KR20070054227A - Ventilating device and building - Google Patents

Abstract

It is an object of the present invention to provide a ventilation device having an indirect vaporization cooling function that can be installed in a house.

The ventilation device 1A includes a water supply and drainage device 12 that supplies water to the indirect vaporization element 11 of the indirect vaporization cooling unit 4. The water supply and drainage device 12 includes a water supply valve 12a that controls the supply of water to the indirect vaporization element 11, a drain pan 13 that receives water, and a drain valve that controls the drainage of the water of the drain pan 13 ( 12b), the supply / drainage control is performed in accordance with the level of water and the like accumulated in the drain pan 13.

Drain Fan, Drainage, Ventilation

Description

Ventilation and Buildings {VENTILATING DEVICE AND BUILDING}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ventilator installed in a house and ventilating indoors and outdoors, and to a building provided with the ventilator. Specifically, the present invention relates to a ventilator and a building having an indirect vaporization cooling function for cooling air by using vaporization heat of water. It is about.

Conventionally, although the air conditioning apparatus which cools a building is proposed, the air conditioning apparatus provided with the indirect vaporization cooling apparatus which cools air using the heat of vaporization of water is proposed (for example, refer Unexamined-Japanese-Patent No. 2004-190907). ). The indirect vaporization cooling device is configured to exchange sensible heat (temperature) between flow paths partitioned by partition walls, to cool air by using vaporization heat of water in one flow path, and to exchange cold heat with the other flow path, The air passing through the other flow path is cooled and supplied to the room.

The air conditioner provided with the conventional indirect vaporization cooling apparatus is installed in an office, a store, etc., and installation in a house is not considered. In the case where the air conditioner provided with an indirect vaporization cooling device is installed in a house, the treatment of water used for cooling becomes important, but there is a problem that the conventional device does not include a water treatment device suitable for use in a house. In addition, there is a problem that the operating cost can not be suppressed by reducing the consumption of water.

This invention is made | formed in order to solve such a subject, and an object of this invention is to provide the ventilation apparatus provided with the indirect vaporization cooling function which can be installed in a house, and the building provided with such a ventilation apparatus.

In order to solve the above-mentioned problems, the invention of claim 1 provides a supply air passage communicating with the air supply outlet from an outside air intake port, an exhaust passage communicating with the exhaust outlet from the ventilation intake port, and working air supplied in communication with the supply air passage or the exhaust passage. It has a working air flow path and a product air flow path supplied with the product air in communication with the supply air flow path, the working air is cooled by the heat of vaporization of water, and the working air and the product air flow path between the working air flow path and the product air flow path partitioned by the partition wall. A water supply and drainage device having an indirect vaporization cooling unit in which sensible heat exchange is performed, a water supply device to the indirect vaporization cooling unit, a drain pan receiving watered water and a drainage device from the drain pan, and a drainage device to control the water in the drain pan. And control means for draining the water.

According to a second aspect of the present invention, there is provided an air supply passage communicating with an air supply outlet from an outside air intake port, an exhaust passage communicating with an exhaust outlet from an external air intake port, and a working air passage and a supply air passage supplied with working air in communication with the exhaust passage. An indirect vaporization cooling unit having a product air flow path to which air is supplied, wherein the working air is cooled by the heat of vaporization of water, and sensible heat exchange between the working air and the product air is performed between the working air flow path and the product air flow path partitioned by the partition wall; And a water supply and drainage device having a water supply device to an indirect vaporization cooling unit, a drain pan receiving watered water, and a drainage device from the drain pan, and control means for controlling the drainage device to drain the water of the drain pan. do.

According to a third aspect of the present invention, there is provided an air supply passage communicating with a supply air inlet port from a ventilation inlet port, an exhaust passage communicating with an exhaust outlet port from a ventilation intake port, and a working air passage and a supply air passage in which working air is supplied in communication with the exhaust passage line. An indirect vaporization cooling unit having a product air flow path to which air is supplied, wherein the working air is cooled by the heat of vaporization of water, and sensible heat exchange between the working air and the product air is performed between the working air flow path and the product air flow path partitioned by the partition wall; And a water supply and drainage device having a water supply device to an indirect vaporization cooling unit, a drain pan receiving watered water, and a drainage device from the drain pan, and control means for controlling the drainage device to drain the water of the drain pan. do.

In the invention of Claims 1 to 3, overflow is prevented by receiving water supplied to the indirect vaporization cooling unit with a drain pan and draining it when the water storage amount exceeds a predetermined amount.

According to a tenth aspect of the present invention, there is provided an air supply passage communicating with an air supply outlet from an outside air intake port, an exhaust passage communicating with the exhaust outlet through a ventilation intake port, a working air passage and an air supply passage for supplying working air in communication with the supply passage or the exhaust passage; Indirect vaporization cooling in which product air flows in communication with product air, and the working air is cooled by the heat of vaporization of water, and the sensible heat exchange between the working air and the product air is performed between the working air flow path and the product air flow path partitioned by the partition wall. A unit, a water supply and drainage device installed in the indirect vaporization cooling unit to perform water supply and drainage, and a recovery device for recovering the vaporized water from the indirect vaporization cooling unit and reusing it for water supply.

According to the eleventh aspect of the present invention, there is provided an air supply passage communicating with an air supply outlet from an external air intake port, an exhaust passage communicating with an exhaust outlet from an external air intake port, and a working air passage and a supply air passage supplied with working air in communication with the exhaust passage. An indirect vaporization cooling unit having a product air flow path to which air is supplied, wherein the working air is cooled by the heat of vaporization of water, and sensible heat exchange between the working air and the product air is performed between the working air flow path and the product air flow path partitioned by the partition wall; It is provided with the water supply and drainage apparatus provided in an indirect vaporization cooling unit to perform water supply and drainage, and the collection | recovery apparatus which collect | recovers the vaporized water in an indirect vaporization cooling unit, and reuses it for water supply.

According to a twelfth aspect of the present invention, there is provided an air supply passage communicating with a supply air outlet from a ventilation intake port, an exhaust passage communicating with an exhaust outlet from a ventilation intake port, and a working air passage and a supply air passage supplied with working air in communication with the exhaust passage. An indirect vaporization cooling unit having a product air flow path to which air is supplied, wherein the working air is cooled by the heat of vaporization of water, and sensible heat exchange between the working air and the product air is performed between the working air flow path and the product air flow path partitioned by the partition wall; It is provided with the water supply and drainage apparatus provided in an indirect vaporization cooling unit to perform water supply and drainage, and the collection | recovery apparatus which collect | recovers the vaporized water in an indirect vaporization cooling unit, and reuses it for water supply.

In the invention of Claims 10 to 12, water consumption can be suppressed by recovering the vaporized water in the indirect vaporization cooling unit and reusing it for the water supply to the indirect vaporization cooling unit.

The invention according to claim 16 is provided with such a ventilation device.

According to the ventilation device of the present invention, by controlling the drain of the drain pan receiving the water supplied to the indirect vaporization cooling unit, overflow can be prevented without oversizing the drain pan, or the unnecessary water can be drained at the time of operation stop. There is drainage treatment suitable for use in house.

In addition, by recovering the vaporized water in the indirect vaporization cooling unit and reused in the feed water to the indirect vaporization cooling unit, it is possible to reduce the consumption of water and to suppress operating costs.

Therefore, the ventilation device provided with the indirect vaporization cooling function which has the performance required for installation in a house can be provided compactly and inexpensively.

In a building equipped with such a ventilation device, air conditioning is performed while ventilation of the outside air and the air inside the building can provide a comfortable living space, and at the same time, power consumption can be reduced by air conditioning with water. Can be. In addition, the consumption of water can also be suppressed by recovering and reusing water.

1 is a configuration diagram showing an example of the ventilation device 1A of the first embodiment.

2A is an explanatory diagram showing an outline of an indirect vaporizing element.

2B is an explanatory diagram showing an outline of an indirect vaporizing element.

2C is an explanatory diagram showing an outline of an indirect vaporizing element.

3 is a graph showing the relationship between the flow rate of the working air WA and the outlet temperature of the product air PA.

4 is a graph showing the relationship between the flow rate of the product air PA and the outlet temperature of the product air PA.

5 is a graph showing the relationship between the inlet temperature of the working air WA and the product air PA and the outlet temperature of the product air PA.

6 is a graph showing the relationship between the intake temperature of the working air WA and the product air PA and the consumption of water.

7 is a graph showing the relationship between the inlet humidity of the working air WA and the product air PA and the outlet temperature of the product air PA.

8 is a configuration diagram showing an example of the ventilation device 1B of the second embodiment.

9 is a configuration diagram showing an example of the ventilation device 1C according to the third embodiment.

10A is a configuration diagram showing an example of the ventilation device 1D according to the fourth embodiment.

10B is a comparative example of the configuration with the heat exchange unit and the configuration without the heat exchange unit.

11 is a configuration diagram showing an example of the ventilation device 1E of the fifth embodiment.

12 is a configuration diagram showing an example of the ventilation device 1F of the sixth embodiment.

13A is a configuration diagram showing an example of the ventilation device 1G of the seventh embodiment.

13B is an example of the effect of the structure provided with a dehumidification unit.

14 is a configuration diagram showing an example of the ventilation device 1H of the eighth embodiment.

15 is a configuration diagram showing an example of the ventilation device 1I of the ninth embodiment.

16 is a configuration diagram showing an example of the ventilation device 1J of the tenth embodiment.

17 is a configuration diagram showing an example of the ventilation device 1K of the eleventh embodiment.

18 is a configuration diagram showing an example of the ventilation device 1L of the twelfth embodiment.

19 is a graph showing the relationship between the rotational speed of the dehumidifying rotor and the outlet temperature of the product air PA.

20 is a configuration diagram showing an example of the ventilation device 1M of the thirteenth embodiment.

FIG. 21: is a block diagram which shows an example of the ventilation apparatus 1N of 14th Embodiment.

22 is a configuration diagram showing an example of the ventilation device 1P of the fifteenth embodiment.

FIG. 23 is a configuration diagram showing an example of the ventilation device 1Q of the sixteenth embodiment.

24 is a configuration diagram showing an example of the ventilation device 1R of the seventeenth embodiment.

25 is a configuration diagram showing an example of the ventilation device 1S of the eighteenth embodiment.

FIG. 26A is a perspective view illustrating an example of a configuration of main parts of the ventilation device of each embodiment. FIG.

FIG. 26B is a perspective view illustrating an example of a configuration of main parts of the ventilation device of each embodiment. FIG.

27 is a diagram showing the configuration of main parts of the ventilation device of each embodiment.

28 is a diagram showing the configuration of another main part of the ventilation device in each embodiment.

FIG. 29A is a configuration diagram of another indirect vaporizing element illustrating a main part configuration of the ventilation device of each embodiment. FIG.

FIG. 29B is a configuration diagram of another indirect vaporizing element illustrating a main part configuration of the ventilation device of each embodiment. FIG.

FIG. 29C is a configuration diagram of another indirect vaporizing element illustrating a main part configuration of the ventilation device of each embodiment. FIG.

30 is a configuration diagram showing an example of a building of the present embodiment.

31 is a configuration diagram showing an example of an air supply port.

32 is a configuration diagram showing an example of the ventilation device 1T of the nineteenth embodiment.

33 is a block diagram showing an example of a control function of a ventilation device.

34 is a flowchart showing an example of cooling control by the temperature sensor.

35 is a flowchart showing another example of cooling control by the temperature sensor.

36 is a flowchart showing an example of cooling control by a human body sensor.

37 is a flowchart showing an example of ventilation amount control by a human body sensor.

38 is a flowchart showing an example of manual start / stop control.

39 is a flowchart showing an example of automatic start / stop control.

40 is a configuration diagram showing an example of a drain pan.

41 is a flowchart showing an example of drainage control.

42A is a block diagram showing a first embodiment of an indirect vaporization cooling unit equipped with a water recovery device.

42B is a configuration diagram showing the first embodiment of the indirect vaporization cooling unit including the water recovery device.

FIG. 43A is a block diagram showing a second embodiment of an indirect vaporization cooling unit including a water recovery device. FIG.

FIG. 43B is a configuration diagram showing a second embodiment of the indirect vaporization cooling unit provided with a water recovery device. FIG.

FIG. 44A is a block diagram showing a third embodiment of an indirect vaporization cooling unit equipped with a water recovery device. FIG.

44B is a configuration diagram showing a third embodiment of the indirect vaporization cooling unit equipped with a water recovery device.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to drawings, embodiment of the ventilator and building of this invention is described.

<Configuration of Ventilator 1A of First Embodiment>

1 is a configuration diagram showing an example of the ventilation device 1A of the first embodiment. The ventilation device 1A of the first embodiment includes an air supply fan 2, an exhaust fan 3, and an indirect vaporization cooling unit 4.

In addition, the ventilation device 1A includes an outdoor air intake port 5 for sucking outside air (OA) from the outside, and an air supply outlet 6 for blowing supply air (SA) into the room. . In addition, the ventilation device 1A includes a ventilation intake port 7 that sucks in the return air (RA) from the room, and an exhaust blower outlet 8 that blows out the exhaust air (EA) to the outdoors. do. In addition, each outlet and each suction port are connected with the indoor and the outdoor through a duct which is not shown, for example.

The air supply fan 2 and the exhaust fan 3 are, for example, a Sirocco fan, and the air supply fan 2 is in the air supply flow path 9A communicated from the external air intake port 5 to the air supply outlet 6. Generates a flow of air toward the air supply outlet 6. The exhaust fan 3 also generates a flow of air toward the exhaust outlet 8 in the exhaust passage 10A communicated from the ventilation inlet 7 to the exhaust outlet 8.

The indirect vaporization cooling unit 4 includes an indirect vaporization element 11, a water supply and drainage device 12, a drain pan 13, and the like. The indirect vaporization element 11 has a working air passage 11a through which the working air WA cooled by the heat of vaporization of water passes and a product air PA in which sensible heat (temperature) is exchanged between the working air WA. The product air flow path 11b which passes is provided.

The water supply and drainage device 12 has a water supply valve 12a composed of, for example, an electromagnetic valve, and is configured to control the water supply to the indirect vaporization element 11. The drain pan 13 receives the water supplied to the indirect vaporization element 11 in the water supply and drainage device 12. Moreover, the water supply and drainage apparatus 12 is a structure which can drain the water of the drain pan 13 by providing the drain valve 12b comprised as an electromagnetic valve, for example.

The water supply and drainage device 12 is a configuration in which water is dropped or sprinkled from the upper side of the indirect vaporization element 11 to be received by the drain pan 13. The water supply valve 12a of the water supply and drainage device 12 may be configured to be connected to a water pipe, or may be configured to use stored rainwater. The details of the water supply and drainage operation will be described later.

The air supply flow path 9A communicates from the outdoor air intake port 5 to the air supply outlet 6 through the air supply fan 2 and the product air flow path 11b of the indirect vaporization element 11. The exhaust flow passage 10A communicates from the ventilation intake port 7 to the exhaust outlet 8 through the working air flow passage 11a of the indirect vaporization element 11 and the exhaust fan 3.

The air supply flow path 9A includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the indirect vaporization cooling unit 4. The air supply flow rate adjustment damper 14 constitutes a flow rate control means, includes a damper for adjusting the flow rate of air by opening and closing, and a motor for driving the damper, and adjusts the opening degree of the air supply flow rate adjustment damper 14. The flow rate of air flowing through the flow path 9A is adjusted. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 which comprises the indirect vaporization cooling unit 4 is adjusted.

The exhaust flow path 10A includes, for example, an exhaust flow rate adjustment damper 15 on an upstream side of the indirect vaporization cooling unit 4. The exhaust flow rate adjustment damper 15 constitutes a flow rate control means, is provided with a damper for adjusting the flow rate of air by opening and closing, and a motor for driving the damper, and exhausting the exhaust flow rate adjustment damper 15 by adjusting the opening degree. The flow rate of air flowing through the flow path 10A is adjusted. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 which comprises the indirect vaporization cooling unit 4 is adjusted.

In addition, the air supply flow path 9A includes an air cleaning filter 16 as an air cleaning device on the upstream side of the indirect vaporization cooling unit 4, for example. By providing the air cleaning filter 16 in the air supply flow path 9A, the air supply SA from which dust and the like has been removed from the outside air OA is supplied to the room. In addition, the air cleaning filter 16 is disposed upstream of the indirect vaporization cooling unit 4 to prevent intrusion of dust or the like into the indirect vaporization element 11.

Moreover, the air supply temperature is detected by providing the temperature sensor 17 in the air supply flow path 6 in the air supply flow path 9A.

<Configuration of indirect vaporization element>

2A to 2C are explanatory views showing an overview of the indirect vaporization element 11, FIG. 2A is an overall configuration of the indirect vaporization element 11, FIG. 2B is a major part configuration of the indirect vaporization element 11, and FIG. 2C is a cooling principle. Indicates.

The indirect vaporization element 11 includes a plurality of dry cells 21 having a plurality of first flow passages 21b partitioned into partitions 21a and a plurality of partitions 22a as shown in FIG. 2B. The wet cell 22 which has the 2nd flow path 22b, and the partition 23 which partitions the dry cell 21 and the wet cell 22 are provided.

The dry cell 21 and the wet cell 22 are stacked with the partitions 23 interposed therebetween in an orientation in which the first flow passage 21b and the second flow passage 22b are perpendicular to each other.

The partition wall 23 includes a moisture proof film 23a formed of a polyethylene film or the like and a wet layer 23b formed of pulp or the like, as shown in FIG. 2C, and the moisture proof film 23a is formed on the dry cell 21. And the wet layer 23b faces the wet cell 22.

In addition, as shown in Fig. 2B, the partition 23 is provided with a vent hole 23c for communicating a part of the first flow passage 21b and the second flow passage 22b. In addition, as shown in Fig. 2A, a blocking portion 24 is formed at the outlet of the first flow path 21b in which the vent hole 23c is formed, so that air does not escape.

Thereby, in the indirect vaporization element 11, the working air flow path 11a is the 1st flow path 21b, the ventilation hole 23c, and the 2nd from the inlet of the 1st flow path 21b in which the ventilation hole 23c was formed. It communicates with the exit of the 2nd flow path 22b through the flow path 22b. In addition, the product air flow passage 11b communicates with the outlet of the first flow passage 21b through the first flow passage 21b from the inlet of the first flow passage 21b where the vent hole 23c is not formed.

The outline of the cooling principle by the indirect vaporizing element 11 will be described with reference to FIG. 2C. Here, although the working air WA and the product air PA flow in an orthogonal orientation, in Fig. 2C, the orientations in which the working air WA and the product air PA flow are shown in parallel.

Water is supplied to the wet layer 23b facing the working air passage 11a by the water supply and drainage device 12 shown in FIG. As a result, water vaporizes due to the temperature difference between the working air WA passing through the working air flow passage 11a and the wet layer 23b, and the working air WA is cooled.

When the working air WA is cooled, the product air PA passing through the product air flow passage 11b partitioned into the working air flow passage 11a and the partition 23 is cooled by receiving heat of heat through the partition 23.

Here, since the moisture proof film 23a which comprises the partition 23 does not let moisture pass through, even if the product air PA passes through the product air flow path 11b, absolute humidity does not change. In addition, when the working air WA passes through the working air flow passage 11a, it becomes high humidity.

As an example, when the input temperature of the product air (PA) and the working air (WA) is 30 ° C, the absolute humidity is 10 g / kg (DA: dry air), and the relative humidity is about 40% RH, the product air (PA) Outlet temperature is lowered to 20 ° C. Relative humidity rises to about 70% RH because the temperature decreases, but absolute humidity does not change to 10 g / kg (DA).

