JP2020106185A - Heat exchange type ventilation device - Google Patents

Abstract

To provide a heat exchange type ventilation device capable of reducing generation of dew condensation in a heat exchange part.SOLUTION: A heat exchange type ventilation device 1 includes: a window frame 3; a light collection part 4; and a heat exchange part 5. The light collection part 4 is mounted inside the window frame 3 and includes: an indoor side light collection part 14 located on an indoor side; and an outdoor side light collection part 15 located on an outdoor side. The heat exchange part 5 is juxtaposed with the light collection part 4 at a position sandwiched between the indoor side light collection part 14 and the outdoor side light collection part 15, and includes a heat transmission plate 16, an exhaust air duct 17 and an air supply duct 18. The exhaust air duct 17 is provided with an introducing port 19 through which indoor air 6 after heat exchange can be introduced to the air supply duct 18, and an air duct switching part 20 which switches an air duct communicating with an exhaust air flow outlet 9 blowing out the indoor air 6 to the outdoor side to an air duct communicating with the introducing port 19. The air duct switching part 20 performs switch to the air duct communicating with the introducing port 19 when it is determined that dew condensation generates in the exhaust air duct 17.SELECTED DRAWING: Figure 4

Description

The present invention relates to a heat exchange type ventilation device, and more particularly to a heat exchange type ventilation device for windows which is installed in a window to ventilate a room.

In recent years, there has been an increasing demand for reducing the air-conditioning load of homes due to global warming, and a heat exchange type ventilation device having both excellent energy saving performance and workability is required. As such a heat exchange type ventilation device, for example, a heat exchange type ventilation device for windows installed in a window to ventilate a room is known (for example, refer to Patent Document 1).

Hereinafter, a conventional heat exchange type ventilation device 101 for windows will be described with reference to FIGS. 6 and 7. FIG. 6 is a schematic perspective view showing an installation example of the conventional heat exchange type ventilation device 101. FIG. 7 is a schematic perspective view showing the configuration of a conventional heat exchange type ventilation device 101.

As shown in FIG. 6, a conventional heat exchange type ventilation device 101 is embedded in a window frame 102. Further, as shown in FIG. 7, the conventional heat exchange type ventilation device 101 includes a heat exchange element 105 in an exhaust air passage that connects an exhaust air inlet 103 for taking in indoor air and an exhaust air outlet 104 for blowing out indoor air. An exhaust blower 106 is provided. Further, the heat exchange type ventilation device 101 is provided with a heat exchange element 105 and a supply air blower 109 in a supply air passage that connects a supply air inlet 107 for taking in outdoor air and a supply air outlet 108 for blowing out outdoor air. .. By operating the exhaust blower 106 and the supply air blower 109, heat is exchanged between the exhaust air flow (indoor air) and the air supply air (outdoor air) inside the heat exchange element 105.

Japanese Patent Publication No. 2013-525733

However, in the conventional heat exchange type ventilation device 101, since the heat exchange element 105 for exchanging heat between the exhaust air flow and the supply air flow exists inside the window frame 102, the area required for heat exchange is limited to the window frame portion. To be done. For this reason, particularly in winter, the conventional heat exchange type ventilator 101 has a problem that sufficient heat exchange cannot be performed and the temperature of air blown out into the room lowers, which deteriorates comfort. Therefore, in order to cope with such a problem, we are studying a heat exchange type ventilation device in which a light exchanging unit having a light transmitting property is arranged in parallel in a daylighting unit arranged inside a window frame.

Generally, in a heat exchange type ventilator including the conventional heat exchange type ventilator 101, when the temperature of the outside air is low such as in winter, in the portion of the exhaust air passage inside the heat exchange element, which is close to the intake air inlet. Condensation may occur in the exhaust air passage of the heat exchange element due to a decrease in temperature. Therefore, in the heat exchange type ventilation device in which the heat exchange elements are arranged in parallel in the daylighting section, dew condensation occurs in the exhaust air passage of the heat exchange section, which reduces the visibility of the window. Is a concern.

