JP7372174B2 - Air conditioning system for multiple disaster cots - Google Patents

Description

TECHNICAL FIELD The present invention relates to an air conditioning system for a plurality of disaster cots.

For example, in the event of a disaster such as a tsunami, earthquake, volcanic eruption, or landslide caused by heavy rain, many people evacuate to evacuation centers such as gymnasiums and schools when they are forced to leave their homes.
Evacuation centers house many people in a single space and provide drinking water, food, and blankets for sleeping.
For this reason, disaster cots equipped with blindfold sheets are used in evacuation centers to ensure a space that protects privacy (for example, see Patent Document 1).

Japanese Patent Application Publication No. 2007-160030

However, as mentioned above, evacuation centers such as gymnasiums and schools accommodate many people, so the room temperature may rise and make the evacuation center uncomfortable. Particularly in the hot summer months, the room temperature rises significantly, making you feel even more uncomfortable. If a conventional disaster cot is used in such an environment, the temperature inside the disaster cot will further rise because the blindfold sheet blocks the airflow.
For this reason, sick and injured people who cannot easily go back and forth between the evacuation center and the outside will always lie inside the disaster cot, which may lead to their physical condition worsening.
The present invention was made in view of the above circumstances, and is intended to protect the privacy of sick people lying on multiple disaster cots in a shelter during a disaster, as well as improve comfort and protect the sick people. The purpose of the present invention is to provide an air conditioning system for multiple cots for disaster situations.

In order to achieve the above-mentioned object, the present invention provides a plurality of cots for disaster situations, each of which has a reclining sheet provided above the floor surface on which a user lies, and a blindfold sheet covering the periphery and upper part of the reclining sheet. An air conditioner, which connects a blower driven by electric power, an outlet of the blower and the inside of the blindfold sheet of each of the plurality of disaster cots, and air sent out by the blower. and a blower pipe for feeding into the inside of the blindfold sheet of each of the plurality of disaster cots.

By sending the air sent out by the blower into the inside of the blindfold sheet of each of the multiple cots for disaster relief using the blower pipe, it is possible to remove the air from multiple sick people lying on the cots for disaster relief at evacuation centers during a disaster. This is advantageous in protecting privacy, improving comfort, and protecting multiple sick patients.

1 is a schematic diagram showing the overall configuration of an air conditioner for a plurality of disaster cots according to a first embodiment; FIG. It is a perspective view of a cot for disasters. FIG. 3 is a functional block diagram of a blower. It is a perspective view of an air pipe. It is a figure showing the end of the main wind pipe. It is a figure showing a distribution wind pipe. It is a figure showing the flow of air by the air conditioner of the disaster cot shown in a 1st embodiment. FIG. 2 is a schematic diagram showing the overall configuration of an air conditioner for a plurality of disaster cots according to a second embodiment.

(First embodiment)
An air conditioner 1 for a plurality of cots for emergencies according to a first embodiment will be described below with reference to the accompanying drawings.
As shown in FIG. 1, an air conditioner 1 for a plurality of disaster cots according to the present embodiment includes a blower 20 and a blower pipe 30, and includes a plurality of disaster cots installed in an evacuation center or the like. Used for 10.
The air conditioner 1 for a plurality of disaster cots according to the present embodiment sends air sent out by a blower 20 into the ten disaster cots 10 through a blow pipe 30. The number of cots 10 is arbitrary.
In addition, since FIG. 1 schematically represents the air conditioner 1 for a plurality of emergency cots, the size of each component differs from the actual proportion.

As shown in FIG. 2, the emergency bed 10 includes a frame 12 made of pipe material, and a lying sheet supported by the frame 12 and provided upwardly from the floor for the user to lie down on. 16, and a blindfold sheet 18 that covers the periphery and upper part of the lying sheet 16.
In this embodiment, the blindfold sheet 18 includes four side surfaces and an upper surface connected to the upper edges of these side surfaces, and an entrance/exit is provided on one of the four side surfaces.
Note that various conventionally known disaster cots including a lying sheet 16 and a blindfold sheet 18 can be applied to the disaster cot 10.
In this embodiment, a plurality of disaster cots 10 are arranged and installed at predetermined positions.