In addition, the outlet temperature of the working air WA falls to 23 ° C. However, absolute humidity goes up to 16 g / kg (DA).

<Cooling principle of indirect vaporization element>

The cooling principle of the indirect vaporization element 11 is the temperature Td of the product air PA, the absolute humidity Xd, the air volume Gd, the temperature Tw of the working air WA, the absolute humidity Xw, and the air volume. (Gw) and other parameters can be expressed as follows.

(1) From the law of conservation of energy

[1]

(2) from the law of conservation of mass

[2]

G _d : Product air flow rate [㎏ '/ s]

G _w : Working air flow rate [㎏ '/ s]

h _d : product air enthalpy [J / kg ']

h _w : Working air enthalpy [J / kg ']

h _di : Product air enthalpy at the inlet [J / ㎏ ']

h _wi : Working air enthalpy at entrance [J / kg ']

V _d : air amount per kilogram of product air [kg ']

V _w : Air amount per one cell of working air [kg ']

T _d : temperature of product air [℃]

T _w : Temperature of working air [℃]

X _d : absolute humidity of product air [㎏ / ㎏ ']

X _w : absolute humidity of working air [㎏ / ㎏ ']

X _di : Absolute humidity of product air at inlet [㎏ / ㎏ ']

X _wi : Absolute humidity of the working air at the inlet [㎏ / ㎏ ']

X _k : Absolute humidity near the wet layer [㎏ / ㎏ ']

α _d : Product air-side thermal conductivity [J / (m 2 · K · s)]

α _w : working air side thermal conductivity [J / (m 2 · K · s)]

α _G : mass transfer rate [m / s] of evaporation (defined as a function of wind speed, not integer)

ρ _a : Dry air density [㎏ '/ ㎥]

C _pw : specific heat of water [J / (㎏ · K)]

W: weight of wet water of one cell [kg]

γ: latent heat of evaporation of water [J / ㎏]

ΔA: area for one cell [m 2]

(3) Relationship between the flow rate of the working air WA and the outlet temperature of the product air PA

From the above-mentioned formula, the relationship between the flow volume of the working air WA in the indirect vaporization element 11, and the outlet temperature of the product air PA is calculated | required, and is shown in the graph of FIG.

3 is a graph showing the relationship between the flow rate of the working air WA and the outlet temperature of the product air PA. The conditions of the working air WA and the product air PA input to the indirect vaporization element 11 are absolute. Humidity 5.26 g / kg (DA: dry air), inlet temperature 30 ℃ fixed, product air (PA) flow rate is set to 50 m 3 / hour fixed.

It can be seen from FIG. 3 that the outlet temperature of the product air PA decreases as the flow rate of the working air WA increases. In addition, although the air cooled by the indirect vaporization element 11 has a temperature distribution, the temperature data of each example is described as the minimum temperature.

(4) Relationship between the flow rate of the product air PA and the outlet temperature of the product air PA

From the above-mentioned formula, the relationship between the flow volume of the product air PA in the indirect vaporization element 11, and the outlet temperature of the product air PA is calculated | required, and is shown in the graph of FIG.

4 is a graph showing the relationship between the flow rate of the product air PA and the outlet temperature of the product air PA. The conditions of the working air WA and the product air PA input to the indirect vaporization element 11 are absolute. The humidity is 5.26 g / kg (DA), the inlet temperature is fixed at 30 ° C., and the flow rate of the working air (WA) is set to 50 m 3 / hour.

It can be seen from FIG. 4 that the outlet temperature of the product air PA is lowered as the flow rate of the product air PA is lower.

(5) Relationship between inlet temperature of working air WA and product air PA and outlet temperature of product air PA

From the above-mentioned formula, the relationship between the inlet temperature of the working air WA and the product air PA in the indirect vaporization element 11, and the outlet temperature of the product air PA is calculated | required, and is shown in the graph of FIG.

FIG. 5 is a graph showing the relationship between the inlet temperature of the working air WA and the product air PA and the outlet temperature of the product air PA. The working air WA and the product air input to the indirect vaporization element 11 are shown in FIG. The condition of PA is set to 5.26 g / kg (DA) of absolute humidity and the flow rate is set to 50 m 3 / hour.

It can be seen from FIG. 5 that the outlet temperature of the product air PA increases as the inlet temperatures of the working air WA and the product air PA are higher.

(6) Relation between inlet temperature of working air (WA) and product air (PA) and water consumption

From the above-mentioned formula, the relationship between the intake temperature of the working air WA and the product air PA in the indirect vaporization element 11, and the consumption amount of water is calculated | required, and is shown in the graph of FIG.

6 is a graph showing the relationship between the intake temperature of the working air WA and the product air PA and the consumption of water. The conditions of the working air WA and the product air PA input to the indirect vaporization element 11 are shown in FIG. The absolute humidity is 5.26 g / kg (DA) and the flow rate is fixed at 50 m3 / hour.

It can be seen from FIG. 6 that the higher the inlet temperature of the working air WA and the product air PA, the greater the consumption of water used for cooling.

Accordingly, it can be seen from FIGS. 5 and 6 that when the inlet temperatures of the working air WA and the product air PA are lowered, the outlet temperature of the product air PA is lowered and the water consumption is reduced.

(7) Relationship between inlet humidity of working air WA and product air PA and outlet temperature of product air PA

From the above-mentioned formula, the relationship between the inlet humidity of the working air WA and the product air PA in the indirect vaporization element 11, and the outlet temperature of the product air PA is calculated | required, and is shown in the graph of FIG.

7 is a graph showing the relationship between the inlet humidity of the working air WA and the product air PA, and the outlet temperature of the product air PA. The working air WA and the product air input to the indirect vaporization element 11 are shown in FIG. The condition of (PA) is a temperature of 30 ° C. and a flow rate of 50 m 3 / hour is fixed.

It can be seen from FIG. 7 that the outlet temperature of the product air PA is lowered as the inlet humidity of the working air WA and the product air PA is lower.

From the above, the indirect vaporization element 11 has a flow rate of the working air WA, a flow rate of the product air PA, an inlet temperature of the working air WA, an inlet temperature of the product air PA, and a working air WA. It can be seen that the outlet temperature of the product air PA can be controlled by controlling the inlet humidity of the product, the inlet humidity of the product air PA, and the like.

<Operation of the Ventilator 1A of the First Embodiment>

Next, with reference to FIG. 1 etc., operation | movement of the ventilation apparatus 1A of 1st Embodiment is demonstrated. When the air supply fan 2 is driven, the ventilation device 1A generates a flow of air toward the air supply outlet 6 in the air supply flow path 9A. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the product air flow path 11b of the air cleaning filter 16 and the indirect vaporization element 11 as the air supply SA from the air supply outlet 6. It is supplied indoors.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10A. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. .

Therefore, in the ventilation device 1A, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

In addition, the air supply valve 12a of the water supply and drainage device 12 is opened to supply water to the indirect vaporization element 11, and the wet layer 23b shown in Figs. 2A to 2C always contains water. .

As described with reference to Figs. 2A to 2C, in the indirect vaporization element 11, when the working air WA passing through the working air flow path 11a is cooled by the heat of vaporization of water, and the working air WA is cooled, the product air flow path The product air PA passing through 11b is cooled by receiving the heat of cooling of the working air WA.

In addition, since no movement of humidity occurs between the working air passage 11a and the product air passage 11b, the outside air OA that has passed through the product air passage 11b of the indirect vaporization element 11 is subjected to humidity (absolute). Humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Moreover, since the ventilation RA which passed the working air flow path 11a of the indirect vaporization element 11 turns into high humidity air, it is discharged | emitted as exhaust EA from the exhaust outlet 8.

In the ventilation device 1A, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow rate adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, by operating either one of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 to adjust the flow rate of the product air PA and the flow rate of the working air WA, it is described in Figures 3 and 4 As described, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

That is, when the flow rate of the working air WA is increased by controlling the opening degree of the exhaust flow rate adjusting damper 15, the outlet temperature of the product air PA in the indirect vaporization element 11 is lowered. Therefore, the air supply temperature from the air supply outlet 6 can be lowered.

In addition, when the flow rate of the working air WA is reduced by controlling the opening degree of the exhaust flow rate adjusting damper 15, the outlet temperature of the product air PA in the indirect vaporization element 11 increases. Therefore, the air supply temperature from the air supply outlet 6 can be raised.

In addition, when the flow rate of the product air PA is increased by controlling the opening degree of the air supply flow rate adjusting damper 14, the outlet temperature of the product air PA in the indirect vaporization element 11 increases. Therefore, the air supply temperature from the air supply outlet 6 can be raised.

In addition, when the flow rate of the product air PA is reduced by controlling the opening degree of the air supply flow rate adjusting damper 14, the outlet temperature of the product air PA in the indirect vaporization element 11 is lowered. Therefore, the air supply temperature from the air supply outlet 6 can be lowered.

In this way, since the air supply temperature can be controlled by adjusting the flow rate of either the product air PA or the working air WA, one of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 is provided. The configuration may be.

In addition, by operating both of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15, the flow rate of the product air PA and the flow rate of the working air WA are also adjusted to the indirect vaporization element 11. The outlet temperature of the product air PA in is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA can be adjusted.

Therefore, the product air in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. The outlet temperature of PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The above-mentioned temperature control can also be performed manually by the setting switch mentioned later, and can also be automatically adjusted to temperature using the temperature sensor 17 etc.

In addition, the temperature of the room is lowered by using the ventilation device 1A in summer. Therefore, the temperature of the ventilation RA is also low. As described in FIG. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA is lowered, so that the product air PA can be efficiently used by using the ventilation RA as the working air WA. Supply temperature can be controlled by lowering the outlet temperature of

By using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1A has a function of cooling while performing ventilation.

In addition, according to the Building Standard Act, it is necessary to install a ventilation system that can replace the air in a house at a predetermined time, and use a ventilator or the like to forcibly perform ventilation using a fan. It is possible to replace.

Since the ventilation device 1A of the present example has a function of cooling while performing ventilation, the air in the room at a predetermined time is adjusted by adjusting the flow rate of the ventilation RA and the flow rate of the air supply SA without providing another ventilation device. It is possible to use ventilation as a replacement device for 24 hours. For this reason, in the ventilation device 1A, the temperature is controlled by the flow rate of the working air WA or the flow rate of the product air PA, so that the desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

The 24-hour ventilation function is a function of continuously or intermittently ventilating to satisfy a predetermined number of times of ventilation (for example, 0.5 times / hour) of an area to be ventilated in a building. This may satisfy the predetermined number of times of ventilation only with the ventilation device 1, or may provide a predetermined number of times of ventilation by adding the ventilation amounts of other ventilation devices. In addition, in order to reduce the predetermined number of times of ventilation in winter or the like, the switch or the temperature of the operation means may be detected and switched manually or automatically, so that the amount of ventilation airflow may be reduced for 24 hours.

<Configuration of Ventilator 1B of Second Embodiment>

8 is a configuration diagram showing an example of the ventilation device 1B of the second embodiment. The ventilation device 1B according to the second embodiment uses the outside air OA for the working air WA of the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4. In addition, in the ventilation apparatus 1B of 2nd Embodiment, the same component as the 1st ventilation apparatus of 1st Embodiment is attached | subjected and demonstrated.

The ventilator 1B is provided with an air supply flow path 9B which communicates with the air supply fan 2 and the product air flow path 11b of the indirect vaporization element 11 from the outside air intake port 5 to the air supply outlet 6. do.

In addition, the ventilation device 1B branches from the air supply fan 2 on the downstream side with the air supply flow path 9B, passes through the working air flow path 11a and the exhaust fan 3 of the indirect vaporization element 11, and the exhaust outlet port ( The first exhaust flow path 10B communicating with 8) and the second exhaust flow path 10C communicating with the exhaust outlet 8 through the exhaust fan 3 from the ventilation inlet 7 are provided. In addition, the part shown with the broken line of the 2nd exhaust flow path 10C is formed along the side wall of a case, for example so that it may become independent from the air supply flow path 9B.

The air supply flow path 9B is provided with the air supply flow volume adjustment damper 14 downstream from the branch position with the 1st exhaust flow path 10B, for example upstream of the indirect vaporization cooling unit 4. Moreover, the 1st exhaust flow path 10B is equipped with exhaust flow volume adjustment damper 15 downstream from the branch position with the air supply flow path 9B, for example, upstream of the indirect vaporization cooling unit 4.

The flow rate of the air which flows through the air supply flow path 9B is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

Moreover, the flow volume of the air which flows through the 1st exhaust flow path 10B is adjusted by adjusting the opening degree of the exhaust flow volume adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

Moreover, the air supply flow path 9B is equipped with the air cleaning filter 16 upstream rather than a branch position with the 1st exhaust flow path 10B, for example. In addition, the air supply flow path 9B includes a temperature sensor 17 at the air supply outlet 6.

<Operation of the Ventilator 1B of the Second Embodiment>

Next, operation | movement of the ventilation apparatus 1B of 2nd Embodiment is demonstrated with reference to FIG. When the air supply fan 2 is driven, the ventilation device 1B generates a flow of air toward the air supply outlet 6 in the air supply flow path 9B. As a result, the outside air OA is sucked from the outside air intake port 5, and is supplied to the room as the air supply SA from the air supply outlet 6 through the product air flow path 11b of the indirect vaporization element 11.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10B and the second exhaust passage 10C. As a result, a part of the outside air OA is discharged to the outside as the exhaust EA from the exhaust outlet 8 through the working air passage 11a of the indirect vaporizing element 11 by the first exhaust passage 10B. In addition, the ventilation RA from the room is sucked from the ventilation intake port 7 by the second exhaust flow path 10C, and is discharged from the exhaust blowout port 8 to the outside as the exhaust EA.

Accordingly, in the ventilation device 1B, the outside air OA becomes the product air PA and the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

In addition, since the outside air OA which has passed through the working air flow path 11a of the indirect vaporization element 11 becomes air of high humidity, it is discharged | emitted as exhaust EA from the exhaust outlet 8.

In the ventilation device 1B, similar to the ventilation device 1A of the first embodiment, the product air passing through the product air flow path 11b of the indirect vaporization element 11 by the degree of opening of the air supply flow rate adjustment damper 14. The flow rate of PA is adjusted. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, by operating either or both of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, the flow volume of the product air PA, the flow volume of the working air WA, or the flow volume of both are adjusted, 3 and 4, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA is adjustable.

Therefore, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Since the ventilator 1B has a function of exhausting the ventilation RA to the outdoors, the ventilator 1B can cool and blow the outside air while exhausting the indoor air to the outdoors, and the ventilator 1B performs cooling while ventilating. It has a function.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation apparatus 1B, since temperature control is performed by the flow volume of the working air WA and the flow volume of the product air PA, ventilation operation | movement is possible so that a desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1C of Third Embodiment>

9 is a configuration diagram showing an example of the ventilation device 1C according to the third embodiment. The ventilation device 1C according to the third embodiment includes an air supply flow path that bypasses the indirect vaporization cooling unit 4. In addition, in the ventilation apparatus 1C of 3rd Embodiment, the same component as the 1st ventilation apparatus of 1st Embodiment is attached | subjected and demonstrated.

The ventilation device 1C has an air supply passage 9C which communicates with the air supply fan 2 through the air supply fan 2 and the product air passage 11b of the indirect vaporizing element 11 to the air supply outlet 6. . The exhaust flow path 10A has the same configuration as the ventilation device 1A of the first embodiment.

In addition, the bypass device 1C branches from the air supply flow path 9C on the upstream side of the indirect vaporization cooling unit 4, bypasses the indirect vaporization cooling unit 4, and communicates with the air supply outlet 6. 10D is provided.

The bypass flow path 10D includes an air supply flow rate adjustment damper 18. The air supply flow rate adjustment damper 18 constitutes a flow rate control means, is provided with a damper for adjusting the flow rate of air by opening and closing, and a motor for driving the damper, and by adjusting the opening degree of the air supply flow rate adjustment damper 18. The flow rate of air flowing through the path flow path 10D is adjusted. Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Moreover, the air supply flow path 9C is provided with the air cleaning filter 16 at an upstream side, for example rather than the branch position with the bypass flow path 10D.

In the ventilation device 1C, the water supply valve 12b of the water supply and drainage device 12 is disposed below the indirect vaporization cooling unit 4. For example, it is good also as a structure which makes water supply so that the indirect vaporization element 11 may be immersed in the water accumulated in the drain pan 13.

<Operation of the Ventilator 1C of the Third Embodiment>

Next, the operation of the ventilation device 1C of the third embodiment will be described with reference to FIG. 9 and the like. When the air supply fan 2 is driven, the ventilation device 1C generates a flow of air toward the air supply outlet 6 in the air supply flow path 9C. As a result, the outside air OA is sucked from the outside air intake port 5, and is supplied to the room as the air supply SA from the air supply outlet 6 through the product air flow path 11b of the indirect vaporization element 11.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10A. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. .

Accordingly, in the ventilation device 1C, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

In the ventilation device 1C, the flow rate of the air flowing through the bypass flow path 10D is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 18.

Thereby, the flow volume of the air supplied to the air supply outlet 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Therefore, by operating the air supply flow rate adjusting damper 18 to adjust the flow rate of the air flowing through the bypass flow path 10D, the air cooled through the indirect vaporization cooling unit 4 and the indirect vaporization cooling unit 4 are bypassed. The mixing ratio of the air which has not passed and cooled is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1C can cool and blow out the outside air while exhausting indoor air to the outside by using the ventilation RA, and the ventilation device 1C has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation | movement which replaces air of a room in predetermined time is possible. For this reason, in the ventilation device 1C, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and the ventilation amount can be secured to ensure a predetermined ventilation amount. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1D of Fourth Embodiment>

10A is a configuration diagram showing an example of the ventilation device 1D according to the fourth embodiment. The ventilation device 1D of the fourth embodiment includes a heat exchange unit 31 in addition to the air supply fan 2, the exhaust fan 3, and the indirect vaporization cooling unit 4. In addition, in the ventilation apparatus 1D of 4th Embodiment, the same component as the 1st ventilation apparatus of 1st Embodiment is attached | subjected and demonstrated.

The heat exchange unit 31 includes a heat exchange element 32, a filter (not shown), and the like. The heat exchange element 32 is a heat exchange element material on which the first flow path 32a is formed and a heat exchange element material on which the second flow path 32b is formed, and the first flow path 32a and the second flow path 32b are perpendicular to each other. It is a crossflow heat exchanger stacked in an orientation. The 1st flow path 32a and the 2nd flow path 32b are partitioned by the partition which is not shown in figure, and sensible heat exchange is performed between the air supplied to the 1st flow path 32a and the 2nd flow path 32b.

The air supply flow path 9D constitutes the air supply fan 2, the first flow path 32a of the heat exchange element 32 constituting the heat exchange unit 31, and the indirect vaporization cooling unit 4 from the outside air intake port 5. The product air passage 11b of the indirect vaporization element 11 is communicated with the air supply air outlet 6.

The first exhaust flow path 10E communicates with the exhaust air outlet 8 through the working air flow path 11a of the indirect vaporization element 11 and the exhaust fan 3 from the ventilation intake port 7. In addition, the second exhaust flow path 10F communicates from the ventilation intake port 7 to the exhaust outlet 8 through the second flow path 32b of the heat exchange element 32 and the exhaust fan 3.

The air supply flow path 9D includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the heat exchange unit 31. The flow rate of the air which flows through the air supply flow path 9D is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

The 1st exhaust flow path 10E is equipped with the exhaust flow volume adjustment damper 15 in the upstream of the indirect vaporization cooling unit 4, for example. The flow rate of the air flowing through the first exhaust flow path 10E is adjusted by adjusting the opening degree of the exhaust flow rate adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

In addition, the air supply flow path 9D includes an air cleaning filter 16 on an upstream side of the heat exchange unit 31, for example. By arranging the air cleaning filter 16 upstream of the heat exchange unit 31, intrusion of dust or the like into the heat exchange element 32 and the indirect vaporization element 11 is prevented.