Then, this invention solves the said subject and an object of this invention is to provide the heat exchange type ventilation device which can reduce the generation|occurrence|production of dew condensation in a heat exchange part.

In order to achieve this object, the heat exchange type ventilation device according to the present invention includes a window frame, a daylighting section, and a heat exchange section. The daylighting section is provided at a position surrounded by the window frame, and has an indoor side daylighting section located on the indoor side and an outdoor side daylighting section located on the outdoor side. The heat exchange section is juxtaposed with the lighting section at a position sandwiched between the indoor side lighting section and the outdoor side lighting section, and the indoor air taken in from the indoor side and exhausted to the outdoor side and the indoor air taken in from the outdoor side to the indoor side. Performs heat exchange with the outdoor air to be supplied. The window frame has an exhaust inlet, an exhaust outlet, a supply air inlet, a supply air outlet, an exhaust blower, and an air supply blower. The exhaust air inlet is provided on the indoor side and takes in indoor air. The exhaust outlet is provided outside the room and blows out indoor air. The air supply inlet is provided outside the room and takes in outdoor air. The air supply outlet is provided on the indoor side and blows out outdoor air. The exhaust blower blows indoor air from the exhaust inflow port to the exhaust outflow port. The air supply blower blows outdoor air from the air supply inlet to the air supply outlet. The heat exchange section has a heat transfer plate, an exhaust air passage, and an air supply air passage. The heat transfer plate is provided between the indoor side light collecting portion and the outdoor side light collecting portion and is light transmissive. The exhaust air passage is provided between the indoor side lighting section and the heat transfer plate, and connects the exhaust air inlet and the exhaust air outlet. The air supply air passage is provided between the heat transfer plate and the outdoor daylighting section, and connects the air supply air inlet and the air supply outlet. The heat transfer plate exchanges heat between the indoor air flowing through the exhaust air passage and the outdoor air flowing through the supply air passage. The exhaust air passage is formed with an inlet that can introduce the indoor air after heat exchange into the air supply air passage, and an air passage switching unit that switches the air passage that communicates with the exhaust outlet to the air passage that communicates with the inlet. It The air passage switching unit switches to an air passage communicating with the inlet when it is determined that dew condensation will occur in the exhaust air passage.

According to the present invention, it is possible to provide a heat exchange type ventilation device capable of reducing the occurrence of dew condensation in the heat exchange section.

It is a schematic front view which shows the example of installation of the heat exchange type ventilation device which concerns on one embodiment of this invention. It is the schematic perspective view seen from the indoor side of the heat exchange type ventilation device. It is a schematic perspective view seen from the outdoor side of the heat exchange type ventilation device. It is a schematic sectional drawing of the same heat exchange type ventilation device. It is a block diagram which shows the structure of the control part in the heat exchange type ventilation device. It is a schematic perspective view which shows the example of installation of the conventional heat exchange type ventilation device. It is a schematic perspective view which shows the structure of the conventional heat exchange type ventilation device.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the accompanying drawings. It should be noted that each of the embodiments described below shows a preferred specific example of the present invention. Therefore, the numerical values, shapes, materials, components, arrangement positions and connection forms of the components, steps (processes), the sequence of steps, and the like shown in the following embodiments are examples and limit the present invention. It is not the intention to do. Therefore, among the constituent elements in the following embodiments, the constituent elements which are not described in the independent claims showing the highest concept of the present invention are described as arbitrary constituent elements. Further, in each drawing, the same reference numerals are given to substantially the same configurations, and the duplicate description will be omitted or simplified.

First, a heat exchange type ventilation device 1 according to an embodiment of the present invention will be described with reference to FIGS.

FIG. 1 is a schematic front view showing an installation example of the heat exchange type ventilation device 1. FIG. 2 is a schematic perspective view of the heat exchange type ventilation device 1 installed in a house as seen from the indoor side. FIG. 3 is a schematic perspective view of the heat exchange type ventilation device 1 installed in a house as seen from the outside. FIG. 4 is a schematic cross-sectional view of the heat exchange type ventilation device 1.