The blower 20 is driven by electric power to rotate an impeller and send out air sucked in from the suction port 22 from the outlet 24. In this embodiment, a blower pipe 30 is attached to the outlet 24. ing.
As the blower 20, any other known blower may be used regardless of the shape as long as it sends out air.
The blower 20 also includes a CPU, a ROM that stores and stores control programs, etc., a RAM that serves as an operating area for the control program, an EEPROM that retains various types of data in a rewritable manner, an interface unit that interfaces with peripheral circuits, etc. As shown in FIG. 3, when the CPU executes the control program, it functions as an input reception section 70A, a power control section 70B, an air volume adjustment section 70C, a timer section 70D, and a display control section 70E.

Further, inside the blower 20, as a power source, a battery section is provided that stores electric power supplied to rotate the impeller of the blower 20. In this embodiment, a battery section consisting of a primary battery or a secondary battery is provided. part is retained.
Note that the power source may be any known power source as long as it can supply power to the blower 20, and does not need to be an internally held battery, such as a generator that generates and supplies power, or a mobile battery connected to a USB. , a power source converted from an AC power source to a USB power source, or a solar power source may be used.
In addition, for example, as a power source, it includes a battery section consisting of a primary battery or a secondary battery, a commercial power supply section using a commercial power supply, and a power supply switching section that switches between the battery section and the commercial power supply section and connects it to the blower. It is also possible to adopt a configuration in which the commercial power supply section is switched to the battery section when the commercial power supply becomes unavailable due to a disaster or the like. This allows the blower 20 to be used for a longer period of time even in the event of a power outage during a disaster.

The input reception unit 20A receives instructions corresponding to various input buttons (power button, air volume setting button, timer setting button, etc.) when the user operates various input buttons (not shown) provided on the outside of the blower 20 (power button, air volume setting button, timer setting button, etc.). accept.
Specifically, the input receiving unit 20A issues an instruction to start power supply to supply power from the battery unit to the blower 20 and a power supply to stop supplying power from the battery unit to the blower 20 when the power button is operated. Accepts stop instructions.
In addition, the input receiving unit 20A receives, for example, a weak wind instruction to weaken the air volume of the blower 20 and a strong wind instruction to increase the air volume, when the air volume setting button is operated.
In addition, the input receiving unit 20A receives a stop setting time until the blower 20 is stopped when the timer setting button is operated.

The power control unit 20B controls whether or not power is supplied from the battery unit to the blower 46 and the amount of power.
That is, when the power control unit 20B receives the power supply start instruction from the input reception unit 20A, the power control unit 20B starts supplying power from the battery unit to the blower 20.
Moreover, when the power control unit 20B receives a power supply stop instruction from the input receiving unit 20A, the power control unit 20B stops the power supply from the battery unit to the blower 20.

The air volume adjustment unit 20C supplies an amount of power corresponding to the set air volume to the blower 20 via the power control unit 20B.
That is, when the input receiving unit 20A receives a weak wind instruction, the power amount for sending out a weak air volume is supplied to the blower 20 via the power control unit 20B.
When the input receiving unit 20A receives a strong wind instruction, the amount of power for sending out a strong air volume is supplied to the blower 20 via the power control unit 20B.

When the timer unit 20D receives the stop setting time from the input receiving unit 20A, the timer unit 20D stops supplying power to the blower 20 via the power control unit 20B when the set time has elapsed.

The display control unit 20E displays the driving status of the blower 20 and the presence or absence of a power source on a display screen (not shown) provided on the outside surface of the blower 20.
For example, when the input receiving unit 20A receives an instruction to start power supply, the display control unit 20E displays a message to that effect (for example, "operating", "power on", etc.), and displays a set air volume (for example, "low wind"). (e.g. "strong wind").
Furthermore, for example, when the input receiving unit 20A receives an instruction to stop power supply, the display control unit 20E indicates that it is not being driven by not displaying the display screen.
Note that the display control unit 20E may be configured to not only display characters and the like on the display screen, but also display the driving status of the blower 20, the presence or absence of a power source, etc. by the color of a lamp (display unit) or the like.