In addition, the air supply flow path 9D is provided with the temperature sensor 17 in the air supply outlet 6, whereby the air supply temperature is detected.

<Operation of the Ventilator 1D of the Fourth Embodiment>

Next, with reference to FIG. 10A etc., operation | movement of the ventilation apparatus 1D of 4th Embodiment is demonstrated. When the air supply fan 2 is driven, the ventilation device 1D generates a flow of air toward the air supply outlet 6 in the air supply flow path 9D. As a result, the outside air OA is sucked from the outside air intake port 5, so that the air cleaning filter 16, the first flow path 32a of the heat exchange element 32, and the product air flow path 11b of the indirect vaporization element 11. ) Is supplied from the air supply outlet 6 to the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10E and the second exhaust passage 10F. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. . In addition, a part of the ventilation RA passes through the second flow path 32b of the heat exchange element 32 from the exhaust outlet 8 to the outside as the exhaust EA.

Therefore, in the ventilation device 1D, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilation device 1D in summer, the temperature of the room is lowered, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of the water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus has passed through the product air flow path 11b. In the outside air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the temperature of the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered by the heat exchange unit 31 of the front end. As a result, as described with reference to FIG. 5, when the input temperature of the product air PA is low, the outlet temperature of the product air PA is lowered, so that the heat exchange unit 31 is placed at the front end of the indirect vaporization cooling unit 4. By lowering the input temperature of the product air (PA) by arranging, it is possible to efficiently lower the outlet temperature of the product air (PA) to control the supply air temperature.

In addition, as described with reference to FIG. 5, when the input temperature of the working air WA is low, the outlet temperature of the pro duct air PA decreases, so that the product air can be efficiently used by using the ventilation RA as the working air WA. The supply temperature can be controlled by lowering the outlet temperature of PA.

Moreover, since the ventilation RA which passed the working air flow path 11a of the indirect vaporization element 11 turns into high humidity air, it is discharged | emitted as exhaust EA from the exhaust outlet 8. Moreover, since the temperature rises in the ventilation RA which passed the 2nd flow path 32b of the heat exchange element 32, it is discharged | emitted as exhaust EA from the exhaust outlet 8.

In the ventilator 1D, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow rate adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, also in the ventilation apparatus 1D provided with the heat exchange unit 31, either the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 are operated, and the flow volume of the product air PA or the working air is carried out. By adjusting the flow rate of WA, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled as described with reference to FIGS. 3 and 4. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

For example, when the flow rate of the working air WA is increased, the outlet temperature of the product air PA in the indirect vaporization element 11 is lowered, so that the air supply temperature from the air supply outlet 6 can be lowered.

In addition, when the flow rate of the working air WA is decreased, the outlet temperature of the product air PA in the indirect vaporization element 11 is increased, so that the air supply temperature from the air supply outlet 6 can be increased.

In addition, since the air supply temperature can be controlled by adjusting the flow rate of either the product air PA or the working air WA, one of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 is provided. It may be a configuration.

In addition, by operating both the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 to adjust the flow rate of the product air PA and the flow rate of the working air WA, the indirect vaporization element 11 The outlet temperature of the product air PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA is adjustable.

Therefore, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

10B shows a comparative example of the configuration including the heat exchange unit 31 and the configuration without the heat exchange unit 31, first, in the configuration without the heat exchange unit 31. When the outside air OA is blown in and cooled by the indirect vaporization cooling unit 4, it can be seen from the graph shown in FIG. 5 that air supply SA of 21 ° C. can be generated, but at the same time 0.48 kg as shown in FIG. 6. Consumes an hour of water.

Therefore, the heat exchange unit 31 which lowers the temperature of the blown outside air OA was assembled. The heat exchange element 32 constituting the heat exchange unit 31 generally has a heat exchange rate of about 70%, and is maintained at 40 ° C. outside air (OA) and 25 ° C. ventilation (RA) (room air). By heat exchange, 29.5 degreeC air can be supplied to the indirect vaporization cooling unit 4 with a heat exchange efficiency of 70%.

When supplied as the product air PA and the working air WA of the indirect vaporization element 11 under these conditions, the air supply SA of 17 degreeC can be produced | generated and water consumption can also be suppressed to 0.32 kg / hour. I could see that.

Thereby, the ventilation apparatus 1D is equipped with the heat exchange unit 31, and the cooling ability improves by using ventilation RA in the heat exchange unit 31 and the indirect vaporization cooling unit 4, and at the same time, water consumption is consumed. Can be suppressed. Further, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1D has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation device 1D, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and the ventilation amount can be secured to ensure a predetermined ventilation amount. Control to link the operation with the cooling operation is performed.

<Configuration of Ventilator 1E of Fifth Embodiment>

11 is a configuration diagram showing an example of the ventilation device 1E of the fifth embodiment. The ventilation device 1E of the fifth embodiment is the working air WA of the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4 in the ventilation device 1E having the heat exchange unit 31. To use outside air (OA). In addition, in the ventilator 1E of 5th Embodiment, the same component is attached | subjected and demonstrated about the component same as the ventilator 1D of 4th Embodiment.

The ventilation device 1E passes from the outside air intake port 5 to the air supply fan 2, the first flow path 32a of the heat exchange element 32, and the product air flow path 11b of the indirect vaporization element 11. The air supply flow path 9E communicating with 6) is provided.

In addition, the ventilation device 1E branches from the air supply flow path 9E downstream from the heat exchange unit 31, passes through the working air flow path 11a and the exhaust fan 3 of the indirect vaporization element 11, and exhausts the exhaust outlet. The first exhaust flow path 10G communicating with (8) and the second flow path 32b of the heat exchange element 32 and the exhaust fan 3 are communicated with the exhaust outlet port 8 from the ventilation intake port 7. A second exhaust passage 10H is provided.

The air supply flow path 9E includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the heat exchange unit 31. Further, the first exhaust flow path 10G includes an exhaust flow rate adjustment damper 15 on the downstream side of the indirect vaporization cooling unit 4, for example, on the downstream side from the branch position with the air supply flow path 9E.

The flow rate of the air flowing through the air supply flow path 9E is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

Moreover, the flow volume of the air which flows through the 1st exhaust flow path 10G is adjusted by adjusting the opening degree of the exhaust flow volume adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

In addition, the air supply passage 9E includes, for example, an air cleaning filter 16 upstream of the heat exchange unit 31. In addition, the air supply flow path 9E includes a temperature sensor 17 at the air supply outlet 6.

<Operation of the Ventilator 1E of the fifth embodiment>

Next, the operation of the ventilator 1E of the fifth embodiment will be described with reference to FIG. 11 and the like. When the air supply fan 2 is driven, the ventilation device 1E generates a flow of air toward the air supply outlet 6 in the air supply flow path 9E. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the first air passage 32a of the heat exchange element 32 and the product air flow passage 11b of the indirect vaporization element 11. ) Is supplied to the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10G and the second exhaust passage 10H. As a result, a part of the outside air OA is discharged to the outside as the exhaust EA from the exhaust outlet 8 through the working air passage 11a of the indirect vaporization element 11 by the first exhaust passage 10G. In addition, ventilation RA from the room is sucked from the ventilation intake port 7 by the second exhaust flow path 10H, and exhausts from the exhaust outlet 8 through the second flow path 32b of the heat exchange element 32. (EA) is discharged to the outdoors.

Accordingly, in the ventilation device 1E, the outside air OA becomes the product air PA and the working air WA.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilator 1E in summer, the temperature in the room decreases, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the heat of cooling of the working air WA, thereby cooling the product air flow path 11b. In the outside air OA which passed, the humidity (absolute humidity) does not change and the temperature decreases.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the temperature of the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered by the heat exchange unit 31 at the front end. As a result, as described in FIG. 5, when the input temperature of the product air PA is low, the outlet temperature of the product air PA is lowered, so that the heat exchange unit 31 is placed in front of the indirect vaporization cooling unit 4. By arrange | positioning and lowering the input temperature of product air PA, the outlet temperature of product air PA can be reduced efficiently and air supply temperature can be controlled.

In addition, as described with reference to FIG. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA is lowered, so that a part of the outside air OA cooled by the heat exchange unit 31 is transferred to the working air. By using as (WA), the outlet temperature of product air PA can be reduced efficiently, and air supply temperature can be controlled.

In addition, since the outside air OA which has passed through the working air flow path 11a of the indirect vaporization element 11 becomes air of high humidity, it is discharged | emitted as exhaust EA from the exhaust outlet 8. Moreover, since the temperature rises, the ventilation RA which passed the 2nd flow path 32b of the heat exchange element 32 is discharged | emitted as exhaust EA from the exhaust outlet 8.

In the ventilation device 1E, similar to the ventilation device 1D of the fourth embodiment, the product air passing through the product air flow path 11b of the indirect vaporization element 11 by the degree of opening of the air supply flow rate adjustment damper 14. The flow rate of PA is adjusted. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, by operating either or both of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and adjusting the flow volume of the product air PA, the flow volume of the working air WA, or the flow volume of both. 3 and 4, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA is adjustable.

Therefore, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1E is provided with a heat exchange unit 31, uses the ventilation RA in the heat exchange unit 31, and the OA cooled in the heat exchange unit 31 is transferred to the indirect vaporization cooling unit 4; By using it, the cooling ability improves. In addition, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilator 1E has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation apparatus 1E, since temperature control is performed by the flow volume of the working air WA and the flow volume of the product air PA, a ventilation operation | movement is obtained so that a desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1F of Sixth Embodiment>

12 is a configuration diagram showing an example of the ventilation device 1F of the sixth embodiment. The ventilation device 1F according to the sixth embodiment includes an air supply flow path for bypassing the indirect vaporization cooling unit 4 in the ventilation device 1F including the heat exchange unit 31. In addition, in the ventilation apparatus 1F of 6th Embodiment, the same component as the ventilation apparatus 1D of 4th Embodiment is attached | subjected, and it demonstrates.

The ventilation device 1F passes through the air supply fan 2, the first flow path 32a of the heat exchange element 32, and the product air flow path 11b of the indirect vaporization element 11 from the outside air intake port 5. The air supply flow path 9F which communicates with 6) is provided. The first exhaust passage 10E and the second exhaust passage 10F have the same configuration as the ventilation device 1D of the fourth embodiment.

In addition, the ventilator 1F is branched from the air supply flow path 9F on the upstream side of the indirect vaporization cooling unit 4, bypasses the indirect vaporization cooling unit 4, and communicates with the air supply outlet 6. 10I is provided.

The bypass flow path 10I includes an air supply flow rate adjusting damper 18. The flow rate of the air flowing through the bypass flow path 10I is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 18. Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Moreover, the air supply flow path 9F is provided with the air cleaning filter 16 upstream rather than the heat exchange unit 31, for example.

<Operation of the Ventilator 1F of the Sixth Embodiment>

Next, with reference to FIG. 12 etc., operation | movement of the ventilation apparatus 1F of 6th Embodiment is demonstrated. When the air supply fan 2 is driven, the ventilation device 1F generates a flow of air toward the air supply outlet 6 in the air supply flow path 9F. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the first air passage 32a of the heat exchange element 32 and the product air flow passage 11b of the indirect vaporization element 11. ) Is supplied into the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10E and the second exhaust passage 10F. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. . In addition, a part of the ventilation RA passes through the second flow path 32b of the heat exchange element 32 from the exhaust outlet 8 to the outside as the exhaust EA.

Accordingly, in the ventilation device 1F, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilation device 1F in summer, the temperature in the room decreases, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the temperature of the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered by the heat exchange unit 31 at the front end. As a result, as described with reference to FIG. 5, when the input temperature of the product air PA is low, the outlet temperature of the product air PA is lowered, so that the heat exchange unit 31 is placed at the front end of the indirect vaporization cooling unit 4. By lowering the input temperature of the product air (PA) by arranging, it is possible to efficiently lower the outlet temperature of the product air (PA) to control the supply air temperature.

In addition, as described with reference to FIG. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA decreases, so that the product air PA is used by using the ventilation RA as the working air WA. ), The outlet temperature can be lowered, and the air supply temperature can be lowered.

In the ventilation device 1F, the flow rate of the air flowing through the bypass flow path 10I is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 18.

Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Therefore, by operating the air supply flow rate adjusting damper 18 to adjust the flow rate of the air flowing through the bypass flow path 10I, the air cooled through the indirect vaporization cooling unit 4 and the indirect vaporization cooling unit 4 are bypassed. In the indirect vaporization cooling unit 4, the mixing ratio of the uncooled air is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1F is provided with the heat exchange unit 31, and the cooling ability is improved by using the ventilation RA in the heat exchange unit 31 and the indirect vaporization cooling unit 4. As shown in FIG. In addition, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1F has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation device 1F, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1G of the Seventh Embodiment>

13A is a configuration diagram showing an example of the ventilation device 1G of the seventh embodiment. The ventilation device 1G of the seventh embodiment includes a dehumidifying unit 33 in addition to the air supply fan 2, the exhaust fan 3, and the indirect vaporization cooling unit 4. In addition, in the ventilation apparatus 1G of 7th Embodiment, the same component as the 1st ventilation apparatus of 1st Embodiment is attached | subjected, and it demonstrates.

The dehumidification unit 33 includes a dehumidification flow path 35a and a regeneration flow path 35b partitioned by the partition wall 34, a dehumidification rotor 36 which is rotationally driven over the dehumidification flow path 35a and the regeneration flow path 35b, The heater 37 which heats the air which passes through the regeneration flow path 35b, and the rotation drive device which are not shown in figure which drive rotation of the dehumidification rotor 36 are provided.

The dehumidification rotor 36 is formed in a disk shape so that a member of a honeycomb structure having an adsorbent such as silica gel is formed in an axial direction. The dehumidification rotor 36 is disposed over the dehumidification flow path 35a and the regeneration flow path 35b, and the air passing through the dehumidification flow path 35a and the air passing through the regeneration flow path 35b pass through the dehumidification rotor 36, respectively. do.

In the dehumidification rotor 36, the dehumidification flow path 35a and the regeneration flow path 35b are divided into partitions 34, and the air passing through the dehumidification flow path 35a and the air passing through the regeneration flow path 35b are mixed. There is nothing to be done.

The air passing through the dehumidification passage 35a is adsorbed by the dehumidification rotor 36 and dehumidified. The dehumidification rotor 36 is driven to rotate so that the portion adsorbing moisture moves to the regeneration flow path 35b. The air passing through the regeneration flow path 35b is heated by the heater 37, so that the dehumidification rotor 36 is heated by the air passing through the regeneration flow path 35b, so that the moisture evaporates and regenerates in a state where the moisture can be adsorbed again. do.

The dehumidified rotor 36 moves to the side of the dehumidification flow path 35a. As a result, the dehumidification unit 33 rotates the dehumidification rotor 36 to dehumidify air passing through the dehumidification flow path 35a while repeating the adsorption and regeneration of moisture.

The air supply flow path 9G passes through the air supply fan 2, the dehumidification flow path 35a of the dehumidification unit 33, and the product air flow path 11b of the indirect vaporization element 11 from the outside air intake port 5. Communicate with

The first exhaust flow path 10J communicates from the ventilation intake port 7 to the exhaust outlet 8 through the working air flow path 11a of the indirect vaporization element 11 and the exhaust fan 3. In addition, the second exhaust flow path 10K communicates with the exhaust outlet 8 through the regeneration flow path 35b and the exhaust fan 3 of the dehumidification unit 33 from the ventilation intake port 7.

The air supply flow path 9G includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the dehumidification unit 33. The flow rate of the air which flows through the air supply flow path 9G is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

The 1st exhaust flow path 10J is equipped with the exhaust flow volume adjustment damper 15 in the upstream of the indirect vaporization cooling unit 4, for example. The flow rate of the air flowing through the first exhaust flow path 10J is adjusted by adjusting the opening degree of the exhaust flow rate adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

In addition, the air supply flow path 9G includes an air cleaning filter 16 on an upstream side of the dehumidification unit 33, for example. By arranging the air cleaning filter 16 on the upstream side of the dehumidification unit 33, intrusion of dust and the like into the dehumidification rotor 36 and the indirect vaporization element 11 is prevented.

In addition, the supply air path 9G is provided with the temperature sensor 17 in the air supply outlet 6, and the air supply temperature is detected.

<Operation of the Ventilator 1G of the Seventh Embodiment>

Next, the operation of the ventilator 1G of the seventh embodiment will be described with reference to FIG. 13A and the like. When the air supply fan 2 is driven, the ventilation device 1G generates a flow of air toward the air supply outlet 6 in the air supply flow path 9G. As a result, the outside air OA is sucked from the outside air inlet 5, and the air cleaning filter 16, the dehumidifying flow path 35a of the dehumidification unit 33, and the product air flow path 11b of the indirect vaporization element 11 are removed. It is supplied into the room from the air supply outlet 6 as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10J and the second exhaust passage 10K. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. . In addition, a part of the ventilation RA passes through the regeneration flow path 35b of the dehumidification unit 33 and is discharged to the outside as the exhaust EA from the exhaust outlet 8.

Accordingly, in the ventilation device 1G, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus the product air flow path 11b is opened. In the outside air OA which passed, the humidity (absolute humidity) does not change and the temperature decreases.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the humidity of the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered by the dehumidification unit 33 at the front end. As a result, as described with reference to FIG. 7, when the input humidity of the product air PA is low, the outlet temperature of the product air PA is lowered, so that the dehumidifying unit 33 is disposed at the front end of the indirect vaporization cooling unit 4. By lowering the input humidity of the product air PA, the outlet temperature of the product air PA can be efficiently lowered to control the air supply temperature.

In addition, the temperature of the room is lowered by using the ventilation device 1G in summer. Therefore, the temperature of the ventilation RA is also low. As described in Fig. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA is lowered, so that the product air PA can be efficiently used by using the ventilation RA as the working air WA. The supply temperature can be controlled by lowering the outlet temperature of the.

In addition, since the ventilation RA passing through the working air flow passage 11a of the indirect vaporization element 11 and the ventilation RA passing through the regeneration flow passage 35b of the dehumidification unit 33 become high-humidity air, the exhaust blow-out port It discharges as exhaust (EA) from (8).

In the ventilation device 1G, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow volume adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, even in the ventilation apparatus 1G provided with the dehumidification unit 33, either the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 are operated, and the flow volume of the product air PA and the working air ( By adjusting the flow rate of WA), the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled as described with reference to FIGS. 3 and 4. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

For example, when the flow rate of the working air WA is increased, the outlet temperature of the product air PA in the indirect vaporization element 11 is lowered, so that the air supply temperature from the air supply outlet 6 can be lowered.

In addition, when the flow rate of the working air WA is decreased, the outlet temperature of the product air PA in the indirect vaporization element 11 increases, so that the air supply temperature from the air supply outlet 6 can be increased.

In addition, since the air supply temperature can be controlled by adjusting the flow rate of either the product air PA or the working air WA, one of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 is provided. It may be a configuration.

In addition, by operating both the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 to adjust the flow rate of the product air PA and the flow rate of the working air WA, the indirect vaporization element 11 The outlet temperature of the product air PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA is adjustable.

Therefore, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

When the effect of the structure provided with the dehumidification unit 33 is shown in FIG. 13B, the outside air QA of temperature 30 degreeC, absolute humidity 10g / kg (DA), and about 40% RH of relative humidity is the dehumidification unit 33, for example. By passing through the dehumidification flow path 35a, the input air has a temperature of 40 ° C, an absolute humidity of 5 g / kg (DA), and a relative humidity of about 10% RH.