In addition, FIG. 1 shows a state in which the heat exchange type ventilation device 1 installed in a house is viewed from the indoor side. In the following description, the left-right direction (left side, right side) is defined and described in a state where the heat exchange type ventilation device 1 is viewed from the inside from the front.

As shown in FIG. 1, the heat exchange type ventilation device 1 is installed as a window on a wall surface 2 of a house, for example. The heat exchange type ventilation device 1 is surrounded by a rectangular window frame 3, a position surrounded by the window frame 3, and a daylighting section 4 for introducing outdoor light into the room, and the window frame 3. It has a light-exchanging heat exchange section 5 arranged in parallel with the daylighting section 4 at a position.

The heat exchange type ventilation device 1 takes in light from the outside into the room through the daylighting part 4 and the heat exchange part 5. Further, the heat exchange type ventilation device 1 operates to perform ventilation while exchanging heat between the indoor air of the house (hereinafter, indoor air 6) and the outdoor air (hereinafter, outdoor air 7).

As shown in FIG. 1, the window frame 3 includes an upper side portion 3a on the upper side, a lower side portion 3b on the lower side which is a pair with the upper side portion 3a, a left side portion 3c on the left side, and a left side portion 3c. And the right side portion 3d on the right side. The window frame 3 is connected to the upper end of the left side portion 3c at the left end of the upper side portion 3a, and is connected to the upper end of the right side portion 3d at the right end of the upper side portion 3a. The window frame 3 is connected to the lower end of the left side part 3c at the left end of the lower side part 3b, and is connected to the lower end of the right side part 3d at the right end of the lower side part 3b.

The material of the window frame 3 is generally metal or resin. It is preferable to use lightweight aluminum or the like as the metal, and it is preferable to use vinyl chloride or polycarbonate having high rigidity as the resin. Further, in order to prevent heat from entering from the outside, it is more preferable to use a resin having lower thermal conductivity than metal as the material of the window frame 3.

The window frame 3 is formed of a hollow member, and is configured to take in the indoor air 6 from the room and blow it to the outside, and take the outdoor air 7 from the room to blow it to the room. Specifically, on the indoor side of the upper side portion 3a of the window frame 3, as shown in FIG. 2, an exhaust air inlet 8 for taking in the indoor air 6 and an air supply air outlet 11 for blowing out the outdoor air 7 are provided. Are formed. On the other hand, on the outdoor side of the lower side portion 3b of the window frame 3, as shown in FIG. 3, an exhaust air outlet 9 for blowing out the indoor air 6 and an air supply inlet 10 for taking in the outdoor air 7 are formed. ing.

The air supply outlet 11 allows the outdoor air 7 blown from the air supply outlet 11 to flow to the lower side 3b side of the window frame 3 along the indoor surface of the daylighting section 4 (indoor side daylighting section 14 described later). The blowing direction is adjusted.

Especially in winter, dew condensation is likely to occur on the indoor side of the daylighting section 4 (inside the indoor side daylighting section 14) based on the temperature difference between the indoor and outdoor areas and the indoor humidity. By adjusting the blowing direction of the outdoor air 7 from the air supply outlet 11 as described above, the outdoor air 7 blown out from the air supply outlet 11 is directed toward the indoor side of the daylighting section 4 (the room of the indoor side daylighting section 14). It is possible to prevent the indoor air 6 from reaching the indoor surface of the daylighting section 4 (indoor side lighting section 14) by flowing between the indoor air 6 (inner side) and the indoor side surface of the daylighting section 4 (indoor side lighting section 14). To be done. As a result, it is possible to suppress the occurrence of dew condensation on the indoor side of the daylighting section 4 (inside the indoor side of the daylighting section 14), or to quickly eliminate the dew condensation that has occurred.

Although not shown, an exhaust filter is attached to the exhaust inlet 8 to remove dust contained in the indoor air 6 by the exhaust filter. Further, an air supply filter is attached to the air supply inlet 10, and dust contained in the outdoor air 7 is removed by the air supply filter. As a result, it is possible to prevent the heat exchange section 5 from being clogged with dust contained in the indoor air 6 or the outdoor air 7 to increase the pressure loss and reduce the exhaust air volume or the supply air volume.

