LEDs 112 are arranged such that the optical axis 115 of each DUV-LED 112 passes through the central axis 114 of the base so that ultraviolet rays are emitted radially with respect to the central axis. A rod-shaped ultraviolet light emitting module 110; Then, the ultraviolet light emitting module 110 is arranged on the focal axis 121 of the emission side reflection mirror, and ultraviolet rays are emitted in the vicinity of the condensing axis 122 of the emission side reflection mirror (also the focal axis 124 of the condensing side reflection mirror). Opening 130 is provided.

  Furthermore, a cooling medium flow path 113 is formed inside the cylindrical base body, and the cylindrical base body 111 on which the DUV-LED 112 is mounted is covered with a cover 116 formed of an ultraviolet light transmissive material such as quartz. It has been broken. The cover 116 is airtightly or watertightly attached to the cylindrical substrate using a sealant 117 such as a sealant, packing, o-ring, and the like, and an inert gas such as nitrogen and a gas such as dry air are enclosed therein. Has been. The cylindrical substrate 111 functions not only as a support for fixing and holding the ultraviolet light emitting element 112 but also as a heat sink, and by circulating the cooling medium 118 through the cooling medium flow path 113. It is possible to prevent a temperature rise due to heat radiation from the ultraviolet light emitting element, to enable a stable operation of the element, and to extend an element life.

  The ultraviolet light source 43d can collect the light emitted from the DUV-LED arranged in the direction not facing the irradiated body and emit the ultraviolet light having high intensity as a belt-like translational light. ing. Therefore, it is preferable as a light source used in combination with the light guide plate.

  As described above, the air conditioning system for an aircraft of the present invention with reference to the drawings is not limited to those described in these drawings.

10, 10 ', 10''... Air conditioning system 20 ... Air conditioning target space 21 ... Ventilation air supply port 22 ... Indoor air exhaust port 23 ... Zone 24 ... Exhaust blower 30, 30 '... Fresh air system flow path 31, 32 ... Heat exchanger 33 ... Cooling heat exchanger 33 ... Electric compressor 34 ... Cooling turbine 40 ... Recirculation system flow path 41 ... Filter device 42 ... electric compressors 43, 43a, 43b, 43c ... UV sterilization chambers 45, 45a, 45c ... UV light source 451 ... DUV-LED
452 ... Substrate 453 ... Radiation fins 454 ... Light guide plate 455 ... Lid made of ultraviolet light transmissive material 456 ... Fluid flow path 457 for ultraviolet light emitting diode cooling ... Emission part 458 ... -Light guide 46 ... Suction blower 50 ... Mixer 51 ... Ventilation fresh air inlet 52 ... Purification recirculation air inlet 53 ... Ventilation air outlet 60 ... Suction blowers 61, 62 ... temperature control valve 63 ... heaters 70, 70 ', 70 "... fresh air 71 ... indoor air (air in air conditioning target space)
72 ... Cooled fresh air 73 ... UV light emitting diode cooling fluid 74 ... Recirculation air 75 ... Purified recirculation air 80 ... Piping 81 ... Optical fiber 82 ... Coupler 83 ... Pressure resistant connector 84 ... Pressure space 100 ... UV disinfection device 110 ... UV light emitting module 111 ... Cylindrical substrate 112 ... Deep UV light emitting element (DUV-LED)
113 .. Cooling medium flow path 114... Center axis 115 of cylindrical substrate.. Optical axis 116 of deep ultraviolet light emitting element.. Cover 117... Seal member 118. Output side reflection mirror 121... Focus axis 122 of the output side reflection mirror... Condensing axis 123 of the output side reflection mirror... 125.. Emission side casing 126... Condensing side casing 130.. UV exit opening 140... Collimating optical system 150.

Claims (3)

An air conditioning method for adjusting the temperature and ventilation of the air-conditioning target space while exhausting part of the air existing in the air-conditioning target space to the outside by using a blowing means,
(A) A fresh air intake process for ventilation, in which fresh air for ventilation is taken from the outside into fresh air for ventilation,
(B) the air conditioning and recycling air part of the air existing in the target space, cleaning recirculation air preparation step of obtaining a purifying recirculated air by purifying the recirculating air,
(C) wherein the ventilation fresh air as a mixture of cleaning recirculation air get ventilation air, ventilation air preparation step, and (D) the ventilation air obtained in the ventilation air preparation step wherein supplied to the air conditioning target space, the ventilation air supplying step, including Nde a result,
The purification of the recirculation air in the purification recirculation air preparation step (B) is performed by treating the recirculation air with a filter and / or an adsorbent and then subjecting the recirculation air subjected to the treatment to ultraviolet rays. Is performed by sterilizing by irradiation,
The ventilation air supplied into the air conditioning target space in the (D) ventilation air supply step heats at least one selected from the fresh ventilation air, the purification recirculation air, and the ventilation air. The air conditioning method, wherein the temperature is adjusted by cooling . A ventilation air supply port for supplying ventilation air into the air conditioning target space;
An exhaust port for exhausting air in the air-conditioning target space;
Intake means for taking in fresh air from the outside,
A recirculating air comprising a part of the air discharged from the exhaust port is treated by the filter device , and then the recirculated air subjected to the treatment is included. A recirculation flow path for purifying and purifying recirculating air by sterilizing by irradiating with ultraviolet rays using the ultraviolet irradiation device;
A ventilation fresh air system flow path for obtaining fresh ventilation air consisting of at least part of the fresh air taken in by the intake means;
A path for exhausting a part of the air in the air-conditioning target space to the outside of the air-conditioning target space using ventilation means for ventilation,
Cooling or heater using an air cycle system including a mixer that mixes the purified recirculation air and the fresh ventilation air to obtain ventilation air, and includes a compressor, a heat exchanger for cooling, and a cooling turbine air conditioning system comprising a, a temperature preparation unit for adjusting the temperature of the ventilation air by heating with. The air conditioning system according to claim 2 ,
An air conditioning system further comprising a heater disposed at or downstream of the mixer and configured to heat the ventilation air.

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