The temperature of the input air rises here because the dehumidification rotor 36 is heated by the heater 37 on the regeneration flow path 35b in the dehumidification unit 33.

When the input air of this condition is made into the product air PA and the walking air WA of the indirect vaporization cooling unit 4, since the input humidity (absolute humidity) is low, the outlet temperature of the product air PA is 20 ° C. Go down. In addition, since the absolute humidity is low at 5 g / kg (DA), the outlet temperature may be further lowered.

Thereby, the ventilation apparatus 1G is equipped with the dehumidification unit 33, and cooling ability improves by using ventilation RA in the indirect vaporization cooling unit 4. As shown in FIG. Moreover, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1G has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation device 1G, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and the predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1H of Eighth Embodiment>

14 is a configuration diagram showing an example of the ventilation device 1H of the eighth embodiment. The ventilation device 1H according to the eighth embodiment is the outside air to the working air WA of the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4 in the ventilation device 1H including the dehumidification unit 33. Is to use (OA). In addition, in the ventilation apparatus 1H of 8th Embodiment, the same component as the ventilation apparatus 1G of 7th Embodiment is attached | subjected, and it demonstrates.

The ventilation device 1H passes from the outside air intake port 5 through the air supply fan 2, the dehumidification flow path 35a of the dehumidification unit 33, and the product air flow path 11b of the indirect vaporization element 11. The air supply flow path 9H communicating with the furnace is provided.

Further, the ventilation device 1H branches off from the air supply flow passage 9H on the downstream side of the dehumidification unit 33, passes through the working air flow passage 11a and the exhaust fan 3 of the indirect vaporization element 11, and the exhaust blower outlet ( 8L the 2nd exhaust gas which communicated with the 1st exhaust flow path 10L and the ventilation intake port 7 through the regeneration flow path 35b of the dehumidification unit 33, and the exhaust fan 3 to the exhaust outlet 8 A flow path 10M is provided.

The air supply flow path 9H includes, for example, an air supply flow rate adjustment damper 14 on an upstream side of the dehumidification unit 33. In addition, the first exhaust flow path 10L includes an exhaust flow rate adjustment damper 15 on the downstream side of the branch position with the air supply flow path 9H, for example, on the upstream side of the indirect vaporization cooling unit 4.

The flow rate of the air which flows through the air supply flow path 9H is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

Moreover, the flow volume of the air which flows through the 1st exhaust flow path 10L is adjusted by adjusting the opening degree of the exhaust flow volume adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

Moreover, the air supply flow path 9H is provided with the air cleaning filter 16 upstream rather than the dehumidification unit 33, for example. In addition, the air supply flow path 9H includes a temperature sensor 17 at the air supply outlet 6.

<Operation of the Ventilator 1H of the Eighth Embodiment>

Next, the operation of the ventilation device 1H of the eighth embodiment will be described with reference to FIG. 14 and the like. When the air supply fan 2 is driven, the ventilation device 1H generates a flow of air toward the air supply outlet 6 in the air supply flow path 9H. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the dehumidification flow path 35a of the dehumidification unit 33 and the product air flow path 11b of the indirect vaporization element 11 from the air supply blow-out port 6. It is supplied indoors as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10L and the second exhaust passage 10M. As a result, a part of the outside air OA is discharged from the exhaust blowout port 8 to the outside as the exhaust EA by the first exhaust passage 10L through the working air passage 11a of the indirect vaporization element 11. In addition, the ventilation RA from the room is sucked from the ventilation intake port 7 by the second exhaust flow path 10M, and passes through the regeneration flow path 35b of the dehumidification unit 33 from the exhaust blowout port 8. Is discharged to the outdoors.

Therefore, in the ventilation device 1H, the outside air OA becomes the product air PA and the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, outside air OA is supplied to the product air flow path 11b and the working air flow path 11a of the indirect vaporization element 11, and humidity is lowered by the dehumidification unit 33 of the front end. . As a result, when the input humidity of the product air PA and the working air WA is low as described with reference to FIG. 7, the outlet temperature of the product air PA decreases, so that the dehumidification is performed at the front end of the indirect vaporization cooling unit 4. By arranging the unit 33 to lower the input humidity of the product air PA and the working air WA, the outlet temperature of the product air PA can be efficiently lowered to control the air supply temperature.

Moreover, since the outside air OA which passed the working air flow path 11a of the indirect vaporization element 11, and the ventilation RA which passed through the regeneration flow path 35b of the dehumidification unit 33 become high-humidity air, the exhaust outlet It discharges as exhaust (EA) from (8).

In the ventilation device 1H, similar to the ventilation device 1G of the seventh embodiment, the product air passing through the product air flow path 11b of the indirect vaporization element 11 by the degree of opening of the air supply flow rate adjustment damper 14 ( The flow rate of PA) is adjusted. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, one or both of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 are operated to adjust the flow rate of the product air PA, the flow rate of the working air WA, or both. 3 and 4, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA is adjustable.

Therefore, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1H is provided with the dehumidification unit 33, and cooling ability improves by using the indirect vaporization cooling unit 4 with the outside air OA dehumidified by the dehumidification unit 33. As shown in FIG. In addition, by using the ventilation RA as the regeneration air in the dehumidification unit 33, it is possible to cool and blow the outside air while exhausting the indoor air to the outside, and the ventilation device 1H performs cooling while performing ventilation. Will have

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation device 1H, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilation Device 1I of the Ninth Embodiment>

15 is a configuration diagram showing an example of the ventilation device 1I of the ninth embodiment. The ventilation device 1I of 9th Embodiment is provided with the air supply flow path which bypasses the indirect vaporization cooling unit 4 in the ventilation device 1I provided with the dehumidification unit 33. As shown in FIG. In addition, in the ventilator 1I of 9th Embodiment, the same component as the ventilator 1G of 7th Embodiment is attached | subjected and demonstrated.

The ventilation device 1I passes from the outside air intake port 5 through the air supply fan 2, the dehumidification flow path 35a of the dehumidification unit 33, and the product air flow path 11b of the indirect vaporization element 11. The air supply flow path 9I which communicates with the furnace is provided. The 1st exhaust flow path 10J and the 2nd exhaust flow path 10K are the same structures as the ventilation apparatus 1G of 7th Embodiment.

In addition, the ventilator 1I is branched from the air supply flow path 9I upstream than the indirect vaporization cooling unit 4, bypasses the indirect vaporization cooling unit 4, and communicates with the air supply outlet 6. 10N is provided.

The bypass flow path 10N includes an air supply flow rate adjustment damper 18. The flow rate of the air flowing through the bypass flow path 10N is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 18. Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Moreover, the air supply flow path 9I is equipped with the air cleaning filter 16 upstream rather than the dehumidification unit 33, for example.

<Operation of the Ventilator 1I of the Ninth Embodiment>

Next, with reference to FIG. 15 etc., operation | movement of the ventilation apparatus 1I of 9th Embodiment is demonstrated. When the air supply fan 2 is driven, the ventilation device 1I generates a flow of air toward the air supply outlet 6 in the air supply flow path 9I. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the dehumidification flow path 35a of the dehumidification unit 33 and the product air flow path 11b of the indirect vaporization element 11 from the air supply blow-out port 6. It is supplied indoors as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10J and the second exhaust passage 10K. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. . In addition, a part of the ventilation RA passes through the regeneration flow path 35a of the dehumidification unit 33 and is discharged to the outdoors as the exhaust EA from the exhaust outlet 8.

Accordingly, in the ventilation device 1I, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the humidity of the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered by the dehumidification unit 33 at the front end. As a result, when the input humidity of the product air PA is low as described with reference to FIG. 7, the outlet temperature of the product air PA is lowered, so that the dehumidifying unit 33 is disposed at the front end of the indirect vaporization cooling unit 4. By lowering the input humidity of the product air PA, the outlet temperature of the product air PA can be efficiently lowered to control the air supply temperature.

In addition, the temperature of the room is lowered by using the ventilation device 1I in summer. Therefore, the temperature of the ventilation RA is also low. As described in Fig. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA is lowered, so that the product air PA can be efficiently used by using the ventilation RA as the working air WA. The supply temperature can be controlled by lowering the outlet temperature of the.

In the ventilation apparatus 1I, the flow volume of the air which flows through the bypass flow path 10N is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 18. FIG.

Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Therefore, by operating the air supply flow rate adjusting damper 18 to adjust the flow rate of air flowing through the bypass flow path 10N, the air cooled through the indirect vaporization cooling unit 4 and the indirect vaporization cooling unit 4 are bypassed. The mixing ratio of the air which has not passed and cooled is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, since the air (outer air OA) which bypassed the indirect vaporization cooling unit 4 is dehumidified by the dehumidification unit 33, the humidity of the air supply SA does not rise.

The ventilation device 1I is provided with the dehumidification unit 33, and the cooling ability improves by using ventilation RA in the indirect vaporization cooling unit 4. As shown in FIG. In addition, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1I has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation apparatus 1I, since temperature control is performed by the flow volume of the working air WA and the flow volume of the product air PA, ventilation operation | movement is possible so that a desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1J of the Tenth Embodiment>

16 is a configuration diagram showing an example of the ventilation device 1J of the tenth embodiment. The ventilator 1J of the tenth embodiment includes a heat exchange unit 31 and a dehumidification unit 33 in addition to the air supply fan 2, the exhaust fan 3, and the indirect vaporization cooling unit 4. In addition, in the ventilator 1J of 10th Embodiment, the component same as the ventilator 1A etc. of 1st Embodiment is attached | subjected and described with the same number.

The air supply flow path 9J is connected to the air supply fan 2, the dehumidification flow path 35a of the dehumidification unit 33, the first flow path 32a of the heat exchange element 32, and the indirect vaporization element 11 from the outside air intake port 5. The product air flow passage 11b communicates with the air supply outlet 6.

The first exhaust flow path 10P communicates with the exhaust air outlet 8 through the working air flow path 11a of the indirect vaporization element 11 and the exhaust fan 3 from the ventilation intake port 7. In addition, the second exhaust flow path 10Q exhausts from the ventilation intake port 7 through the second flow path 32b of the heat exchange element 32, the regeneration flow path 35b of the dehumidification unit 33, and the exhaust fan 3. It communicates with the outlet 8.

The air supply flow path 9J includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the dehumidification unit 33. The flow rate of the air flowing through the air supply flow path 9J is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

The 1st exhaust flow path 10P is equipped with the exhaust flow volume adjustment damper 15 upstream of the indirect vaporization cooling unit 4, for example. The flow rate of the air flowing through the first exhaust flow path 10P is adjusted by adjusting the opening degree of the exhaust flow rate adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

Moreover, the air supply flow path 9J is equipped with the air cleaning filter 16 in the upstream of the dehumidification unit 33, for example. By arranging the air cleaning filter 16 upstream of the dehumidification unit 33, intrusion of dust and the like into the dehumidification rotor 36, the heat exchange element 32, and the indirect vaporization element 11 is prevented.

Moreover, the air supply temperature 9J is detected by providing the temperature sensor 17 in the air supply outlet 6.

<Operation of the Ventilator 1J of the Tenth Embodiment>

Next, the operation of the ventilation device 1J of the tenth embodiment will be described with reference to FIG. 16 and the like. When the air supply fan 2 is driven, the ventilation device 1J generates a flow of air toward the air supply outlet 6 in the air supply flow path 9J. Thereby, outside air OA is sucked in from the outside air intake port 5, the air cleaning filter 16, the dehumidification flow path 35a of the dehumidification unit 33, the 1st flow path 32a of the heat exchange element 32, and The product air flow passage 11b of the indirect vaporization element 11 is supplied from the air supply outlet 6 to the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10P and the second exhaust passage 10Q. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. . In addition, a part of the ventilation RA passes through the second flow path 32b of the heat exchange element 32 and the regeneration flow path 35b of the dehumidification unit 33 to the outside as the exhaust EA from the exhaust blowout port 8. do.

Accordingly, in the ventilation device 1J, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

In the dehumidification unit 33, the outdoor air OA passing through the dehumidification passage 35a is dehumidified. However, since the dehumidification rotor 36 is heated by the regeneration air heated by the heater 37 on the regeneration flow path 35b side, the temperature of the outside air OA which passed the dehumidification flow path 35a rises.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilation device 1J in summer, the temperature of the room falls, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As a result, the outside air OA dehumidified and heated by passing through the dehumidification flow path 35a of the dehumidification unit 33 passes through the first flow path 32a of the heat exchange element 32 so that the humidity does not change. Goes down.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the humidity of the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered by the dehumidification unit 33 at the front end. In addition, the temperature is lowered by the heat exchange unit 31. As a result, as described with reference to FIGS. 5 and 7, when the input humidity and the input temperature of the product air PA are low, the outlet temperature of the product air PA is lowered, so that dehumidification is performed at the front end of the indirect vaporization cooling unit 4. By disposing the unit 33 and the heat exchange unit 31 to lower the input humidity and the input temperature of the product air PA, the outlet temperature of the product air PA can be efficiently lowered to control the air supply temperature.

In addition, the temperature of the room is lowered by using the ventilation device 1J in summer. Therefore, the temperature of the ventilation RA is also low. As described in Fig. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA is lowered, so that the product air PA can be efficiently used by using the ventilation RA as the working air WA. The supply temperature can be controlled by lowering the outlet temperature of the.

Furthermore, the ventilation RA passed through the working air flow path 11a of the indirect vaporization element 11 and the second flow path 32b of the heat exchange element 32 and the regeneration flow path 35b of the dehumidification unit 33 pass through. Since one ventilation RA becomes air of high humidity, it exhausts as exhaust EA from the exhaust outlet 8.

In the ventilator 1J, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow volume adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, also in the ventilation apparatus 1J provided with the dehumidification unit 33 and the heat exchange unit 31, any one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 is operated, and product air PA is performed. The outlet temperature of the product air PA in the indirect vaporization element 11 is controlled as described with reference to FIGS. 3 and 4 by adjusting the flow rate of) and the flow rate of the working air WA. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

For example, when the flow rate of the working air WA is increased, the outlet temperature of the product air PA in the indirect vaporization element 11 is lowered, whereby the air supply temperature from the air supply outlet 6 can be lowered.

When the flow rate of the working air WA is decreased, the outlet temperature of the product air PA in the indirect vaporization element 11 increases, whereby the air supply temperature from the air supply outlet 6 can be increased.

In addition, since the air supply temperature can be controlled by adjusting the flow rate of either the product air PA or the working air WA, one of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 is provided. It may be a configuration.

In addition, by operating both the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 to adjust the flow rate of the product air PA and the flow rate of the working air WA, the indirect vaporization element 11 The outlet temperature of the product air PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the product air PA can also be adjusted by varying the rotation speed of the air supply fan 2 to control the amount of air, and similarly by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of air WA is adjustable.

Therefore, the product air in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. The outlet temperature of PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1J is provided with a dehumidification unit 33 and a heat exchange unit 31, and dehumidified in the dehumidification unit 33, and cooled outside of the air (OA) cooled in the heat exchange unit 4 and the room. By using RA in the indirect vaporization cooling unit 4, the cooling capacity is improved. In addition, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilator 1J has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation apparatus 1J, since temperature control is performed by the flow volume of the working air WA and the flow volume of the product air PA, ventilation operation | movement is obtained so that desired cooling temperature can be obtained and a predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Configuration of Ventilator 1K of the Eleventh Embodiment>

17 is a configuration diagram showing an example of the ventilation device 1K of the eleventh embodiment. The ventilation device 1K of the eleventh embodiment is an indirect vaporization element constituting the indirect vaporization cooling unit 4 in the ventilation device 1K including the dehumidification unit 33 and the heat exchange unit 31. The outside air (OA) is used for the working air (WA) of (11). In addition, in the ventilator 1K of 11th Embodiment, the same component as the ventilator 1J of 10th Embodiment is attached | subjected and demonstrated.

The ventilation device 1K is provided from the outside air intake port 5 to the air supply fan 2, the dehumidification flow path 35a of the dehumidification unit 33, the first flow path 32a of the heat exchange element 32, and the indirect vaporization element 11. The air supply flow path 9K which communicates with the product air flow path 11b of the air supply outlet 6 is provided.

In addition, the ventilation device 1K is branched from the air supply flow path 9K downstream from the heat exchange unit 31, and passes through the working air flow path 11a and the exhaust fan 3 of the indirect vaporization element 11, and the exhaust outlet port. The first exhaust flow path 10R communicating with (8), the second flow path 32b of the heat exchange element 32, the regeneration flow path 35b of the dehumidification unit 33, and the exhaust fan from the ventilation intake port 7 ( The 2nd exhaust flow path 10S communicated with 3 through the exhaust outlet 8 is provided.

The air supply flow path 9K includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the dehumidification unit 33. Moreover, the 1st exhaust flow path 10R is equipped with exhaust flow volume adjustment damper 15 downstream from the branch position with the air supply flow path 9K, for example, upstream of the indirect vaporization cooling unit 4.

By adjusting the opening degree of the air supply flow volume adjustment damper 14, the flow volume of the air which flows through the air supply flow path 9K is adjusted. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

In addition, by adjusting the opening degree of the exhaust flow rate adjustment damper 15, the flow rate of the air flowing through the first exhaust passage 10R is adjusted. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

Moreover, the air supply flow path 9K is provided with the air cleaning filter 16 upstream rather than the dehumidification unit 33, for example. In addition, the air supply flow path 9K includes a temperature sensor 17 at the air supply outlet 6.

<Operation of the Ventilator 1K of the Eleventh Embodiment>

Next, operation | movement of the ventilation apparatus 1K of 11th Embodiment is demonstrated with reference to FIG. When the air supply fan 2 is driven, the ventilation device 1K generates a flow of air toward the air supply outlet 6 in the air supply flow path 9K. As a result, the outside air OA is sucked from the outside air intake port 5, and the dehumidification flow path 35a of the dehumidification unit 33, the first flow path 32a of the heat exchange element 32, and the indirect vaporization element 11 are removed. The product air flow passage 11b is supplied from the air supply outlet 6 to the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10R and the second exhaust passage 10S. As a result, part of the outside air OA is discharged to the outside as the exhaust EA from the exhaust outlet 8 through the working air passage 11a of the indirect vaporizing element 11 by the first exhaust passage 10R. In addition, the ventilation RA from the room is sucked from the ventilation intake port 7 by the second exhaust flow path 10S, and the second flow path 32b of the heat exchange element 32 and the regeneration flow path of the dehumidification unit 33 are provided. It passes through 35b and is discharged | emitted to the outdoors as exhaust EA from the exhaust outlet 8.

Therefore, in the ventilation device 1K, the outside air OA becomes the product air PA and the working air WA.

In the dehumidification unit 33, the outdoor air OA passing through the dehumidification passage 35a is dehumidified. However, since the dehumidification rotor 36 is heated by the regeneration air heated by the heater 37 on the regeneration flow path 35b side, the temperature of the outside air OA which passed the dehumidification flow path 35a rises.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilation device 1K in summer, the temperature of the room falls, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As a result, the outside air OA dehumidified and heated by passing through the dehumidification flow path 35a of the dehumidification unit 33 passes through the first flow path 32a of the heat exchange element 32 so that the humidity does not change. Goes down.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, outside air OA is supplied to the product air flow path 11b and the working air flow path 11a of the indirect vaporization element 11, and the outside air OA is the dehumidification unit 33 and the heat exchange unit 31 of the front end. Humidity and temperature decrease by). As a result, as described with reference to FIGS. 5 and 7, when the input humidity and the input temperature of the product air PA and the working air WA are low, the outlet temperature of the product air PA is lowered, so that the indirect vaporization cooling unit ( 4) The dehumidification unit 33 and the heat exchange unit 31 are arranged in front of each other, thereby lowering the input humidity and the input temperature of the product air PA and the working air WA, thereby efficiently exiting the product air PA. The air temperature can be controlled by lowering the temperature.