The exhaust filter may be attached in the vicinity of the exhaust inflow port 8, specifically, in the middle of the air passage from the exhaust inflow port 8 to the heat exchange section 5. Further, the air supply filter may be attached in the vicinity of the air supply inlet 10, specifically, in the middle of the air passage from the air supply inlet 10 to the heat exchange section 5.

As shown in FIG. 4, an exhaust blower 12 for blowing the indoor air 6 from the exhaust inlet 8 to the exhaust outlet 9 is installed inside the upper side portion 3a of the window frame 3. On the other hand, inside the lower side portion 3b of the window frame 3, an air supply blower 13 for blowing the outdoor air 7 from the air supply inlet 10 to the air supply outlet 11 is installed. Here, examples of the blower used for the exhaust blower 12 and the supply blower 13 include a cross flow fan and a small blower fan.

In addition, as shown in FIG. 4, a temperature/humidity sensor 23 that detects the temperature and humidity of the indoor air 6 immediately after being taken in from the exhaust air inlet 8 is installed inside the upper side portion 3 a of the window frame 3. .. On the other hand, a temperature sensor 24 that detects the temperature of the outdoor air 7 immediately after being taken in from the air supply inlet 10 is attached inside the lower side portion 3b of the window frame 3. The temperature/humidity sensor 23 and the temperature sensor 24 output the acquired information to the control unit 25 described later.

As shown in FIGS. 1 to 4, the lighting part 4 and the heat exchange part 5 are fixed to the window frame 3 of the upper side part 3 a, the lower side part 3 b, the left side part 3 c, and the right side part 3 d, and are surrounded by the window frame 3. It is located in the The lighting unit 4 is made of a material that transmits light, and is generally made of a material such as a glass material or a reinforced plastic. Although the details will be described later, the heat exchanging portion 5 is also made of a light-transmissive material.

The lighting unit 4 and the heat exchange unit 5 are arranged side by side, as shown in FIG. Specifically, the daylighting section 4 includes an indoor side daylighting section 14 located on the indoor side and an outdoor side daylighting section 15 located on the outdoor side. The heat exchanging section 5 is arranged in parallel with the daylighting section 4 at a position sandwiched between the indoor-side daylighting section 14 and the outdoor-side daylighting section 15. That is, the configuration in which the daylighting section 4 and the heat exchanging section 5 are arranged side by side means that the indoor side daylighting section 14, the heat exchanging section 5, and the outdoor side daylighting section 15 are stacked in this order from the indoor side to the outdoor side. Shows the state of being arranged.

The indoor daylighting section 14 is composed of a pair of first daylighting plates 14b facing each other with the first hollow layer 14a interposed therebetween. Here, the first hollow layer 14a is formed by sandwiching the first spacer member 14c between the pair of first daylighting plates 14b. Further, the first hollow layer 14a is filled with dry air or a low heat conductive gas such as argon, and the first hollow layer 14a functions as a heat insulating layer.

On the other hand, the outdoor side lighting part 15 is composed of a pair of second lighting plates 15b facing each other with the second hollow layer 15a interposed therebetween. Here, the second hollow layer 15a is formed by sandwiching the second spacer member 15c between the pair of second daylighting plates 15b. The second hollow layer 15a is filled with dry air or a low heat conductive gas such as argon, and the second hollow layer 15a functions as a heat insulating layer. In addition, in this Embodiment, the indoor side lighting part 14 and the outdoor side lighting part 15 are made of the same material and have the same structure.

The heat exchange section 5 exchanges heat between the indoor air 6 taken in from the indoor side and exhausted to the outdoor side and the outdoor air 7 taken in from the outdoor side and supplied to the indoor side. The heat exchange unit 5 is configured to include a heat-transmitting plate 16 having light transparency, an exhaust air passage 17, and an air supply air passage 18. The heat-exchangeable area (heat exchange area) of the heat exchanging portion 5 is set to be approximately the same as or larger than the lighting area of the lighting portion 4, as shown in FIGS. 1 to 4.