Returning to FIG. 1, the blower pipe 30 is a pipe (duct) made of a collapsible material such as nylon or polyester, and connects the outlet 24 of the blower 20 and each of the plurality of disaster cots 10. The interior of the blindfold sheet 18 is connected to the inside of the blindfold sheet 18, and the air sent out by the blower 20 is sent into the inside of the blindfold sheet 18 of each of the plurality of disaster cots 10.
As shown in FIGS. 4, 5, and 6, the air pipe 30 includes a main air pipe 32 that is detachably attached to the outlet 24 of the blower 20, and an exhaust port 34A that branches from the main air pipe 32 into a plurality of parts and discharges air. It is composed of a plurality of distribution wind pipes 34 provided with.
Since the blower pipe 30 is foldable as described above, it is easy to carry and install, which is advantageous in improving convenience.

As shown in FIGS. 4 and 5, the main wind pipe 32 is a pipe having a predetermined length, and has a plurality of attachment parts on the outer peripheral surface on both sides thereof for detachably attaching a plurality of distribution wind pipes 34. 3206 is provided.
One end 3202 of the main wind pipe 32 is removably attached to the outlet of the blower 20, and the other end 3204 is closed to prevent air from being discharged.
The main wind pipe 32 and the blower 20 can be attached, for example, by placing one end 3202 of the main wind pipe 32 over the air outlet 24 of the blower 20, and installing the main wind pipe 32 along the outer periphery of the end 3202. By pulling the string 3204, the end portion 3202 is collapsed and attached to the air outlet 24. In addition, by loosening the string 3204, the end portion 3202 is expanded and can be pulled out from the air outlet 24 of the blower 20 and removed.

Furthermore, the method of attaching the main wind pipe 32 and the blower 20 is not limited to the above-mentioned method, and various known attachment methods can be used as long as they can be attached and detached.
That is, for example, the main wind pipe 32 and the blower 20 may be detachably attached using a hook-and-loop fastener. Specifically, a male hook-and-loop fastener (hook side) is attached to the outer circumferential surface of the blower 20 on the outlet 24 side, and a female hook-and-loop fastener (loop side) is attached to the inner circumferential surface of one end 3202 of the main wind pipe 32. The main wind pipe 32 and the blower 20 may be detachably attached by attaching and detaching the male and female hook-and-loop fasteners.

When air is sealed inside from the blower 20 connected to one end 3202, the main wind pipe 32 expands to have a circular cross section, allowing the air to pass through, and is attached to the outer peripheral surface. Air is sent into the distribution wind pipe 34. A method of attaching the main wind pipe 32 and the distribution wind pipe 34 will be described later.

As shown in FIG. 6, the plurality of distribution air pipes 34 are formed in a rectangular shape smaller than the lying sheet 16, and are provided with an outer peripheral part 3402 that expands into a tubular shape when air is sealed, and the short side of the outer peripheral part 3402 An attachment portion 3406 for attaching to the main wind pipe 32 is provided on one side, and an exhaust port 34A is provided on the long side of the outer peripheral portion 3402.
The exhaust port 34A of this embodiment is provided on the upper surface of the outer circumferential portion 4302 of the distribution wind pipe 34 so as to discharge air upward, and can be opened and closed by a fastener 3404. Therefore, when the fastener 3404 is open, air is allowed to escape, and when the fastener 3404 is closed, air is not allowed to escape.
In this embodiment, two exhaust ports 34A are provided diagonally near the outer circumferential portion 3402 of the distribution wind pipe 34; The number and location of installation are arbitrary.
Further, when in use, the distribution wind pipes 34 are inserted under the lying sheets 16 of the plurality of emergency cots 10, and discharge the air discharged from the exhaust ports 34A toward the lower surface of the lying sheets 16. .