In addition, the outside air OA that has passed through the working air flow path 11a of the indirect vaporization element 11 and the second flow path 32b of the heat exchange element 32 and the regeneration flow path 35b of the dehumidification unit 33 pass through. Since one ventilation RA becomes air of high humidity, it exhausts as exhaust EA from the exhaust outlet 8.

In the ventilation device 1K, like the ventilation device 1J of the tenth embodiment, the product air passing through the product air flow path 11b of the indirect vaporization element 11 by the degree of opening of the air supply flow rate adjustment damper 14. The flow rate of PA is adjusted. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, by operating either or both of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, the flow volume of the product air PA, the flow volume of the working air WA, or the flow volume of both are adjusted, 3 and 4, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

In addition, the flow rate of the product air PA can be adjusted by changing the rotation speed of the air supply fan 2, and the working air can also be controlled by changing the rotation speed of the exhaust fan 3 to control the air volume. The flow rate of WA is adjustable.

Therefore, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both of the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1K includes a dehumidification unit 33 and a heat exchange unit 31, and dehumidifies in the dehumidification unit 33, and cools the outside air OA cooled in the heat exchange unit 4 by an indirect vaporization cooling unit ( By using in 4), the cooling capacity is improved. In addition, by using the ventilation RA in the dehumidification unit 33 and the heat exchange unit 31, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1K is ventilated while It has a function of cooling.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation device 1K, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and the ventilation amount can be secured to ensure a predetermined ventilation amount. Control for interlocking the cooling operation is performed.

<Configuration of the ventilation device 1L of the twelfth embodiment>

18 is a configuration diagram showing an example of the ventilation device 1L of the twelfth embodiment. The ventilation device 1L of the twelfth embodiment is provided with an air supply flow path for bypassing the indirect vaporization cooling unit 4 in the ventilation device 1L including the dehumidification unit 33 and the heat exchange unit 31. will be. In addition, in the ventilation apparatus 1L of 12th Embodiment, the same component as the ventilation apparatus 1J of 10th Embodiment is attached | subjected and demonstrated.

The ventilation device 1L is provided from the outside air intake port 5 to the air supply fan 2, the dehumidification flow path 35a of the dehumidification unit 33, the first flow path 32a of the heat exchange element 32, and the indirect vaporization element 11. The air supply flow path 9L which communicates with the product air flow path 11b to the air supply blow-out port 6 is provided. The 1st exhaust flow path 10P and the 2nd exhaust flow path 10Q are the same structures as the ventilation apparatus 1J of 10th Embodiment.

The bypass device 1L is branched from the air supply flow path 9L on the upstream side of the indirect vaporization cooling unit 4, bypasses the indirect vaporization cooling unit 4, and communicates with the air supply outlet 6. 10T is provided.

The bypass flow path 10T includes an air supply flow rate adjustment damper 18. The flow rate of the air flowing through the bypass flow path 10T is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 18. Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Moreover, the air supply flow path 9L is provided with the air cleaning filter 16 upstream rather than the dehumidification unit 33, for example.

<Operation of the Ventilator 1L of the 12th Embodiment>

Next, with reference to FIG. 18 etc., operation | movement of the ventilation apparatus 1L of 12th Embodiment is demonstrated. When the air supply fan 2 is driven, the ventilation device 1L generates a flow of air toward the air supply outlet 6 in the air supply flow path 9L. As a result, the outside air OA is sucked from the outside air intake port 5, and the dehumidification flow path 35a of the dehumidification unit 33, the first flow path 32a of the heat exchange element 32, and the indirect vaporization element 11 are removed. The product air flow passage 11b is supplied from the air supply outlet 6 to the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust passage 10P and the second exhaust passage 10Q. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. . In addition, a part of the ventilation RA is discharged to the outside as the exhaust EA from the exhaust outlet 8 through the second flow passage 32b of the heat exchange element 32 and the regeneration flow passage 35a of the dehumidification unit 33. do.

Therefore, in the ventilation device 1L, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

In the dehumidification unit 33, outside air OA which passes through the dehumidification flow path 35a is dehumidified. However, since the dehumidification rotor 36 is heated by the regeneration air heated by the heater 37 on the regeneration flow path 35b side, the temperature of the outside air OA which passed the dehumidification flow path 35a rises.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilation device 1L in summer, the temperature in the room decreases, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As a result, the outside air OA dehumidified and heated by passing through the dehumidification flow path 35a of the dehumidification unit 33 passes through the first flow path 32a of the heat exchange element 32 so that the humidity does not change. Goes down.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Here, the outside air OA passing through the product air flow path 11b of the indirect vaporization element 11 is lowered in humidity and temperature by the dehumidifying unit 33 and the heat exchange unit 31 at the front end. As a result, as described with reference to FIGS. 5 and 7, when the input humidity and the input temperature of the product air PA are low, the outlet temperature of the product air PA is lowered, so that dehumidification is performed at the front end of the indirect vaporization cooling unit 4. By disposing the unit 33 and the heat exchange unit 31 to lower the input humidity and the input temperature of the product air PA, the outlet temperature of the product air PA can be efficiently lowered to control the air supply temperature.

In addition, the temperature of the room is lowered by using the ventilation device 1L in summer. Therefore, the temperature of the ventilation RA is also low. As described in Fig. 5, when the input temperature of the working air WA is low, the outlet temperature of the product air PA is low, so that the product air PA can be efficiently used by using the ventilation RA as the working air WA. The supply temperature can be controlled by lowering the outlet temperature of the.

In the ventilation device 1L, the flow rate of the air flowing through the bypass flow path 10T is adjusted by adjusting the opening degree of the air supply flow rate adjustment damper 18.

Thereby, the flow volume of the air supplied to the air supply blow port 6 by bypassing the indirect vaporization cooling unit 4 is adjusted.

Therefore, the air cooled through the indirect vaporization cooling unit 4 and the indirect vaporization cooling unit 4 are bypassed by operating the air supply flow rate adjusting damper 18 to adjust the flow rate of the air flowing in the bypass flow path 10T. And the mixing ratio of the uncooled air is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, since the air (outer air OA) which bypassed the indirect vaporization cooling unit 4 is dehumidified by the dehumidification unit 33 and cooled by the heat exchange unit 31, the humidity of the air supply SA rises. none.

The ventilation device 1L includes a dehumidification unit 33 and a heat exchange unit 31, and is dehumidified in the dehumidification unit 33, and cooled outside of the air (OA) cooled in the heat exchange unit 4 and the room. By using RA in the indirect vaporization cooling unit 4, the cooling capacity is improved. In addition, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outdoors, and the ventilation device 1L has a function of cooling while performing ventilation.

And by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room in predetermined time is possible. For this reason, in the ventilation device 1L, the temperature is controlled by the flow rate of the working air WA or the flow rate of the product air PA, so that the desired cooling temperature can be obtained and the predetermined ventilation amount can be ensured. Control for interlocking the cooling operation is performed.

<Modified example of the ventilation device of each embodiment>

Although the ventilation apparatus 1 of each embodiment mentioned above demonstrated the example which arrange | positioned the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 upstream of the indirect vaporization cooling unit 4, the indirect vaporization cooling unit You may arrange | position downstream of (4).

In addition, in order to use a part of ventilation RA as a circulation RA on the air supply side, ventilation RA may be communicated with the outside air intake port 5. As described above, since the ventilation RA is cooled by air conditioning in summer, input temperature or input such as product air PA in the indirect vaporization cooling unit 4 by using a part of the ventilation RA as air supply. Humidity drops, improving cooling capacity.

In addition to the air cleaning filter 16, an ion generator or an ozone generator may be provided as an air cleaning device. For example, the ion generator generates positive ions and negative ions, supplies approximately the same number of positive ions and negative ions, and has a function of supplying only negative ions or more negative ions than positive ions.

When such an ion generator is provided in the air supply outlet 6, the air supply SA containing approximately the same number of positive ions and negative ions is supplied to the living room or the like, whereby mold and the like can be prevented and sterilized. In addition, the relaxation effect can be obtained by supplying negative ions.

In addition, by disposing the ion generator on the upstream side of the air supply flow path 9 upstream of the indirect vaporization unit 4, sterilization in the apparatus as well as the living room can be performed.

In addition, the indirect vaporization cooling unit 4 and the air supply fan 2, the exhaust fan 3, the heat exchange unit 31, and the dehumidification unit 33 may not each be in the same housing, and the fan may be a fan of another apparatus. You may combine with.

<Modified example of the ventilation device with a heat exchange unit>

In the ventilation apparatus of 4th-6th embodiment mentioned above, and the ventilation apparatus of 10th-12th embodiment, the structure provided with the heat exchange element 32 which performs sensible heat (temperature) exchange as a heat exchange unit 31. As shown in FIG. It is good also as a structure provided with what is called a total heat exchange element which performs latent heat (humidity) exchange in addition to sensible heat exchange.

When the total heat exchange is performed between the outside air (OA) and the ventilation (RA), since the temperature and humidity of the air (RA) is lower than the temperature and humidity of the outside air (OA) in summer, the outside air (OA) has a high temperature and humidity. Down, ventilation (RA) rises in temperature and humidity.

Like the ventilation device 1D of the fourth embodiment and the ventilation device 1J of the tenth embodiment, the outside air OA cooled in the heat exchange unit 31 is supplied to the product air PA of the indirect vaporization element 11. In the configuration used as a heat exchange element, the input temperature and input humidity of the product air PA can be lowered, and the temperature of the air supply SA can be controlled by lowering the outlet temperature of the product air PA. Cooling capacity is improved.

Further, like the ventilation device 1E of the fifth embodiment, the ventilation device 1K of the eleventh embodiment, and the like, the outside air OA cooled by the heat exchange unit 31 is supplied to the product air of the indirect vaporization element 11 ( In the configuration used as the PA and the working air WA, by using the heat exchange element, the input temperature and the input humidity of both the product air PA and the working air WA can be reduced, and the product air PA can be more efficiently. The temperature of the air supply SA can be controlled by lowering the outlet temperature of the (), thereby improving the cooling capacity.

<Modified example of the ventilation device with a dehumidification unit>

In the ventilation apparatus provided with the dehumidification unit 33 demonstrated in 7th-12th embodiment mentioned above, the humidity of the air which passed the dehumidification unit 33 can be controlled by controlling the rotation speed of the dehumidification rotor 36. .

19 is a graph showing the relationship between the rotational speed of the dehumidification rotor 36 and the outlet temperature of the product air PA. As shown in Fig. 19, it can be seen that the amount of dehumidification increases as the rotation speed of the dehumidification rotor 36 increases. The humidity of the air output from the dehumidification unit 33 is controlled by changing the rotational speed of the dehumidification rotor 36 by this.

As described in FIG. 7, when the input humidity of the product air PA and the working air WA decreases in the heat exchange element 11, the outlet temperature of the product air PA decreases.

Like the ventilation device 1G of the seventh embodiment and the ventilation device 1J of the tenth embodiment, the outside air OA dehumidified in the dehumidification unit 33 is used as the product air PA of the indirect vaporization element 11. In the structure to be used, the input humidity of the product air PA can be controlled by providing the speed control means which controls the rotation speed of the dehumidification rotor 36.

For example, when the rotational speed of the dehumidification rotor 36 is increased, the input humidity of the product air PA decreases, so that the outlet temperature of the product air PA can be lowered as described in FIG. Therefore, the temperature of the air supply SA can be lowered. In addition, when the rotational speed of the dehumidification rotor 36 is lowered, the input humidity of the product air PA increases, so that the outlet temperature of the product air PA can be increased. Therefore, the temperature of air supply SA can be raised.

Moreover, the product air PA of the indirect vaporization element 11 carries out the outside air OA dehumidified by the dehumidification unit 33 like the ventilation apparatus 1H of 8th Embodiment, the ventilation apparatus 1K of 11th Embodiment, etc. ) And the working air WA, the input humidity of the product air PA and the working air WA can be controlled by controlling the rotational speed of the dehumidification rotor 36.

By controlling the input humidity of both the product air PA and the working air WA, the outlet temperature of the product air can be controlled more efficiently.

In addition, temperature control can be performed without changing the ventilation flow rate and the air supply flow rate, thereby ensuring a ventilation amount for replacing the air in the room at a predetermined time.

Moreover, you may combine control of the air supply temperature by rotation control of the dehumidification rotor 36, and control of the air supply temperature by flow control by a damper etc.

In addition, the humidity of the air supplied to the indirect vaporization cooling unit 4 is provided with dehumidification control means for controlling the dehumidification amount of the dehumidification rotor 36 by adjusting the temperature of the regeneration heater 37 of the dehumidification rotor 36. May be controlled.

<Other modifications of the ventilation device>

20 is a configuration diagram showing an example of the ventilation device 1M of the thirteenth embodiment. Here, in the ventilation device 1M of the thirteenth embodiment, the same components as those in the ventilation device 1A of the first embodiment will be denoted by the same reference numerals.

The ventilation device 1M includes an air supply fan 2 and an indirect vaporization cooling unit 4, and constitutes the air supply fan 2 and the indirect vaporization cooling unit 4 from the outside air intake port 5. It is provided with the air supply flow path 9M which communicates with the product air flow path 11b of () and the air supply blow-out port 6).

In addition, the ventilation device 1M is branched from the air supply flow path 9M downstream from the air supply fan 2 and exhausted through the working air flow path 11a of the indirect vaporization element 11 to the exhaust outlet 8. A flow path 10U is provided.

The air supply flow path 9M is provided with an air supply flow rate adjustment damper 14 on the downstream side of, for example, an upstream side of the indirect vaporization cooling unit 4 from the branch position with the exhaust flow path 10U. In addition, the exhaust flow path 10U includes an exhaust flow rate adjustment damper 15 on the downstream side of, for example, the upstream side of the indirect vaporization cooling unit 4 from the branch position with the air supply flow path 9M.

The flow rate of the air which flows through the air supply flow path 9M is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

Moreover, the flow volume of the air which flows through the exhaust flow path 10U is adjusted by adjusting the opening degree of the exhaust flow volume adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

Next, the operation of the ventilation device 1M of the thirteenth embodiment will be described. When the air supply fan 2 is driven, the ventilation device 1M generates a flow of air toward the air supply outlet 6 in the air supply flow path 9M. As a result, the outside air OA is sucked from the outside air intake port 5, and is supplied to the room as the air supply SA from the air supply outlet 6 through the product air flow path 11b of the indirect vaporization element 11.

Further, when the air supply fan 2 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10U branched from the air supply flow path 9M. As a result, a part of the outside air OA passes through the working air flow passage 11a of the indirect vaporization element 11 and is discharged to the outside as the exhaust EA from the exhaust outlet 8.

Therefore, in the ventilation device 1M, the outside air OA becomes the product air PA and the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the heat of cooling of the working air WA, and thus the product air flow path 11b is closed. In the outside air OA which passed, the humidity (absolute humidity) does not change and the temperature decreases.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

In the ventilation device 1M, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow rate adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, by operating either or both of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, the flow volume of the product air PA, the flow volume of the working air WA, or the flow volume of both are adjusted, 3 and 4, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

In addition, the flow rate of the product air PA and the working air WA can be adjusted by changing the rotation speed of the air supply fan 2 to control the air volume.

Therefore, the product in the indirect vaporization element 11 is combined with control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of the air supply fan 2, respectively. The outlet temperature of air PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1M does not have a function of ventilation in a single member, but has a function of air supply and air conditioning, and thus can provide a 24-hour ventilation device in combination with other exhaust devices of a simple configuration.

That is, when the exhaust system already exists in the building, it can be used to build an air conditioning system that can be inexpensive 24 hours ventilation and air conditioning.

FIG. 21: is a block diagram which shows an example of the ventilation apparatus 1N of 14th Embodiment. Here, in the ventilator 1N of the fourteenth embodiment, the same components as those in the ventilator 1A of the first embodiment are assigned the same numbers and described.

The ventilation device 1N includes an exhaust fan 3 and an indirect vaporization cooling unit 4, and the product air flow path of the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4 from the ventilation intake port 7 ( An air supply flow path 9N communicating with the air supply outlet 6 through 11b) is provided.

In addition, the ventilation device 1N includes an exhaust flow path 10V which communicates with the exhaust air outlet 8 through the working air flow path 11a of the indirect vaporization element 11 and the exhaust fan 3 from the ventilation intake port 7. do.

The air supply flow path 9N includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the indirect vaporization cooling unit 4. In addition, the exhaust flow path 10V includes an exhaust flow rate adjustment damper 15 on an upstream side of the indirect vaporization cooling unit 4, for example.

The flow rate of the air which flows through the air supply flow path 9N is adjusted by adjusting the opening degree of the air supply flow volume adjustment damper 14. Thereby, the flow volume of the product air PA which flows through the product air flow path 11b of the indirect vaporization element 11 is adjusted.

Moreover, the flow volume of the air which flows through the exhaust flow path 10V is adjusted by adjusting the opening degree of the exhaust flow volume adjustment damper 15. Thereby, the flow volume of the working air WA which flows through the working air flow path 11a of the indirect vaporization element 11 is adjusted.

The ventilation device 1N is connected to the air supply device 41 through a duct or the like not shown in the air supply outlet 6. The air supply device 41 is a device that sucks outside air or indoor air and supplies air to the room, and the air supply jet 6 of the ventilation device 1N is connected to the inlet 41a of the air supply device 41. .

Next, operation | movement of the ventilation apparatus 1N of 14th Embodiment is demonstrated. When the air supply device 41 is driven, the ventilation device 1N generates a flow of air toward the air supply outlet 6 in the air supply flow path 9N. Thereby, ventilation RA is sucked in from the ventilation intake port 7, passes through the product air flow path 11b of the indirect vaporization element 11, and is supplied as air supply SA from the air supply blow-out port 6 through the air supply device 41. It is supplied indoors.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10V. Thereby, the ventilation RA is discharged | emitted as the exhaust EA from the exhaust blowout port 8 through the working air flow path 11a of the indirect vaporization element 11 to the outdoors.

Accordingly, in the ventilation device 1N, the ventilation RA is the product air PA and the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the heat of cooling of the working air WA, and thus the product air flow path 11b is closed. The ventilation RA which passed through does not change humidity (absolute humidity), and temperature falls.

Therefore, the room temperature can be lowered by blowing the ventilation RA which passed the product air flow path 11b of the indirect vaporization element 11 from the air supply outlet 6 as air supply SA.

In the ventilator 1N, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow rate adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, by operating either or both of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, the flow volume of the product air PA, the flow volume of the working air WA, or the flow volume of both are adjusted, 3 and 4, the outlet temperature of the product air PA in the indirect vaporization element 11 is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

The flow rate of the working air WA can also be adjusted by changing the rotation speed of the exhaust fan 3 to control the air volume.

Therefore, the product air in the indirect vaporization element 11 combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 with the control of the air volume of the exhaust fan 3. The outlet temperature of PA is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

The ventilation device 1N can constitute a 24-hour ventilation device by combining with the air supply device 41 of a simple structure. That is, when the air supply device already exists in the building, it can be used to build an air conditioning system that can be inexpensive 24 hours ventilation and air conditioning.

22 is a configuration diagram showing an example of the ventilation device 1P of the fifteenth embodiment. Here, in the ventilation device 1P of the fifteenth embodiment, the same components as those in the ventilation device 1D of the fourth embodiment will be assigned the same reference numbers.