The heat transfer plate 16 is provided between the indoor side lighting section 14 and the outdoor side lighting section 15, and is provided between the indoor air 6 flowing through the exhaust air passage 17 and the outdoor air 7 flowing through the air supply air passage 18. Heat exchange. As the material of the heat transfer plate 16, a material having light transparency and transmitting only heat for heat exchange, for example, a resin such as polypropylene or polycarbonate or a glass material installed in a conventional window is used. Alternatively, as the material of the heat transfer plate 16, a material having light transparency and capable of transmitting both heat and humidity, for example, a resin such as polyurethane may be used.

On the entire surface of the heat transfer plate 16 on the exhaust air passage 17 side, a translucent conductive layer 22 is formed which generates heat when energized (current flows). For the transparent conductive layer 22, for example, in addition to a thin film made of a transparent conductive oxide such as tin oxide or indium oxide, a Low-E (Low Emissive) coating using silver or the like, which has little absorption of visible light, may be used. it can.

The translucent conductive layer 22 is formed with a pair of power supply terminals (not shown) for supplying power from a power supply (for example, an external power supply for driving the exhaust blower 12 and the air supply blower 13). The translucent conductive layer 22 generates heat by energizing the pair of power supply terminals. The method of controlling the power supply to the transparent conductive layer 22 will be described later with reference to FIG.

The exhaust air passage 17 is an air passage that is provided between the indoor-side daylighting section 14 and the heat transfer plate 16 and connects the exhaust air inlet 8 and the exhaust air outlet 9. The exhaust air passage 17 is configured such that the room air 6 flowing through the exhaust air passage 17 flows from the upper side portion 3a of the window frame 3 toward the lower side portion 3b of the window frame 3.

On the other hand, the air supply air passage 18 is an air passage that is provided between the heat transfer plate 16 and the outdoor daylight collecting portion 15 and communicates the air supply air inlet 10 and the air supply outlet 11. The air supply air passage 18 is configured such that the outdoor air 7 flowing through the air supply air passage 18 flows from the lower side portion 3b of the window frame 3 toward the upper side portion 3a of the window frame 3. That is, the air flow direction of the indoor air 6 flowing through the exhaust air passage 17 and the air flow direction of the outdoor air 7 flowing through the air supply air passage 18 are opposed to each other.

Here, in the present embodiment, by fixing the indoor side lighting part 14 and the heat transfer plate 16 to the window frame 3 so that a gap is created between the indoor side lighting part 14 and the heat transfer plate 16, the exhaust gas is exhausted. The air passage 17 is formed. Further, the air supply air passage 18 is formed by fixing the outdoor side lighting unit 15 and the heat transfer plate 16 to the window frame 3 so that a gap is created between the outdoor side lighting unit 15 and the heat transfer plate 16. .. That is, the heat exchange section 5 according to the present embodiment is formed by attaching the indoor side lighting section 14, the outdoor side lighting section 15, and the heat transfer plate 16 to the window frame 3.

A heat exchange element, which is entirely made of a light-transmissive material and has a heat transfer plate, an exhaust air passage, and an air supply passage, is sandwiched between the indoor side lighting section 14 and the outdoor side lighting section 15. The heat exchange type ventilation device 1 may be formed by fixing the heat exchange type ventilation device 1 to the window frame 3 so as to be juxtaposed with the daylighting part 4 at a different position. In this case, this heat exchange element functions as the heat exchange section 5.

The exhaust air passage 17 is formed with an inlet 19 through which the indoor air 6 after heat exchange can be introduced into the air supply air passage 18. Further, the exhaust air passage 17 is formed with an air passage switching unit 20 configured as a damper for switching the air passage communicating with the exhaust outlet 9 to the air passage communicating with the inlet 19.

When the exhaust air passage 17 is communicated with the exhaust outlet 9 by the air passage switching unit 20, the indoor air 6 after heat exchange is blown out from the exhaust outlet 9. On the other hand, when the exhaust air passage 17 is communicated with the inlet 19 by the air passage switching unit 20, the indoor air 6 after the heat exchange is introduced into the supply air passage 18. The air passage switching unit 20 determines the ratio of the area where the exhaust air passage 17 and the exhaust outlet 9 communicate with the area where the exhaust air passage 17 communicates with the inlet 19 according to the position (angle) of the damper. It can be changed. That is, the air passage switching unit 20 can control the amount of air that can introduce the indoor air 6 after heat exchange from the exhaust air passage 17 to the air supply air passage 18 by controlling the position (angle) of the damper.