A method of attaching the main wind pipe 32 and the distribution wind pipe 34 will be explained.
As shown in FIGS. 4 and 5, the plurality of attachment parts 3206 of the main wind pipe 32 are provided on the outer circumferential surface on both sides of the pipe, and have openings 3206A to allow air to be discharged.
Further, as shown in FIGS. 4 and 6, the attachment portion 3406 of the distribution wind pipe 34 is provided on the short side of the outer peripheral portion 3402, and has an opening 3406A to take in air.
The main wind pipe 32 and the distribution wind pipe 34 are attached by the attachment portion 3206 and the attachment portion 3406, and are detachably attached using, for example, a hook-and-loop fastener.
Specifically, a male hook-and-loop fastener is attached to the back of the end located above the attachment portion 3206 of the main wind pipe 32, and a female hook-and-loop fastener is attached to the back of the end located below the attachment portion 3206. . On the other hand, a female hook-and-loop fastener is attached to the surface of the end located above the attachment portion 3406 of the distribution air pipe 34, and a male hook-and-loop fastener is attached to the surface of the end positioned below the attachment portion 3406.
In other words, the male and female hook-and-loop fasteners are attached to the attachment portions 3206 and 3406 upside down, and by attaching and detaching the male and female hook-and-loop fasteners on the upper and lower sides, respectively, they can be connected to the main wind pipe 32 and distributed. A wind pipe 34 is detachably attached.
Also, since the attachment part 3206 of the main wind pipe 32 is a male hook-and-loop fastener, and the lower side is a female hook-and-loop fastener, if the distribution wind pipe 34 is not attached, the upper side of the attachment part 3206 of the main wind pipe 32 The opening 3206A can be closed by bringing the lower sides together. Therefore, if the number of disaster cots 10 installed in an evacuation center is less than the number of attachment parts 3206, the air conditioner 1 is used by attaching distribution wind pipes 34 according to the number of disaster cots 10. be able to.
Note that various known attachment methods can be used to attach the main wind pipe 32 and the distribution wind pipe 34 as long as they can be attached and detached.

In such a blow pipe 30, one end 3202 of the main wind pipe 32 is attached to the outlet 24 of the blower 20, and the distribution wind pipe 34 attached to the main wind pipe 32 is inserted below the lying sheet 16. and placed on the floor.
For this reason, as shown by the arrows in FIG. 7, the air conditioner 1 for the plurality of disaster cots sends the air sent out by the blower 20 to the blindfold sheet 18 below the lying sheet 16 through the blower pipe 30. Send it into the space surrounded by the sides.

A case will be described in which the air conditioner 1 for a plurality of disaster cots configured as described above is used.
The blower 20 and the folded air pipe 30 are carried to a desired position, the main air pipe 32 of the air pipe 30 is installed, and the necessary number of distribution air pipes 34 are attached.
Then, the distribution wind pipe 34 is inserted and placed under the lying sheet 16 of each of the plurality of disaster cots 10.
Next, one end 3202 of the main wind pipe 32 of the air pipe 30 is attached to the outlet 24 of the blower 20.
Then, when the blower 20 is powered on and the desired air volume is set by the user's operation, the air sent out from the blower 20 passes through the inside of the blower pipe 30 and is used for lying down on the disaster cot 10. The air is sent below the sheet 16 and is discharged from the exhaust port 34A toward the lower surface of the lying sheet 16.

According to the air conditioner 1 for a bed with multiple emergency pipes of this embodiment, there is a lying sheet 16 provided above the floor surface on which the user lies, and a blindfold that covers the area around and above the lying sheet 16. When a plurality of disaster cots 10 having sheets 18 are installed in an evacuation center, the air sent out by the blower 20 is sent through the air pipe 30 into the inside of the blindfold sheet 18 of each of the disaster cots 10. By sending them, it is advantageous in protecting the privacy of multiple sick people lying on disaster cots set up at evacuation centers during disasters, as well as improving comfort and protecting multiple sick people. .
Further, the plurality of distribution wind pipes 34 of the air pipe 30 are inserted under the lying sheets 16 of each of the plurality of disaster cots 10, and exhaust air from the exhaust ports 34A provided on the upper surface of the distribution wind pipes 34. It is discharged toward the lower surface of the lying sheet 16. Therefore, it is possible to send air into the blindfold sheet 18 while applying air to the lower surface of the lying sheet 16, thereby avoiding direct air exposure to the patient, etc., and preventing air from being trapped under the lying sheet 16. Exhaust and ventilate hot air to improve comfort.
Furthermore, since the blower pipe 30 is made of a foldable material, it is easy to carry and easy to install at a desired position, which is advantageous in improving convenience.
Further, in the air pipe 30, each of the plurality of distribution air pipes 34 is attached to the main air pipe 32 by the attachment part 3206 of the main air pipe 32 and the attachment part 3406 of the distribution air pipe 34, and the distribution air pipe 34 is not attached. In this case, the opening 3206A of the attachment part 3206 of the main wind pipe 32 can be closed to prevent air from being discharged. For this reason, the air conditioner 1 for beds in a plurality of disaster pipes according to the present embodiment is configured according to the number of disaster cots 10 installed in the evacuation center (the number of people using the disaster cots 10). Since the distribution wind pipe 34 can be attached and used, it is further advantageous in terms of improving convenience.