The ventilation device 1P is provided with the heat exchange unit 31 and the indirect vaporization cooling unit 4, and the 1st flow path of the heat exchange element 32 which comprises the heat exchange unit 31 from the outside air intake port 5 ( 32a) and the air supply flow path 9P which communicates with the air supply outlet 6 through the product air flow path 11b of the indirect vaporization element 11 which comprises the indirect vaporization cooling unit 4, and is provided.

In addition, the ventilation device 1P is provided with a first exhaust flow path 10W communicating with a working air flow passage 11a of the indirect vaporization element 11 from the ventilation intake port 7 to the exhaust outlet 8, and a ventilation intake port 7. ) And a second exhaust flow passage 10X communicating with the exhaust blowout opening 8 via the second flow passage 32b of the heat exchange element 32.

The ventilation device 1P is connected to the air supply device 41 through a duct or the like not shown in the air supply outlet 6. In addition, the exhaust device 42 or the like is connected to the ventilation suction port 7 via a duct not shown. The exhaust device 42 is, for example, a device that sucks indoor air and exhausts it to the outside, and the ventilation intake port 7 of the ventilation device 1P is connected to the outlet 42a of the exhaust device 42.

Next, operation | movement of the ventilation device 1P of 15th Embodiment is demonstrated. When the air supply device 41 is driven, the ventilation device 1P generates a flow of air toward the air supply outlet 6 in the air supply flow path 9P. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the first air passage 32a of the heat exchange element 32 and the product air flow passage 11b of the indirect vaporization element 11. ) Is supplied to the room as the air supply SA through the air supply device 41.

In addition, when the exhaust device 42 is driven, a flow of air toward the exhaust outlet 8 is generated in the first exhaust flow path 10W and the second exhaust flow path 10X. Thereby, the ventilation RA is discharged | emitted through the exhaust device 42 through the working air flow path 11a of the indirect vaporization element 11 to the outdoors from the exhaust outlet 8 as exhaust EA. A part of the ventilation RA is also discharged to the outside as the exhaust EA from the exhaust outlet 8 through the exhaust passage 42 via the second flow path 32b of the heat exchange element 32.

Therefore, in the ventilation device 1P, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus, the product air flow path 11b. Outside air OA which passed through, temperature (absolute humidity) does not change, and temperature falls.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

In the ventilation device 1P, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the air supply device 41. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the exhaust device 42.

As a result, by controlling the flow rate in either or both of the air supply device 41 and the exhaust device 42, the product air PA in the indirect vaporization element 11 as shown in Figs. The outlet temperature is controlled. Therefore, the air supply temperature from the air supply outlet 6 is controlled.

As described above, the ventilation of the building is mandated by the Building Standards Act, whereby a ventilation device (called a 24-hour ventilation device or the like) capable of supplying and exhausting air in one unit, or a ventilation device capable of supplying only air or only air supply ( Intermediate duct fans, etc.) are installed in the building. By connecting with another ventilation device as described above, a configuration in which only the exhaust fan 3 is provided as a fan as in the ventilation device 1N, or a configuration in which neither the supply fan nor the exhaust fan is provided as in the ventilation device 1P is also used. It is possible to reduce the product cost by not mounting a fan.

<Configuration example of the ventilation device using the working air>

FIG. 23 is a configuration diagram showing an example of the ventilation device 1Q of the sixteenth embodiment. The ventilation device 1Q exhausts the working air WA of the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4 through the heat exchange unit 31. In addition, as an overall structure of a ventilation apparatus, it demonstrates taking the ventilation apparatus 1D of 4th Embodiment as an example.

The ventilation device 1Q includes an air supply fan 2, an exhaust fan 3, a heat exchange unit 31, and an indirect vaporization cooling unit 4, and the outside air OA is supplied to the product air of the indirect vaporization element 11. It uses as (PA) and uses ventilation (RA) as working air (WA).

The air supply passage 9D communicates from the air supply fan 2 to the air supply outlet 6 through the first air passage 32a of the heat exchange element 32 and the product air passage 11b of the indirect vaporization element 11.

The ventilation flow path 10Y passes from the ventilation intake port 7 through the working air flow path 11a of the indirect vaporization element 11, the second flow path 32b of the heat exchange element 32, and the exhaust fan 3. Communicate with 8). In addition, the part shown with the broken line of the exhaust flow path 10Y is formed along the side wall of a case so that it may become independent from the air supply flow path 9D etc., for example.

The air supply flow path 9D includes, for example, an air supply flow rate adjustment damper 14 on the upstream side of the heat exchange unit 31, and adjusts the opening degree of the air supply flow rate adjustment damper 14, thereby indirectly vaporizing the element 11. The flow rate of the product air PA flowing through the product air flow passage 11b is adjusted.

The exhaust flow path 10Y includes, for example, an exhaust flow rate adjustment damper 15 on the upstream side of the indirect vaporization cooling unit 4, and adjusts the opening degree of the exhaust flow rate adjustment damper 15, thereby adjusting the indirect vaporization element 11. The flow volume of the working air WA which flows through the working air flow path 11a of () is adjusted.

Next, the operation of the ventilation device 1Q will be described. When the air supply fan 2 is driven, the ventilation device 1Q generates a flow of air toward the air supply outlet 6 in the air supply flow path 9D. As a result, the outside air OA is sucked from the outside air intake port 5, so that the air cleaning filter 16, the first flow path 32a of the heat exchange element 32, and the product air flow path 11b of the indirect vaporization element 11. ) Is supplied from the air supply outlet 6 to the room as air supply SA.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10Y. Thereby, the ventilation RA from the room is sucked from the ventilation intake port 7 and exhausted through the working air flow passage 11a of the indirect vaporization element 11 and the second flow passage 32b of the heat exchange element 32. It is discharged | emitted from the blowout port 8 to the outdoors as exhaust EA.

Accordingly, in the ventilation device 1Q, the outside air OA becomes the product air PA, and the ventilation RA becomes the working air WA.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down. In addition, although the humidity RA goes up through the working air flow path 11a, temperature rises.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. The ventilation RA passes through the working air flow passage 11a of the indirect vaporization element 11, whereby the temperature is lowered and lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases. Here, ventilation RA becomes high humidity by passing the working air flow path 11a of the indirect vaporization element 11, but since the heat exchange element 32 is a heat exchange element which performs sensible heat exchange, the humidity of the outside air OA is Does not change.

Thereby, the ventilation RA which passed the working air flow path 11a of the indirect vaporization element 11 passes through the 2nd flow path 32b of the heat exchange element 32, and the front end of the indirect vaporization cooling unit 4 is carried out. The outside air (OA) can be cooled efficiently.

As described in FIG. 5, when the input temperature of the product air PA is low, the outlet temperature of the product air PA is lowered, so that the heat exchange unit 31 is disposed in front of the indirect vaporization cooling unit 4. At the same time, by passing the working air WA through the heat exchange unit 31, the input temperature of the product air PA is lowered efficiently, and the cooling capacity is improved.

In the ventilation device 1Q, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow volume adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, when either or both of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 are operated, and the flow volume of working air WA is increased, for example, in the indirect vaporization element 11, The supply temperature from the air supply outlet 6 can be lowered by decreasing the outlet temperature of the product air PA.

In addition, when the flow rate of the working air WA is decreased, the outlet temperature of the product air PA in the indirect vaporization element 11 increases, so that the air supply temperature from the air supply outlet 6 can be increased.

In addition, the product air PA in the indirect vaporization element 11 is controlled by controlling the air volume of either the air supply fan 2 and the exhaust fan 3 or both the air supply fan 2 and the exhaust fan 3. Is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

Moreover, even if it combines the control of the opening degree of at least one of the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15, and the control of the air volume of at least one of the air supply fan 2 and the exhaust fan 3, it is indirect. The outlet temperature of the product air PA in the vaporization element 11 is controlled, and the air supply temperature from the air supply outlet 6 is controlled.

24 is a configuration diagram showing an example of the ventilation device 1R of the seventeenth embodiment. The ventilation device 1R uses the working air WA of the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4 as the air supply SA. In addition, as an overall structure of a ventilation apparatus, the ventilation apparatus 1E of 5th Embodiment is demonstrated to an example.

The ventilator 1R includes an air supply fan 2, an exhaust fan 3, a heat exchange unit 31, and an indirect vaporization cooling element 4, and supplies outside air OA to the product air of the indirect vaporization element 11. It is used as PA and working air WA.

The first air supply flow path 9R is supplied from the outside air intake port 5 through the air supply fan 2, the first flow path 32a of the heat exchange element 32, and the product air flow path 11b of the indirect vaporization element 11. It communicates with the outlet 6.

The 2nd air supply flow path 9S branches with the 1st air supply flow path 9R downstream from the heat exchange unit 31, and passes through the working air flow path 11a of the indirect vaporization element 11, and the dehumidification apparatus 44. As shown in FIG. It communicates with the air supply outlet 6.

The exhaust flow path 10H communicates from the ventilation intake port 7 to the exhaust outlet 8 through the second flow path 32b of the heat exchange element 32 and the exhaust fan 3.

The dehumidifier 44 includes a permeable membrane filter and the like to separate water and air, and dehumidify air passing through the second air supply flow path 9S.

The first air supply flow path 9R includes, for example, an air supply flow rate adjustment damper 14 on the upstream side of the heat exchange unit 31, and adjusts the opening degree of the air supply flow rate adjustment damper 14, thereby adjusting the indirect vaporization element ( The flow volume of the product air PA which flows through the product air flow path 11b of 11) is adjusted.

In addition, the second air supply flow path 9S includes, for example, an exhaust flow rate adjustment damper 15 on the upstream side of the indirect vaporization cooling unit 4, and indirectly by adjusting the opening degree of the exhaust flow rate adjustment damper 15. The flow volume of the working air WA which flows through the working air flow path 11a of the vaporization element 11 is adjusted.

Next, operation | movement of the ventilation apparatus 1R of 17th Embodiment is demonstrated. When the air supply fan 2 is driven, the ventilation device 1R generates a flow of air toward the air supply outlet 6 in the first air supply passage 9R and the second air supply passage 9S. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the first air passage 32a of the heat exchange element 32 and the product air flow passage 11b of the indirect vaporization element 11. ) Is supplied to the room as air supply SA.

In addition, a part of the outside air OA which has passed through the heat exchange unit 31 passes through the working air flow passage 11a of the indirect vaporization element 11 and the dehumidifying device 44 as the air supply SA from the air supply outlet 6. It is supplied indoors.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10H. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged from the exhaust outlet 8 to the outside as the exhaust EA through the second flow path 32b of the heat exchange element 32. .

Accordingly, in the ventilation device 1R, the outside air OA becomes the product air PA and the working air WA.

In the heat exchange element 32, heat exchange is performed between the outside air OA which passes through the 1st flow path 32a, and the ventilation RA which passes through the 2nd flow path 32b. By using the ventilation device 1R in summer, the temperature in the room decreases, and the temperature of the ventilation RA is lower than the temperature of the outside air OA.

Therefore, the temperature of the outside air OA which has passed through the first flow path 32a of the heat exchange element 32 decreases, and the temperature of the ventilation RA which has passed through the second flow path 32b increases.

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down. In addition, the outdoor air OA that has passed through the working air flow passage 11a increases in humidity but decreases in temperature.

Therefore, the indoor temperature can be lowered by blowing the outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the air supply outlet 6.

Moreover, although the outdoor air OA which passed the working air flow path 11a of the indirect vaporization element 11 becomes high humidity, it can be utilized as air supply SA by dehumidifying through the dehumidification apparatus 44, and the product air flow path 11b. By blowing air (SA) from the air supply outlet 6 together with the outside air OA having passed through), it is possible to lower the temperature and humidity of the room without increasing the temperature.

Here, both the outside air OA is supplied to the product air flow path 11b and the working air flow path 11a of the indirect vaporization element 11, and the outside air OA is lowered in temperature by the heat exchange unit 31 at the front end. have. Thereby, the outlet temperature of the product air PA can be reduced efficiently, and the air supply temperature can be controlled. In addition, the cooling capacity is improved by dehumidifying the cooled working air WA and using it as the air supply SA.

In the ventilator 1R, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow rate adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

As a result, when one or both of the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper 15 are operated to increase the flow rate of the working air WA, for example, the indirect vaporization element 11 When the outlet temperature of the product air PA decreases, the air supply temperature from the air supply outlet 6 can be lowered.

In addition, when the flow rate of the working air WA is decreased, the outlet temperature of the product air PA in the indirect vaporization element 11 increases, so that the air supply temperature from the air supply outlet 6 can be increased.

<Configuration example of ventilation device using array in dehumidification unit>

25 is a configuration diagram showing an example of the ventilation device 1S of the eighteenth embodiment. The ventilation device 1S uses an array as a heat source of regeneration air. In addition, as an overall structure of a ventilation apparatus, it demonstrates taking the ventilation apparatus 1G of 7th Embodiment as an example.

The ventilation device 1S includes a dehumidification unit 33. The dehumidification unit 33 has a heater 37 for heating air (regenerated air) passing through the regeneration flow path 35b, but uses an array for the heat source of the heater 37.

As the source of the arrangement, for example, the outdoor unit 38 of the air conditioner is used. The collector 38a of warm air is installed in the outdoor unit 38, and warm air is sent to the heater 37 via the duct 39a or the like.

The heater 37 heats the regeneration air passing through the regeneration flow path 35b by passing the warm air from the outdoor unit 38 in the pipe wound in a coil shape, for example. The warm air passing through the heater 37 is exhausted from the exhaust device 42 through the duct 39b or the like.

The operation of the ventilation device 1S is similar to the ventilation device 1G of the seventh embodiment. A part of the ventilation RA is used as the regeneration air, but by using the arrangement of the outdoor unit 38 for heating the regeneration air, it is not necessary to equip the ventilator 1S with a drive source of the heater 37, for example, a heater. The power consumption can be suppressed as compared with the case of using the electric heater at 37.

As the heat source of the heater 37, in addition to the arrangement of the outdoor unit, a hot air or hot water for boiling water in a hot water heater for boiling water with gas or electricity may be used.

<Main part constitution of the ventilation apparatus of each embodiment>

26A and 26B are perspective views illustrating an example of a main part configuration of the ventilation device of each embodiment. For example, as described in FIGS. 10A, 10B and the like, in the ventilation apparatuses of the fourth to sixth embodiments including the heat exchange unit 31 and the indirect vaporization cooling unit 4, the heat exchange unit 31 is provided. It encloses with the heat insulating material 51a, and surrounds the indirect vaporization cooling unit 4 with the heat insulating material 51b.

The heat insulating material 51a and the heat insulating material 51b are made of, for example, foamed styrol, have a shape in which the flow path is opened, and surround the heat exchange unit 31, the indirect vaporization cooling unit 4, and the like. By enclosing the heat exchange unit 31 or the indirect vaporization cooling unit 41 with a heat insulating material, it is difficult to be affected by the temperature outside the apparatus, and the cooling ability can be improved.

Here, by enclosing the heat exchange unit 31 and the indirect vaporization cooling unit 4 with the heat insulating material of an independent form, the maintainability at the time of unit replacement etc. can be aimed at. Moreover, the structure which encloses each unit by one heat insulating material may be sufficient.

Moreover, as a unit enclosed with a heat insulating material, in addition to the heat exchange unit 31 and the indirect vaporization cooling unit 4, the air cleaning apparatus, such as an air cleaning filter arrange | positioned in the flow path through which air passes, may be sufficient. The air purifier may be an ion generator, an ozone generator, or the like in addition to the air purifier.

In addition, although FIG. 26A and 26B demonstrated the ventilation apparatus of 4th-6th embodiment provided with the heat exchange unit 31 and the indirect vaporization cooling unit 4 as an example, the indirect vaporization cooling unit 4 is provided. The ventilation device of the first to third embodiments, the ventilation device of the seventh to ninth embodiments including the dehumidification unit 33 and the indirect vaporization cooling unit 4, and also the dehumidification unit 33 and the heat exchange unit. The ventilation apparatus of 10th-12th embodiment provided with (4) and the indirect vaporization cooling unit 4 is similarly applicable.

27 is a diagram showing the configuration of main parts of the ventilation device of each embodiment. For example, in the ventilation device 1D having the heat exchange unit 31 and the indirect vaporization cooling unit 4 described in FIGS. 10A and 10B, between the heat exchange unit 31 and the indirect vaporization cooling unit 4. The diffusion plate 52 is provided in the air supply flow path 9D. The diffusion plate 52 agitates the air passing through the air supply flow path 9D.

The air flowing into the heat exchange unit 31 or the indirect vaporization cooling unit 4 is biased toward the center, and it is difficult to achieve uniform flow for each flow path such as the indirect vaporization element 11. For this reason, by providing the diffuser plate 52 etc. in front of the indirect vaporization cooling unit 4, the cooling ability can be improved by stirring air and making it flow substantially uniform with respect to each flow path.

In addition, the diffusion plate 52 may be provided in front of the heat exchange unit 31. In addition, in the ventilation apparatus 1G provided with the dehumidification unit 33 and the indirect vaporization cooling unit 4 demonstrated by FIG. 7 etc., for example, the air supply flow path between the dehumidification unit 33 and the indirect vaporization cooling unit 4 ( 9G) may be provided with the diffusion plate 52, or may be provided in front of the dehumidification unit 33, and is applicable to the ventilation apparatus of other embodiment.

28 is a diagram showing the configuration of another main part of the ventilation device in each embodiment. For example, in the ventilation apparatus 1D provided with the heat exchange unit 31 and the indirect vaporization cooling unit 4 described in FIGS. 10A and 10B, the heat exchange unit 31 and the indirect vaporization cooling unit 4 are provided. Air flow path of the first flow path 32a of the heat exchange element 32 constituting the heat exchange unit 31 and the indirect vaporization element 11 constituting the indirect vaporization cooling unit 4 by arranging the adjacent parts thereof. The gap between the inlet of (11b) should be as small as possible. In FIG. 28, for example, the air supply flow rate adjustment damper provided on the upstream side of the heat exchange unit 31, and the exhaust flow rate adjustment damper provided on the upstream side of the indirect vaporization cooling unit 4, for example, are illustrated. I'm not doing it.

When the distance between the heat exchange unit 31 and the indirect vaporization cooling unit 4 is wide, the air flowing into the indirect vaporization cooling unit 4 is biased in the center of the flow, and for each flow path of the indirect vaporization element 11. It is hard to be a uniform flow. For this reason, the cooling capacity can be improved by arranging the heat exchange unit 31 and the indirect vaporization cooling unit 4 in close proximity and making the flow substantially uniform with respect to each flow path.

In addition, the gap between the heat exchange unit 31 and the indirect vaporization cooling unit 4 is preferably about 5 cm or less. Moreover, even if the heat exchange element 32 and the indirect vaporization element 11 are integrally comprised so that the 1st flow path 32a of the heat exchange element 32 and the product air flow path 11b of the indirect vaporization element 11 may communicate. good.

In addition, when the outlet of the first flow path 32a of the heat exchange element 32 and the inlet of the product air flow path 11b of the indirect vaporization element 11 are made the same, the flow of air becomes efficient. Further, by miniaturizing each unit, the apparatus can be miniaturized.

29A to 29C are other configuration diagrams of the indirect vaporizing element showing the main part configuration of the ventilation device of each embodiment. 29A is an external perspective view, FIG. 29B is an exploded perspective view, and FIG. 29C is a sectional view.

The indirect vaporization element 11 'is composed of a drying cell 21 having a plurality of first flow passages 21b partitioned into partitions 21a and a plurality of partitions 22a as shown in Fig. 29B. The wet cell 22 which has the 2nd flow path 22b, and the partition 23 which partitions the dry cell 21 and the wet cell 22 are provided, The entrance of each flow path is formed in the other surface, A part of the 1st flow path 21b and the 2nd flow path 22b is comprised so that it may become parallel.