A method of controlling the position (angle) of the damper in the air passage switching unit 20 will be described later with reference to FIG.

Next, heat exchange ventilation in the heat exchange type ventilation device 1 will be described with reference to FIG.

The heat exchange type ventilation device 1 drives the exhaust blower 12 and the supply air blower 13 when performing heat exchange ventilation.

The heat exchange type ventilation device 1 drives the exhaust blower 12 provided in the upper side part 3a of the window frame 3 to suck the indoor air 6 from the exhaust air inlet 8 provided in the upper side part 3a on the indoor side, and to exhaust the exhaust blower. The gas flows through the exhaust air passage 17 of the heat exchange unit 5 via 12. The indoor air 6 that has flowed through the exhaust air passage 17 is discharged to the outside from the exhaust air outlet 9 provided on the lower side portion 3b on the outside of the window frame 3.

On the other hand, the heat exchange type ventilation device 1 sucks the outdoor air 7 from the air supply inlet 10 provided on the lower side 3b of the outdoor side by driving the air supply blower 13 provided on the lower side 3b of the window frame 3. The air flows in the air supply air passage 18 of the heat exchange unit 5 via the air supply blower 13. The outdoor air 7 flowing through the air supply air passage 18 is taken into the room from the air supply outlet 11 provided on the upper side portion 3a on the indoor side.

The heat exchanging section 5 heats the indoor air 6 (exhaust air flow) flowing through the exhaust air passage 17 and the outdoor air 7 (air supply airflow) flowing through the air supply air passage 18 via the heat transfer plate 16. Exchange. Thereby, when performing ventilation in winter, the heat exchange unit 5 transfers the heat of the indoor air 6 released to the outside to the outdoor air 7 taken into the room, and suppresses the release of unnecessary heat to the inside of the room. Recovering heat. In addition, when performing ventilation in the summer, the heat exchanging unit 5 transfers the heat of the outdoor air 7 taken into the room to the indoor air 6 which is released to the outside, and suppresses the release of the outdoor heat to the room. doing.

Next, a method for controlling the energization of the translucent conductive layer 22 formed on the surface side of the heat transfer plate 16 on the exhaust air passage 17 side, and the position of the damper of the air passage switching unit 20 formed on the exhaust air passage 17 ( A method of controlling the angle will be described with reference to FIG. FIG. 5 is a block diagram showing the configuration of the control unit 25 that controls the energization of the translucent conductive layer 22 and the position (angle) of the damper of the air passage switching unit 20 in the heat exchange type ventilation device 1.

As shown in FIG. 5, the control unit 25 includes an input unit 25a, a storage unit 25b, a determination unit 25c, and an output unit 25d. Although not shown in FIG. 4, the control unit 25 is installed inside the window frame 3 (for example, inside the upper side portion 3a).

The input unit 25a receives the first information on the temperature and humidity of the indoor air 6 from the temperature/humidity sensor 23. The input unit 25a also receives the second information from the temperature sensor 24 regarding the temperature of the outdoor air 7. The input unit 25a outputs the received first information and second information to the determination unit 25c.

The storage unit 25b stores the third information regarding the heat exchange unit 5. The third information is information about the length of the exhaust air passage 17, the length of the supply air passage 18, the heat exchange efficiency between the exhaust flow and the supply air flow, the air volume set by the user, and the like. The storage unit 25b outputs the third information stored via the input unit 25a to the determination unit 25c.

The determination unit 25c receives the first information and the second information from the input unit 25a, and also receives the third information from the storage unit 25b. The determining unit 25c uses the received first to third information to calculate the dew point of the indoor air 6 and also the temperature distribution of the indoor air 6 in the exhaust air duct 17 (the temperature that decreases due to heat exchange). To estimate.