Further, since a battery is used as a power source for the blower 20, it is advantageous in improving comfort even when a power outage continues for a long time. That is, for example, in a hot summer evacuation center, the room temperature rises significantly as many people are accommodated therein, and the temperature inside the disaster cot 10, where the air flow is blocked by the blindfold sheet 18, is even higher. It is possible that the temperature could rise to over 40 degrees, which is considerably higher than body temperature. In such an environment, if a sick person who cannot easily travel between the evacuation center and the outside is lying on the disaster cot 10, it is assumed that the internal temperature will become high and the condition will worsen further. Ru. In this embodiment, a battery is used as a power source, so even if there is a power outage, the air conditioner 1 is driven by the battery, and air from the blower 20 is sent into the disaster cot 10 and the interior is ventilated. can do. Therefore, it is advantageous in improving the comfort of a sick person lying on a cot for use in a disaster, suppressing the deterioration of the condition, and protecting the sick person.

Note that although the blower 20 of the first embodiment is installed on the floor inside the evacuation center, a long blower pipe 30 that can connect the disaster cot 10 to the outside of the evacuation center may be attached. The blower 20 may be installed outside a building such as a shelter. As a result, air from outside the building can be taken into the interior of the cot 10 for use in emergencies, so odors trapped inside buildings such as evacuation centers can be exhausted and ventilation can be achieved using the outside air from the building, improving comfort. can be further improved.

(Second embodiment)
In the first embodiment, the air sent out by the blower was sent into the inside of the blindfold sheet of the disaster cot, whereas in the second embodiment, the air conditioning of a plurality of disaster cots was carried out. Device 2 is different in that the cold air sent out from the air conditioner is sent out by a blower and sent into the inside of the blindfold sheet of the cot for disaster use.
In the following description of the embodiment, parts and members similar to those in the first embodiment are given the same reference numerals, and the description thereof will be omitted, and emphasis will be placed on parts that are different from the first embodiment. Explain.

As shown in FIG. 8, the air conditioner 2 for a plurality of disaster cots according to the present embodiment includes a blower 20, a blower pipe 30, a cooling device 50, and piping 60, and is installed in an evacuation center or the like. It is used for a plurality of emergency cots 10.
Note that, like FIG. 1, FIG. 8 schematically represents the air conditioner 2 for a plurality of emergency cots, so the size of each component differs from the actual ratio.

The cooling device 50 cools air by being driven by electric power, and sends out the cooled air (cold air) from the outlet 52.
The cooling device 50 of the present embodiment is configured to use, for example, a commercial power source as a power source, but the power source only needs to be able to supply power to the cooling device 50, and a primary power source that stores enough power to drive the cooling device 50 is sufficient. A battery, a secondary battery, a generator that generates electric power, or the like may be used.
Further, similarly to the blower 20, for example, as a power source, a battery section made of a primary battery or a secondary battery, a commercial power supply section using a commercial power supply, and the battery section and the commercial power supply section are switched and connected to the blower. The power supply switching unit may be configured to include a power supply switching unit, so that when the commercial power supply becomes unavailable due to a disaster or the like, switching from the commercial power supply unit to the battery unit may be performed. This allows the cooling device 50 to be used for a longer period of time even in the event of a power outage during a disaster.