The partition 23 has a moisture proof film 23a formed of a polyethylene film or the like and a wet layer 23b formed of pulp or the like, as shown in Fig. 29C, and the moisture proof film 23a is formed in the dry cell 21. And the wet layer 23b faces the wet cell 22.

Thereby, in the indirect vaporization element 11 ', the 2nd flow path 22b becomes the working air flow path 11a shown in FIG. 1 etc., and the 2nd flow path 21b becomes the product air flow path 11b.

In the indirect vaporization cooling element 11 ′, when a part of the working air flow passage 11 a and the product air flow passage 11 b are arranged in parallel, the partition 23 of the working air flow passage 11 a and the product air flow passage 11 b is provided. Since the part which is contacting through () becomes long, the cold heat of the working air WA cooled by vaporization heat can be transmitted to product air PA efficiently, and can improve a cooling capability.

<Installation example of the ventilation device>

30 is a configuration diagram showing an example of a building of this embodiment, showing an example of installation of the ventilation device 1. The ventilation device 1 described in FIG. 1 or the like is installed on the rear surface of the ceiling of the building 101 or the like. The building 101 includes a plurality of living rooms 102, a toilet 103, a washroom 104a, a bathroom 104b, and the like, and the air supply outlet 6 shown in FIG. It is connected to the air supply port 105 provided in the ceiling of 102 etc. via the duct 106.

In addition, although FIG. 1 etc. is equipped with one air supply outlet 6, in order to supply air supply SA to several living room 102, the branch chamber 106a is installed in the middle of the duct 106, and 1 is provided. The two ducts 106 may be branched into the plurality of ducts 106.

In addition, the ventilation device 1 may be provided with the some air supply blow-out 6, and the ventilation apparatus 1 provided with the some air supply blow-out 6 and the branch chamber 106a may be combined.

The ventilation suction port 8 shown in FIG. 1 and the like of the ventilation device 1 is connected to the suction port 107 provided in the ceiling of the toilet 103, for example, via a duct 107a or the like. The air supplied into the living room 105 is collected at the inlet 107 through the undercut portion, the insect screen, etc. of the door, and the ventilation RA sucked from the ventilation inlet 8 is the working air WA as described in FIG. The exhaust gas is used as an exhaust gas so as not to return to the living room. Thereby, odor can be exhausted. The inlet 107 may be provided on the lower surface of the main body of the ventilator 1 as shown in FIG. 1, or may be provided with a plurality of the inlet vents 7. Moreover, you may provide the suction port 107 in the living room 102 which provided the air supply 105, respectively.

The outside air intake port 5 shown in FIG. 1 and the like of the ventilation device 1 is connected to the intake port 109 provided on the wall surface such as the veranda 108 through the duct 109a. In addition, the exhaust outlet 8 is connected to the exhaust port 110 provided in the wall surface, such as the veranda 108, through the duct 110a. Thereby, the ventilation apparatus 1 can blow in the outdoor air OA from the outdoors, and can also exhaust the ventilation RA from the toilet 103 etc. to the outdoors as exhaust EA.

As shown in FIG. 1 and the like, the ventilation device 1 includes a water supply and drainage device 12 and a drain pan 13 in the indirect vaporization cooling unit 4. In the indirect vaporization cooling unit 4, as described above, water is supplied by the water supply and drainage device 12 to cool the working air WA with the heat of vaporization of water, and the unconsumed water is stored in the drain pan 13. do. Then, the drain pan 13 and the drain drain 111 provided in the veranda 108 or the like are connected by the hose 111a, and the water of the drain pan 13 can be drained out of the apparatus by the water supply / drainage device 12 or the like. It is supposed to be.

Here, the air supply device 41 connected to the ventilation device 1N described with reference to FIG. 21 is provided, for example, in the duct 106 connecting the ventilation device 1 and the air supply device 105. In addition, the exhaust device 42 connected to the ventilation device 1P described with reference to FIG. 22 is provided in the duct 107a which connects the ventilation device 1 and the suction port 107, for example.

31 is a configuration diagram showing an example of an air supply port. The air supply unit 105 includes an air supply grill 61 for blowing air supply SA, a human body sensor 62 detecting whether a person is present in the living room 102 in which the air supply unit 105 is installed, and an air supply unit. The temperature sensor 63 which detects the temperature of the living room 102 in which 105 was provided is provided.

In addition, the air supply port 105 may be provided with the ion generator 64. The ion generator 64 generates positive ions and negative ions and supplies them to the air supply SA. Here, by generating approximately the same number of positive ions and negative ions, the air supply SA including approximately the same number of positive ions and negative ions is supplied to the living room 102. Thereby, generation | occurrence | production of the mold in the living room 102 can be suppressed. Further, by generating more negative ions than only negative ions or positive ions, the negative ions are supplied to the living room 102. As a result, a relaxation effect can be obtained in the living room 102.

In addition, the air supply unit 105 is provided with a damper for adjusting the air supply flow rate, and when there is an increase or decrease in the air supply flow rate, the air supply amount in the air supply unit 105 of the arbitrary or predetermined living room 102 is adjusted to provide a building. The ventilation amount in the whole may be protected.

<Configuration example of ventilation device for branching air supply>

32 is a configuration diagram showing an example of the ventilation device 1T of the nineteenth embodiment. The ventilation device 1T is provided with a plurality of air supply outlets 6, and at the same time, it is possible to control the flow rate at each air supply outlet 6. In addition, as a whole structure of a ventilation apparatus, the ventilation apparatus 1A of 1st Embodiment is demonstrated to an example.

The ventilator 1T is a supply air inlet port and, in this example, includes a first air supply outlet 6a and a second air supply outlet 6b. In addition, the ventilation device 1T includes an air supply fan 2, an exhaust fan 3, and an indirect vaporization cooling unit 4, and the air supply flow path 9A is connected to the indirect vaporization element 11 from the air supply fan 2. The product air flow passage 11b communicates with the first air supply outlet 6a and the second air supply outlet 6b.

The ventilation flow path 10A communicates from the ventilation intake port 7 to the exhaust outlet 8 through the working air flow path 11a of the indirect vaporization element 11 and the exhaust fan 3.

The air supply flow path 9A includes, for example, an air supply flow rate adjusting damper 14 on an upstream side of the indirect vaporization cooling unit 4. In addition, the exhaust flow path 10A includes an exhaust flow rate adjustment damper 15 on an upstream side of the indirect vaporization cooling unit 4, for example.

In addition, an air supply flow rate adjustment damper 19 is provided at at least one of the first air supply outlet 6a and the second air supply outlet 6b. In this example, the air supply flow volume adjustment damper 19 is provided in the 2nd air supply blow-out port 6b. By adjusting the opening degree of the air supply flow volume adjustment damper 19, the flow volume of the air supply SA which flows through the 2nd air supply blow-out port 6b is adjusted.

Next, the operation of the ventilation device 1T will be described. When the air supply fan 2 is driven, the ventilation device 1T generates a flow of air toward the first air supply outlet 6a and the second air supply outlet 6b in the air supply flow path 9A. As a result, the outside air OA is sucked from the outside air intake port 5 and passes through the product air flow passage 11b of the air cleaning filter 16 and the indirect vaporization element 11 to the first air supply outlet 6a and the second air supply. It is supplied indoors as air supply SA from the blowout opening 6b.

In addition, when the exhaust fan 3 is driven, a flow of air toward the exhaust outlet 8 is generated in the exhaust flow path 10B. Thereby, the ventilation RA from the room is sucked in from the ventilation intake port 7, and is discharged to the outside as the exhaust EA from the exhaust blowout port 8 through the working air flow passage 11a of the indirect vaporization element 11. .

As described above, in the indirect vaporization element 11, the working air WA is cooled by the heat of vaporization of water, and the product air PA is cooled by receiving the cold heat of the working air WA, and thus passes through the product air flow path 11b. In one outdoor air OA, the humidity (absolute humidity) does not change and the temperature goes down. In addition, the ventilation RA, which has passed through the working air flow passage 11a, increases in humidity but decreases in temperature.

Therefore, the indoor temperature is blown by blowing outside air OA which has passed through the product air flow path 11b of the indirect vaporization element 11 as the air supply SA from the 1st air supply outlet 6a and the 2nd air supply outlet 6b. Can be lowered.

In the ventilation device 1T, the flow rate of the product air PA passing through the product air flow path 11b of the indirect vaporization element 11 is adjusted by the opening degree of the air supply flow rate adjustment damper 14. In addition, the flow rate of the working air WA passing through the working air flow passage 11a of the indirect vaporization element 11 is adjusted by the opening degree of the exhaust flow rate adjusting damper 15.

Thereby, the air supply SA of which the air supply flow volume adjustment damper 14 and the exhaust flow volume adjustment damper 15 or both are operated, and blows out from the 1st air supply blow-out port 6a and the 2nd air supply blow-out port 6b. The temperature is controlled.

In addition, in the ventilation device 1T, by operating the air supply flow rate adjustment damper 19, the flow rate of the air supply SA blown out from the first air supply outlet 6a and the air supply SA blown out from the second air supply outlet 6b. Flow rate is controlled.

For example, by increasing the opening degree of the air supply flow rate adjustment damper 19, it is possible to increase the flow rate of the air supply SA blown out from the second air supply outlet 6b, thereby increasing the opening degree of the air supply flow rate adjustment damper 19. By making it small, the flow volume of air supply SA blown out from the 2nd air supply blow-out port 6b can be reduced.

As shown in FIG. 30, when supplying air to the plurality of living rooms 102 from the ventilation device 1, the distances from the ventilation device 1 to each living room 102 are not equal, so that each of the ducts 106 Often different lengths.

When the air supply SA is supplied at the same flow rate and air is supplied to each living room 102 from the duct 106 having a different length, the cooling temperature is different in the living room 102. The cooling temperature is also different depending on the difference in the area of the living room 102. For this reason, as shown in FIG. 32, when the flow volume can be adjusted in the plurality of air supply outlets 6, and the air volume is controlled according to the length of the duct 106 or the like, the cooling temperature of each living room 102 is approximately equal. can do.

In addition, although two examples of air supply outlets were demonstrated in FIG. 32, two or more may be sufficient. In addition, although the flow rate was adjusted with a damper, the structure which can make the diameter of the air supply blow-out port 6 variable may be sufficient. In addition, the branch chamber 106a shown in FIG. 30 may have the same function.

In addition, as shown in FIG. 30, when the ventilation RA is performed from one room (toilet), as shown in FIG. 32, there is only one ventilation inlet 7, but the ventilation RA is provided in a plurality of rooms ( In the case of a living room), a plurality of ventilation suction ports 7 may be provided. In this case, by providing the damper which comprises the ventilation flow volume adjustment means in the at least 1 ventilation intake port 7, the flow volume of ventilation RA is adjusted, and the ventilation flow volume flow rate is adjusted for every room, for example, from arbitrary rooms. The ventilation can be controlled such as stopping.

Also in the ventilation device 1T, by using the ventilation RA, the outside air can be cooled and blown while exhausting the indoor air to the outside, and the ventilation device 1T has a function of cooling while performing ventilation.

Thereby, by adjusting the flow volume of ventilation RA and the flow volume of air supply SA, the ventilation operation which replaces the air of a room at predetermined time is possible, and can also be used also as a ventilation apparatus for 24 hours. For this reason, in the ventilation device 1T, temperature control is performed by the flow rate of the working air WA and the flow rate of the product air PA, so that the desired cooling temperature can be obtained and the ventilation amount can be secured to ensure a predetermined ventilation amount. Control for interlocking the cooling operation is performed.

<Control example of the ventilation device>

33 is a block diagram showing an example of a control function of a ventilation device. Moreover, as a ventilation apparatus, the structure provided with the dehumidification unit is taken as an example. The ventilator 1 includes a fan motor 72 for driving the air supply fan 2 and the exhaust fan 3 to the CPU 71 constituting the control means, and the air supply flow rate adjustment damper 14 and the exhaust flow rate adjustment damper ( 15 and the damper motor 73 and the dehumidification rotor motor 74 for driving the dehumidification rotor 36 of the dehumidification unit 33 are connected, and the CPU 71 controls these drive sources to supply the air supply SA. Temperature control and the like are performed.

In addition, the water supply valve 12a and the drain valve 12b of the water supply and drainage device 12 are connected to the CPU 71 to perform the water supply and drainage control in the indirect vaporization cooling unit 4. The temperature sensor 17 provided in the air supply outlet 6 and the like in the CPU 71, the water level sensor 13a provided in the drain fan 13, and the air supply unit 105 shown in FIG. The human body detection sensor 62 and the temperature sensor 63 are connected, and temperature control of the air supply SA is performed based on various detection information.

In addition, the setting switch 75 which configures the setting means in the CPU 71 to perform various operations and the like, the cooling operation stop switch 76 constituting the instruction means, and the memory 77 which stores setting information and the like are connected. Based on various operations and settings, temperature control of the air supply SA, control of operation stop, and the like are performed.

In addition, when the ion generator is provided in the ventilation apparatus 1 etc., an ion generator is connected to CPU71, and generation | occurrence | production of positive ion and negative ion is controlled.

<Control by temperature sensor>

34 is a flowchart showing an example of cooling control by the temperature sensor, with reference to FIG. 32 and the like for a specific control example. Here, it is assumed that a desired set temperature value is registered in advance in the memory 77. In addition, it is assumed that the fan motor 72 or the like is driven to perform the cooling operation.

Step SA1: The CPU 71 reads the temperature of the air supply SA from the temperature sensor 17. Alternatively, the temperature of the living room 102 is read from the temperature sensor 63.

Step SA2: The CPU 71 reads the set temperature value from the memory 77.

Step SA3: The CPU 71 compares, for example, the temperature of the air supply SA read out from the temperature sensor 17 with the set temperature value read out from the memory 77. When the temperature of the air supply SA is lower than the set temperature value, control of the development is maintained without changing the fan rotation speed, damper opening degree, or the like, and the flow returns to step SA1.

Step SA4: In the comparison of step SA3, when the temperature of the air supply SA is higher than the set temperature value, the CPU 71 lowers the temperature of the air supply SA, for example, indirect vaporization cooling shown in FIG. 1 and the like. The flow rate of the working air WA of the unit 4 is increased. For example, the CPU 71 increases the flow rate of the working air WA by controlling the damper motor 73 to increase the opening degree of the exhaust flow rate adjustment damper 15.

When the flow rate of the working air WA in the indirect vaporization cooling unit 4 increases, the temperature of the product air PA decreases as described above. Therefore, the temperature of the air supply SA can be lowered.

The temperature control of the air supply SA may be performed by controlling the fan air volume, controlling the rotation speed of the dehumidification rotor 36, and the like, in addition to controlling the opening degree of the exhaust flow rate adjustment damper 15.

In addition, in step SA3, when the temperature of the air supply SA is lower than the set temperature value, the control of the phenomenon is maintained, but the control to increase the temperature of the air supply SA by reducing the flow rate of the working air flow rate WA, etc. May be performed.

In addition, when the setting date data such as the date and time for performing the operation at the desired set temperature value is registered in the memory 77, and the current date and time are the date and time specified by the setting date data registered in the memory 77, As described above, control to obtain a desired set temperature may be performed. In addition to the temperature control, the ventilation flow rate may be controlled.

Here, the memory 77 is a modifiable memory, and the set temperature value can be corrected by the operation of the setting switch 75. As the setting switch 75, an operation panel provided in the ventilation device 1, a remote control device connected by wire, wireless, infrared light, or the like is used.

By modifying the set temperature value registered in the memory 77, a desired air supply temperature can be obtained. The set temperature value registered in the memory 77 may be temperature data, the rotation speed of the fan motor 72, the drive voltage of the fan motor 72, the damper opening degree by the damper motor 73, and the damper motor ( 73) may be a driving voltage.

35 is a flowchart showing another example of cooling control by the temperature sensor. Here, it is assumed that a desired set temperature value is registered in advance in the memory 77. In addition, it is assumed that the fan motor 72 or the like is driven to perform the cooling operation.

Step SB1: The CPU 71 reads the temperature of the air supply SA from the temperature sensor 17. Alternatively, the temperature of the living room 102 is read from the temperature sensor 63.

Step SB2: The CPU 71 reads the set temperature value from the memory 77.

Step SB3: The CPU 71 compares, for example, the temperature of the air supply SA read out from the temperature sensor 17 with the set temperature value read out from the memory 77. When the temperature of the air supply SA is lower than the set temperature value, control of the development is maintained without changing the fan rotation speed, damper opening degree, or the like, and the flow returns to step SA1.

Step SB4: In the comparison of step SB3, when the temperature of the air supply SA is higher than the set temperature value, since the CPU 71 lowers the temperature of the air supply SA, for example, the water supply and drainage device shown in FIG. The opening degree of the water supply valve 12 of 12 is increased, and the water supply amount to the indirect vaporization element 11 is increased.

In the indirect vaporization cooling unit 4, as described above, the working air WA is cooled using the heat of vaporization of the water in the indirect vaporization element 11, so that when the amount of water supplied to the indirect vaporization element 11 increases, the working air is increased. The temperature of the WA decreases, and the temperature of the product air PA which receives the cold heat of the working air WA decreases. Therefore, the temperature of the air supply SA can be lowered.

Here, the set temperature value registered in the memory 77 can be corrected. Further, the flow rate control of air described in FIG. 34 and the control of the water supply amount may be combined.

<Control by human body sensor>

36 is a flowchart showing an example of cooling control by a human body sensor. In this case, it is assumed that a desired set temperature value switched according to the presence or absence of a person is registered in the memory 77. In addition, it is assumed that the fan motor 72 and the like are driven to perform the cooling operation.

Step SC1: The CPU 71 reads the presence or absence of a person in the living room 102 shown in FIG. 30 from the human body detection sensor 62.

Step SC2: The CPU 71 reads the first set temperature value and the second set temperature value from the memory 77. Here, a 1st set temperature value is made into the cooling temperature when there is a person, and a 2nd set temperature value is made into the cooling temperature when there is no person.

Step SC3: The CPU 71 determines the presence or absence of a person from the output of the human body detection sensor 62.

Step SC4: In the judgment of step SC3, when there is a person in the living room 102, the CPU 71 causes the fan rotation speed by the fan motor 72 to adjust the temperature of the air supply SA to the first set temperature value. By controlling the damper opening degree by the damper motor 73, the rotation speed control of the dehumidification rotor 36, etc., for example, by adjusting the flow rate of the working air WA, the temperature of the air supply SA is adjusted to the first set temperature value. do.

Step SC5: When there is no person in the living room 102 at the judgment of step SC3, the CPU 71 changes the fan rotation speed by the fan motor 72 to set the temperature of the air supply SA to the second set temperature value. The damper opening degree etc. by the damper motor 73 are controlled, for example, the flow volume of working air WA is adjusted, and the temperature of air supply SA is made into a 2nd set temperature value.

In this way, by changing the cooling temperature with or without a person, for example, when there is no person, power consumption and the like can be suppressed by setting the cooling temperature high.

Here, the first set temperature value and the second set temperature value registered in the memory 77 can be corrected by the operation of the setting switch 75. Thereby, desired air supply temperature can be obtained.

37 is a flowchart showing an example of ventilation amount control by a human body sensor. Here, it is assumed that a desired ventilation flow rate value that is switched in accordance with the presence or absence of a person is registered in the memory 77. In addition, it is assumed that the fan motor 72 or the like is driven to perform the cooling operation.