Then, the determining unit 25c determines whether or not condensation may occur in the exhaust air passage 17 based on the dew point of the indoor air 6 and the temperature distribution of the indoor air 6 in the exhaust air passage 17. The determination unit 25c outputs the determination information regarding the possibility of dew condensation to the output unit 25d.

The output unit 25d receives the determination information from the determination unit 25c. The output unit 25d controls the power supply to the translucent conductive layer 22 based on the received determination information, and also controls the position (angle) of the damper of the air passage switching unit 20.

Specifically, the output unit 25d does not supply power to the translucent conductive layer 22 when there is no possibility of dew condensation in the exhaust air passage 17 from the determination information of the determination unit 25c. To control. On the other hand, if there is a possibility that dew condensation may occur in the exhaust air duct 17 based on the determination information of the determination unit 25c, control is performed so that electric power is supplied to the translucent conductive layer 22.

As described above, the control unit 25 controls the energization of the translucent conductive layer 22. As a result, the energization of the translucent conductive layer 22 is executed only when there is a possibility that dew condensation may occur in the exhaust air passage 17 (or when dew condensation occurs). When the light-transmitting conductive layer 22 is energized, the light-transmitting conductive layer 22 generates heat, so that it is possible to suppress the occurrence of dew condensation in the exhaust air passage 17, or to generate it in the exhaust air passage 17. Condensation can be quickly eliminated.

It should be noted that, based on the degree of possibility of dew condensation occurring in the exhaust air passage 17 (or the amount of dew condensation generated) that is determined based on the determination information of the determination unit 25c, the output unit 25d determines that the transparent conductive layer 22 The amount of electric power supplied to may be changed. That is, the higher the possibility of the occurrence of dew condensation in the exhaust air passage 17 or the larger the amount of dew condensation generated, the output unit 25d may increase the amount of power supplied to the translucent conductive layer 22. .. As a result, it is possible to suppress energy generation in the exhaust air passage 17, or to use only the energy necessary for quickly eliminating the moisture condensation generated in the exhaust air passage 17, so that energy saving can be achieved.

In addition, the output unit 25d determines that the exhaust air passage 17 communicates with the exhaust outlet 9 when there is no possibility of dew condensation in the exhaust air passage 17 based on the determination information of the determination unit 25c. The position (angle) of the damper of the switching unit 20 is controlled. On the other hand, if there is a possibility that dew condensation may occur in the exhaust air passage 17 based on the determination information of the determination unit 25c, the damper of the air passage switching unit 20 is controlled so that the exhaust air passage 17 communicates with the introduction port 19. Control the position (angle).

As described above, the control unit 25 controls the position (angle) of the damper of the air passage switching unit 20. As a result, when dew condensation may occur in the exhaust air passage 17, the indoor air 6 after heat exchange is mixed from the inlet 19 with the outdoor air 7 flowing in the air supply air passage 18. Therefore, the temperature of the outdoor air 7 in the air supply air passage 18 can be raised. Therefore, the temperature decrease on the surface of the heat transfer plate 16 in the exhaust air passage 17 can be suppressed, so that the occurrence of dew condensation in the heat exchange section 5 can be reduced.

It should be noted that, based on the degree of possibility of dew condensation occurring in the exhaust air duct 17 (or the amount of dew condensation generated) that is determined based on the determination information of the determination unit 25c, the output unit 25d causes the output of the air passage switching unit 20. You may control so that the position (angle) of a damper may be changed. That is, as the possibility of dew condensation occurring in the exhaust air passage 17 is lower, or the amount of dew condensation generated is smaller, the area in which the exhaust air passage 17 and the exhaust outlet 9 communicate with each other in the output unit 25d increases. As described above, the position (angle) of the damper of the air passage switching unit 20 is controlled, and the higher the possibility of dew condensation in the exhaust air passage 17 or the larger the amount of dew condensation, the more the output unit 25d. May control the position (angle) of the damper of the air passage switching unit 20 so that the area where the exhaust air passage 17 and the inlet 19 communicate with each other increases.