The piping 60 is a pipe (duct) made of plastic cardboard, for example, and is removably attached to the cold air outlet 52 of the cooling device 50 and the air intake port 22 of the blower 20, and is connected to the cooling device 50. The cold air sent out is passed inside and sent to the blower 20.
The piping 60 includes a first piping 6002 and a second piping 6004 each having a rectangular cross section, and a third piping 6006 having a circular cross section to match the shape of the suction port 22 of the blower 20. It consists of
The first pipe 6002 is a pipe that connects the cooling device 50 and the second pipe 6004, and has an opening for taking in the cold air sent out from the cooling device 50, and the air outlet 52 and the opening are aligned. installed.
The second pipe 6004 is a pipe that connects the first pipe 6002 and the third pipe 6004, and is provided in the vertical direction so as to carry cold air to the floor surface.
The third pipe 6006 is a pipe that connects the second pipe 6004 and the suction port 22 of the blower 20.

The piping 60 and the cooling device 50 are attached using, for example, hook-and-loop fasteners. Specifically, a male hook-and-loop fastener (hook side) is attached around the air outlet 52 of the cooling device 50, and a female hook-and-loop fastener (loop side) is attached around the opening of the first pipe 6002 of the air pipe 60. The piping 60 is detachably attached to the cooling device 50 by attaching and detaching the male and female hook-and-loop fasteners.
Similarly, the piping 60 and the blower 20 are attached using, for example, hook-and-loop fasteners. Specifically, a male hook-and-loop fastener (hook side) is attached around the suction port 22 of the blower 20, and an annular plate-shaped protrusion that is discharged from the outer peripheral surface of the end of the third pipe 6002 of the blower pipe 60 is attached. A female hook-and-loop fastener (loop side) is attached to the end side, and the pipe 60 is detachably attached to the blower 20 by attaching and detaching the male and female hook-and-loop fasteners.
Note that various known attachment methods can be used to attach the piping 60 and the cooling device 50, and to attach the piping 60 and the blower 20, as long as they can be attached and detached. Furthermore, since a disaster is an emergency, the piping 60 and each piping may be connected using adhesive tape or the like.

As described above, in the present embodiment, by sending the cold air sent out from the cooling device 50 to the suction port 22 of the blower 20 through the pipe 60, the blower 20 directs the cold air sucked in from the suction port 22 toward the blow pipe 30. and send it out.
As in the first embodiment, the air pipe 30 has one end 3202 of the main air pipe 32 attached to the outlet 24 of the blower 20, and a distribution air pipe 32 attached to the main air pipe 32. is inserted under the lying sheet 16 and placed on the floor surface.
For this reason, the air conditioner 2 of the plurality of disaster cots is configured to send cold air from the air conditioner 50 to the blower 20 through piping 60, and to conceal the cool air sent out by the blower 20 below the lying sheet 16 using the blower pipe 30. (See FIG. 7 of the first embodiment).

When using the air conditioner 2 for a plurality of disaster cots configured as described above, the blower 20 and the air pipe 30 in a folded state are carried to a desired position near the air conditioner 50, and the piping 60 is The attached cooling device 50 and the blower 20 are connected.
After that, similarly to the first embodiment, the main wind pipe 32 of the air pipe 30 is installed, the necessary number of distribution wind pipes 34 are attached, and the distribution wind pipes 34 are connected to each of the plurality of disaster cots 10. The main air pipe 32 of the air pipe 30 is attached to the air outlet 24 of the air blower 20, and the air blower 20 is turned on.

According to the air conditioner 2 for a plurality of disaster cots according to the present embodiment, the same effects as those of the first embodiment can be achieved.
In addition, in the air conditioner 2 for a plurality of emergency cots according to the present embodiment, since the air conditioner 50 and the blower 20 are connected by the piping 60, the blower 20 sucks the cold air sent out from the air conditioner 50. , and are sent to each disaster cot 10 via the blower pipe 30. Therefore, the temperature inside the disaster cot 10 into which cold air is sent can be lowered more quickly than when air is sent in, and the comfort of the sick person lying on the disaster cot can be quickly improved. This is advantageous in preventing the deterioration of the disease and protecting the sick.
In addition, since the cold air sent out from the cooling device 50 can be taken into the interior of the disaster cot 10, the cooling device 50 that purifies the air can eliminate odors trapped inside buildings such as evacuation shelters. It is possible to ventilate the air with purified cool air, further improving comfort.