Step SD1: The CPU 71 reads the presence or absence of a person in the living room 102 shown in FIG. 30 from the human body sensor 62. FIG.

Step SD2: The CPU 71 reads the first set ventilation flow rate value and the second set ventilation flow rate value from the memory 77. Here, the first set ventilation flow rate value is the ventilation flow rate when there is a person, and the second set ventilation flow rate value is the ventilation flow rate when there is no person.

Step SD3: The CPU 71 determines the presence or absence of a person from the output of the human body sensor 62.

Step SD4: In the judgment of step SD3, when there is a person in the living room 102, the CPU 71 causes the fan rotation speed and the damper motor (the fan motor 72) to make the ventilation flow rate the first set ventilation flow rate value. 73) by controlling the damper opening degree and the like, by adjusting the flow rate of the air supply SA and the flow rate of the suction RA, the ventilation flow rate is the first set ventilation flow rate value.

Step SD5: When there is no person in the living room 102 at the judgment of step SD3, the CPU 71 causes the fan rotation speed and the damper motor (the fan motor 72) to set the ventilation flow rate as the second set ventilation flow rate value. 73), the damper opening degree and the like are controlled to adjust the flow rate of blowing air SA and the flow rate of suction RA, so that the ventilation flow rate is the second set ventilation flow rate value.

In this way, by changing the ventilation flow rate in the presence or absence of a person, power consumption and the like can be suppressed by, for example, setting a small ventilation flow rate when there is no person.

Here, the first set ventilation flow rate value and the second set ventilation flow rate value registered in the memory 77 can be corrected by the operation of the setting switch 75. As a result, a desired ventilation flow rate can be obtained.

<Start / stop control>

The ventilator 1 shown in FIG. 1 and the like functions as an air conditioner for controlling the temperature of the living room by using the indirect vaporization cooling unit 4, and stops the cooling function by the indirect vaporization cooling unit 4 to control temperature control. It does not accompany and functions as a ventilation apparatus which performs ventilation (exchange of air and ventilation) of a living room.

Fig. 38 is a flowchart showing an example of manual start / stop control. First, the stop operation of the manual cooling function will be described.

Step SE1: The CPU 71 reads the output of the cooling operation stop switch 76.

Step SE2: The CPU 71 determines whether the cooling stop is instructed from the output of the cooling operation stop switch 76.

Step SE3: When the cooling stop is instructed in the determination of step SE2, the CPU 71 closes the water supply valve 12a of the water supply and drainage device 12 shown in FIG. 1, for example, to the indirect vaporization element 11. Stop water supply. When the water supply to the indirect vaporization element 11 is stopped, cooling of the working air WA by evaporation of water is not performed, and the product air PA is not cooled. Therefore, the air supply SA does not perform temperature control by the indirect vaporization cooling unit 4. As a result, the cooling function can be stopped.

In addition, when the water supply valve 12a is closed and the water supply to the indirect vaporization element 11 is stopped, the CPU 71 may open the drain valve 12b to drain the water from the drain pan 13. As a result, when the cooling function is stopped for a long time such as in winter, the drain pan 13 can be in a state in which no water remains.

Step SE4: When the start of the cooling function is instructed in the determination of step SE2, the CPU 71 opens the water supply valve 12a of the water supply and drainage device 12 shown in FIG. Water supply with). When water is supplied to the indirect vaporization element 11, the working air WA is cooled by the evaporation of water, and the product air PA is cooled by receiving the cooling heat of the working air WA. Therefore, the air supply SA performs temperature control by the indirect vaporization cooling unit 4, whereby the cooling function can be activated.

In addition, when the water supply valve 12a is opened, the CPU 71 closes the drain valve 12b so that water can be stored in the drain pan 13.

Fig. 39 is a flowchart showing an example of automatic start / stop control. Next, the operation of stopping the automatic cooling function will be described. Here, in the memory 77, set date data such as date and time for stopping the cooling function is registered in advance.

Step SF1: The CPU 71 reads out current date data from a calendar function or the like not shown.

Step SF2: The CPU 71 reads the set date data of the cooling stop period from the memory 77.

Step SF3: The CPU 71 compares the current date data with the setting date data read out from the memory 77.

In the comparison of step SF4: step SF3, if the current date falls within the cooling stop period, the CPU 71 closes the water supply valve 12a of the water supply and drainage device 12 shown in FIG. The water supply to the element 11 is stopped. When the water supply to the indirect vaporization element 11 stops, the cooling function can be stopped as described above.

In addition, when the water supply valve 12a is closed and the water supply to the indirect vaporization element 11 is stopped, the CPU 71 may open the drain valve 12b to drain the water from the drain pan 13.

In the comparison of step SF5: step SF3, if the current date does not enter the cooling stop period, the CPU 71 indirectly opens the water supply valve 12a of the water supply and drainage device 12 shown in FIG. Water is supplied to the vaporization element 11, and a cooling function is started.

In addition, when the water supply valve 12a is opened, the CPU 71 closes the drain valve 12b so that water can be stored in the drain pan 13.

Here, in the flowchart of FIG. 39, the stopping and starting of the cooling function are performed based on the date. However, the set temperature value for stopping the cooling function is registered in the memory 77 and is detected by an outside air temperature sensor (not shown). By comparing the outdoor temperature with the set temperature value, the cooling function may be stopped when the outdoor temperature falls below the set temperature value, and the cooling function may be activated when the outdoor temperature exceeds the set temperature value.

Here, the setting date data and the setting temperature value registered in the memory 77 can be corrected by the operation of the setting switch 75. Thereby, a cooling function can be stopped for a desired period.

<Drainage control>

In the drain control of the drain pan 13, drain control according to the water level is performed in addition to the drain control accompanying the stop of operation.

40 is a configuration diagram showing an example of the drain pan 13. The drain pan 13 is provided with the drain valve 12b in the position which can drain all the accumulated water. Moreover, the water level sensor 13a which detects that the predetermined amount of water accumulates is provided. In addition to the water level, the amount of water accumulated by weight or quantity may be detected.

In addition, the drain pan 13 includes a drain port 13b at a position capable of discharging water above a predetermined level. The drain valve 12b and the drain port 13b are connected to the drain drain port 111 shown in FIG. 30, and the water is drained out of the building. In addition, the drain of the drain pan 13 may be connected to sewage, or may be used as the washing water of the toilet.

41 is a flowchart showing an example of drainage control, and the drainage operation in accordance with the change of the water level will be described.

Step SG1: The CPU 71 reads the output of the water level sensor 13a.

Step SG2: The CPU 71 determines whether the water level of the drain pan 13 exceeds a predetermined amount from the output of the water level sensor 13a.

Step SG3: When the water level of the drain pan 13 exceeds the predetermined amount P1 in the judgment of step SG2, the CPU 71 opens the drain valve 12b of the water supply and drainage device 12 to drain the drain pan 13. ) To drain the water. In addition, while opening the drain valve 12b, the water supply valve 12a is closed and water supply to the indirect vaporization element 11 is stopped.

Step SG4: If the water level of the drain pan 13 does not exceed the predetermined amount P1 at the judgment of step SG2, the CPU 71 maintains the drain valve 12b of the water supply and drainage device 12 closed. Do not drain. If the water level sensor 13a is configured to detect that the amount of water stored in the drain pan is lower than the predetermined amount, the water supply valve 12a is opened to supply water to the indirect vaporization element 11.

In the above control, the water level of the drain pan 13 is monitored to prevent excessive water shortage, but there is a possibility that normal control cannot be performed, such as when the water level sensor 13a is broken.

In this example, the drain pan 13 is provided with the drain port 13b, and the water more than predetermined water level P2 can be discharged | emitted from the drain port 13b. Thereby, overflow can be prevented even if normal control cannot be performed in the case where the water level sensor 13a has failed.

<Water collection structure>

In the indirect vaporization cooling unit 4, since the working air WA is cooled by the heat of vaporization of water, water is consumed. Since the working air WA becomes air of high humidity, water consumption can be reduced by recovering and reusing water from the working air WA.

42A and 42B are configuration diagrams showing the first embodiment of the indirect vaporization cooling unit including the water recovery device. 42A is a plan view schematically showing the configuration of the indirect vaporization cooling unit 4A, and FIG. 42B is a side sectional view schematically showing the configuration of the indirect vaporization cooling unit 4A. Here, in the indirect vaporization cooling unit 4A of FIGS. 42A and 42B, the ventilation RA is used as the working air WA as described in FIG. 1 and the like, but as described in FIGS. 2A to 2C and the like. The form which uses outside air OA as working air WA may be sufficient.

4 A of indirect vaporization cooling units are collection apparatuses 81A, and the water supply piping 82 which comprises the water supply and drainage apparatus 12 is arrange | positioned at the outlet side of the working air flow path 11a in the upper part of the indirect vaporization element 11, and is arranged. do. The water supply pipe 82 is arranged meandering to lengthen the flow path length. In addition, the water supply piping 82 is a structure which supplies water to the indirect vaporization element 11 from a front-end | tip part, for example.

Thereby, the working air flow path 11a of the indirect vaporization element 11 communicates with the exhaust flow path 10 through the space provided with the water supply pipe 82, and the water supply pipe (in the discharge flow path of the working air WA) 82 is disposed.

As described above, in the indirect vaporization element 11, when the working air WA passing through the working air flow passage 11a is cooled by the heat of vaporization of water, and the working air WA is cooled, the product air flow passage 11b is opened. The product air PA passing through is cooled by being cooled by the working air WA.

Thereby, the ventilation RA which passed the working air flow path 11a of the indirect vaporization element 11 turns into air of high humidity.

When the air of high humidity passes through the space in which the water supply pipe 82 is installed, it cools by the cold heat of the supply water which flows through the water supply pipe 82, and moisture condenses. And since the water supply piping 82 is arrange | positioned above the indirect vaporization cooling element 11, the dew condensation water is dripped from the water supply piping 82 to the indirect vaporization cooling element 11, and is reused.

43A and 43B are configuration diagrams showing a second embodiment of the indirect vaporization cooling unit including the water recovery device. 43A is a plan view schematically showing the configuration of the indirect vaporization cooling unit 4B, and FIG. 43B is a side sectional view schematically showing the configuration of the indirect vaporization cooling unit 4B. Here, in the indirect vaporization cooling unit 4B of FIGS. 43A and 43B, the ventilation RA is used as the working air WA as described with reference to FIG. 1 and the like, but as described with reference to FIGS. 2A to 2C and the like. The form which uses outside air OA as a working air WA may be sufficient.

The indirect vaporization cooling unit 4B branches off from the exhaust passage 10 upstream of the indirect vaporization cooling unit 4B as the recovery device 81B, and the exhaust passage 10 and downstream of the indirect vaporization cooling unit 4B. The recovered exhaust pipe 83 communicated with the upper portion of the indirect vaporization cooling unit 4 is provided. The recovery exhaust pipe 83 may be arranged in the discharge flow path of the working air WA.

As described above, in the indirect vaporization element 11, since the working air WA passing through the working air flow passage 11a is cooled by the heat of vaporization of water, the ventilation RA passing through the working air flow passage 11a is characterized by high humidity air. do.

Since the upper side of the indirect vaporization unit 4 is cooled by the cold heat of the ventilation RA which flows through the collection | recovery exhaust piping 83, the air taken out from the working air flow path 11a of the indirect vaporization element 11 condenses moisture. . The condensed water is dropped into the indirect vaporization cooling element 11 and reused.

44A and 44B are block diagrams showing a third embodiment of an indirect vaporization cooling unit equipped with a water recovery device. 44A is a plan view schematically showing the configuration of the indirect vaporization cooling unit 4C, and FIG. 44B is a side sectional view schematically showing the configuration of the indirect vaporization cooling unit 4C. Here, in the indirect vaporization cooling unit 4C of FIGS. 44A and 44B, the ventilation RA is used as the working air WA as described with reference to FIG. 1 and the like, but as described with reference to FIGS. 2A to 2C and the like. The form which uses outside air OA as working air WA may be sufficient.

The indirect vaporization cooling unit 4C is a recovery device 81C, which is a cooling exhaust pipe 84 communicating with the working air passage 11a disposed at the outlet side of the product air passage 11b in the indirect vaporization element 11. And a recovery exhaust pipe 85 in communication with the working air flow passage 11a disposed at the inlet side of the product air flow passage 11b.

The cooling exhaust pipe 84 and the recovery exhaust pipe 85 are in contact with the heat receiving portion 86. The heat receiving portion 86 is configured such that, for example, the small diameter recovery exhaust pipe 85 passes through the large diameter cooling exhaust pipe 84. In addition, there is no distribution of air between the cooling exhaust pipe 84 and the recovery exhaust pipe 85 in the heat receiving portion 86.

In addition, both the cooling exhaust piping 84 and the recovery exhaust piping 85 communicate with the exhaust outlet 8 shown in FIG.

Then, in the indirect vaporization element 11, the outlet air temperature of the working air WA in the working air flow passage 11a disposed on the inlet side of the product air flow passage 11b and the working air flow passage 11a disposed on the outlet side. And outlet humidity are different. That is, the working air WA passing through the working air flow passage 11a disposed on the inlet side of the product air flow passage 11b becomes relatively high temperature and high humidity because the temperature of the product air PA is high. In contrast, the working air WA passing through the working air flow passage 11a disposed at the outlet side of the product air flow passage 11b becomes low temperature and low humidity because the temperature of the product air PA is low.

In this example, moisture is condensed by using the temperature difference of this working air WA. In other words, the relatively high temperature and high humidity working air WA flowing through the recovery exhaust pipe 85 is cooled by the cold heat of the cold air and low humidity working air WA flowing through the cooling exhaust pipe 84 in the heat receiving portion 86 to obtain moisture. This is condensation.

Since the recovery exhaust piping 85 is connected to the upper side of the indirect vaporization element 11, the condensed water is dropped from the recovery exhaust piping 85 to the indirect vaporization cooling element 11 and reused.

As in each of the above examples, the water consumed by the indirect vaporization element 11 is provided with the recovery device 81 and the water can be supplied to the indirect vaporization element 11 again, thereby reducing the consumption of water and reducing the running cost. can do.

The present invention is installed in a general house and is applied to a ventilation device that performs ventilation and air conditioning of a plurality of rooms.

Claims (16)

An air supply flow path communicating with the air supply outlet from the outside air intake port, An exhaust passage communicating with the exhaust outlet through the ventilation inlet; The working air passage communicating with the air supply passage or the exhaust passage and supplied with working air; and a product air passage communicating with the air supply passage and supplied with product air, and the working air is cooled by heat of vaporization of water and partitioned into partition walls. An indirect vaporization cooling unit in which sensible heat exchange between the working air and the product air is performed between the working air passage and the product air passage; A water supply and drainage device having a water supply device to the indirect vaporization cooling unit, a drain pan receiving water supplied water, and a drainage device from the drain pan; And a control means for controlling the drainage device to drain the water of the drain pan. An air supply flow path communicating with the air supply outlet from the outside air intake port, An exhaust passage communicating with the exhaust outlet from the outside air inlet; A working air flow path communicating with the exhaust flow path and a working air flow path supplied with working air, and a product air flow path communicating with the air supply flow path and supplied with product air; An indirect vaporization cooling unit in which sensible heat exchange between the working air and the product air is performed between the product air flow paths; A water supply and drainage device having a water supply device to the indirect vaporization cooling unit, a drain pan receiving water supplied water, and a drainage device from the drain pan; And a control means for controlling the drainage device to drain the water of the drain pan. An air supply flow path communicating with the air supply outlet from the ventilation intake port, An exhaust passage communicating with the exhaust intake port from the ventilation intake port, A working air flow path communicating with the exhaust flow path and a working air flow path supplied with working air, and a product air flow path communicating with the air supply flow path and supplied with product air; An indirect vaporization cooling unit in which sensible heat exchange between the working air and the product air is performed between the product air flow paths; A water supply and drainage device having a water supply device to the indirect vaporization cooling unit, a drain pan receiving water supplied water, and a drainage device from the drain pan; And a control means for controlling the drainage device to drain the water of the drain pan. The drain pan according to claim 1, wherein the drain pan is provided with a water detection sensor, And the control means drains the water of the drain pan by controlling the drainage device in accordance with the storage amount of the drain pan detected by the water detection sensor. The ventilation device according to any one of claims 1 to 4, wherein the control means drains the water of the drain pan by controlling the drainage device when instructed to stop the cooling operation. The ventilation device according to any one of claims 1 to 5, wherein the drain pan includes a drain hole at a position capable of discharging water above a predetermined level. The drain pan is provided with a water detection sensor according to any one of claims 1 to 6, And the control means supplies water in the water supply device in accordance with the storage amount of the drain pan detected by the water detection sensor. 8. The ventilation device according to any one of claims 1 to 7, wherein the water supply device receives a supply of water pipes or stored rainwater. The ventilation device according to any one of claims 1 to 8, wherein the drainage device drains the drainage to sewage or a drain of a building. An air supply flow path communicating with the air supply outlet from the outside air intake port, An exhaust passage communicating with the exhaust outlet through the ventilation inlet; The working air passage communicating with the air supply passage or the exhaust passage and supplied with working air; and a product air passage communicating with the air supply passage and supplied with product air, and the working air is cooled by heat of vaporization of water and partitioned into partition walls. An indirect vaporization cooling unit in which sensible heat exchange between the working air and the product air is performed between the working air passage and the product air passage; A water supply and drainage device installed in the indirect vaporization cooling unit to supply and supply water; And a recovery device for recovering the vaporized water from the indirect vaporization cooling unit and reusing it for water supply. An air supply flow path communicating with the air supply outlet from the outside air intake port, An exhaust passage communicating with the exhaust outlet from the outside air inlet; A working air flow path communicating with the exhaust flow path and a working air flow path supplied with working air, and a product air flow path communicating with the air supply flow path and supplied with product air; An indirect vaporization cooling unit in which sensible heat exchange between the working air and the product air is performed between the product air flow paths; A water supply and drainage device installed in the indirect vaporization cooling unit to supply and supply water; And a recovery device for recovering the vaporized water from the indirect vaporization cooling unit and reusing it for water supply. An air supply flow path communicating with the air supply outlet from the ventilation intake port, An exhaust passage communicating with the exhaust intake port from the ventilation intake port, A working air flow path communicating with the exhaust flow path and a working air flow path supplied with working air, and a product air flow path communicating with the air supply flow path and supplied with product air; An indirect vaporization cooling unit in which sensible heat exchange between the working air and the product air is performed between the product air flow paths; A water supply and drainage device installed in the indirect vaporization cooling unit to supply and supply water; And a recovery device for recovering the vaporized water from the indirect vaporization cooling unit and reusing it for water supply. 13. The working air according to any one of claims 10 to 12, wherein the recovery device passes a water supply pipe constituting the water supply / drainage device through an outlet of the working air flow path, and is working air by cold heat of supply water flowing through the water supply pipe. Ventilation apparatus characterized in that the cooling to recover the moisture condensation. The said recovery apparatus is provided with the collection | recovery exhaust flow path branched from the said air supply flow path or the said exhaust flow path, and in communication with the said exhaust outlet, And cooling the working air by cold heat of the air flowing through the recovery exhaust passage to collect condensation and recover moisture. The said collection apparatus is a cooling exhaust flow path which communicates with the said working air flow path arrange | positioned at the outlet side of the said product air flow path of the said indirect vaporization cooling unit, and the said product air flow path. A recovery exhaust flow path communicating with the working air flow path disposed at an inlet side of the cooling air flow path and having a heat receiving portion with the cooling exhaust flow path, wherein the working air flowing through the recovery exhaust flow path is cooled by cold heat of the working air flowing through the cooling exhaust flow path; And condensation of water to recover moisture. The building provided with the ventilation device in any one of Claims 1-15.

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