The air conditioner for the disaster cot according to the first and second embodiments described above has a configuration in which the distribution wind pipes 34 are installed symmetrically on both sides of the main wind pipe 32, but the distribution wind pipes 34 are installed alternately. A configuration may also be adopted in which an attachment portion 3206 is provided and attached asymmetrically. Further, an attachment portion 3206 may be provided so that the distribution wind pipe 34 can be attached to only one side of the main wind pipe 32. This is advantageous in protecting the privacy of sick people and the like who use the disaster cot 10.

Further, although the first and second air conditioners for the plurality of disaster cots are used for disaster cots such as those in evacuation centers, they are not limited to disaster cots in evacuation centers. It may also be used for multiple emergency cots placed at home.
Further, the use of the air conditioner is not limited to a cot for use in times of disaster, but can be used in accordance with various situations during times of disaster. Therefore, for example, air or cold air can be sent into the interior of a simple tent or the like set up in a shelter to improve the comfort of a sick person lying inside the tent, suppress the deterioration of the condition, and protect the sick person. is also possible.

1, 2 Air conditioner 10 Cot for emergencies 12 Frame 16 Sheet for lying down 18 Blindfold sheet 20 Air blower 20A Input reception section 20B Power control section 20C Air volume adjustment section 20D Timer section 20E Display control section 22 Suction port 24 Air outlet 30 Air blower Pipe 32 Main wind pipe 3202, 3204 End part 3204 Strap 3206 Attachment part 3206A Opening part 34 Distribution wind pipe 34A Exhaust port 3402 Outer part 3404 Fastener 3406 Attachment part 3406 Opening part 50 Air conditioner 60 Piping 6002 First piping 6004 Second Piping 6006 Third piping

Claims (7)

An air conditioner for a plurality of cots for disaster use, comprising a reclining sheet provided above the floor surface on which a user lies, and a blindfold sheet covering the periphery and above of the reclining sheet,
a blower driven by electricity;
The air outlet of the blower is connected to the inside of the blindfold sheet of each of the plurality of disaster cots, and the air sent out by the blower is connected to the inside of the blindfold sheet of each of the plurality of disaster cots. A blow pipe that sends air into the interior,
Equipped with
The blower pipe is composed of a main wind pipe that is detachably attached to the air outlet, and a plurality of distribution wind pipes that are branched from the main wind pipe and provided with exhaust ports that discharge air,
The plurality of distribution wind pipes are inserted below the lying sheet of each of the plurality of disaster cots,
The exhaust port is openably and closably provided on the upper surface of the plurality of distribution wind pipes so as to discharge air upward, and discharge air toward the lower surface of the lying sheet.
An air conditioning system for multiple cots for disaster situations, which is characterized by: The main wind pipe has an opening and is provided with a plurality of attachment parts for detachably attaching the plurality of distribution wind pipes,
In the plurality of attachment parts, the opening part is closed when the distribution wind pipe is not attached.
The air conditioner for a plurality of cots for disaster use according to claim 1 . further comprising a battery unit made of a primary battery or a secondary battery that supplies power to the blower;
The air conditioner for a plurality of emergency cots according to claim 1 or 2 . a battery section consisting of a primary battery or a secondary battery that supplies power to the blower;
A commercial power supply section using commercial power supply,
comprising a power supply switching section that switches between the battery section and the commercial power supply section and connects it to the blower;
The air conditioner for a plurality of emergency cots according to claim 1 or 2 . further comprising a generator that generates electric power and supplies it to the blower;
The air conditioner for a plurality of emergency cots according to claim 1 or 2 . The air pipe is made of a collapsible material.
The air conditioning system for a plurality of cots for disaster use according to any one of claims 1 to 5 . A cooling device that sends out cold air,
Further comprising piping that is detachably attached to a cold air outlet of the cooling device and an air suction port of the blower, and sends cold air sent out by the cooling device to the blower,
The blower sends out cold air sucked from the suction port,
The blow pipe sends cold air sent out by the blower into the inside of the blindfold sheet of each of the plurality of disaster cots.
The air conditioner for a plurality of cots for disaster use according to any one of claims 1 to 6 .

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