As a result, when the possibility of dew condensation occurring in the exhaust air passage 17 is high, or when the amount of dew condensation is large, the outdoor air 7 flowing through the air supply air passage 18 is subjected to a large amount of heat exchange. Since the indoor air 6 can be mixed, it is possible to reliably reduce the occurrence of dew condensation in the heat exchange section 5. On the other hand, when the possibility of dew condensation in the exhaust air passage 17 is low, or when the amount of dew condensation is small, a large amount of room air 6 can be exhausted to the outside from the exhaust outlet 9, so that ventilation is ensured. Can be done.

As described above, according to the heat exchange type ventilation device 1 according to the first embodiment, the following effects can be enjoyed.

(1) The heat exchange type ventilation device 1 includes the heat exchanging section 5 arranged in parallel with the daylighting section 4 at a position sandwiched between the indoor side daylighting section 14 and the outdoor side daylighting section 15. As a result, it is possible to increase the area where heat is exchanged and improve the heat exchange efficiency, as compared with the case where the heat exchange element is provided in the conventional window frame. Therefore, the heat exchange type ventilation device 1 can maintain a comfortable temperature in the room and improve comfort. Further, by disposing the heat exchanging section 5 in parallel with the daylighting section 4, the heat exchanging element conventionally buried in the window frame becomes unnecessary, and the window frame can be downsized. As a result, it is possible to provide the heat exchange type ventilation device 1 capable of improving comfort while reducing the size of the window frame.

(2) In the heat exchange type ventilation device 1, the exhaust air passage 17 is formed between the indoor side lighting part 14 and the heat transfer plate 16 of the heat exchange part 5, and the outdoor side lighting part 15 and the heat transfer plate 16 are connected. An air supply air passage 18 is formed between them. Thereby, the cross-sectional area of the air passage through which the indoor air 6 or the outdoor air 7 flows can be increased, and the pressure loss can be suppressed to be small. Therefore, driving of the exhaust blower 12 and the supply air blower 13 can be suppressed to be small, and energy saving operation and noise reduction of the blower (exhaust blower 12 and supply air blower 13) can be realized.

(3) Since the heat exchange type ventilation device 1 includes the heat exchange section 5 arranged in parallel with the daylighting section 4, the surface temperature of the heat transfer plate 16 of the heat exchange section 5 rises due to the radiant heat of sunlight (sunlight). The temperature of the outdoor air 7 flowing through the supply air passage 18 can be raised. As a result, it is possible to obtain the heat exchange type ventilation device 1 in which the occurrence of dew condensation on the surface of the heat transfer plate 16 in the exhaust air passage 17 is suppressed and the reduction in visibility is suppressed.

(4) Since the heat exchange type ventilation device 1 includes the heat exchange section 5 arranged in parallel with the daylighting section 4, when the temperature of the outdoor air 7 is low such as in winter, when the outdoor air 7 flows through the air supply air passage 18. It is heated by the radiant heat of sunlight (sunlight). As a result, it is possible to suppress a decrease in indoor temperature that occurs when the outdoor air 7 is introduced into the room. As a result, the heat exchange ventilator 1 can reduce the load of indoor heating for compensating for the decrease in indoor temperature due to the introduction of the outdoor air 7.

(5) The heat exchange type ventilation device 1 has, in the exhaust air duct 17, an inlet port 19 capable of introducing the indoor air 6 after heat exchange into the supply air duct 18, and an air duct communicating with the exhaust air outlet port 9. An air passage switching unit 20 for switching to an air passage communicating with 19. Accordingly, when there is a possibility that dew condensation may occur in the exhaust air passage 17, the air passage switching unit 20 is controlled so that the exhaust air passage 17 communicates with the introduction port 19, so that the air supply air passage 18 is provided. The indoor air 6 after heat exchange can be mixed from the inlet 19 with the outdoor air 7 flowing through. Therefore, the temperature of the outdoor air 7 in the air supply air passage 18 can be increased, and the temperature decrease on the surface of the heat transfer plate 16 in the exhaust air passage 17 can be suppressed, so that the occurrence of dew condensation in the heat exchange section 5 can be reduced.

(6) The heat exchange type ventilation device 1 is provided with the translucent conductive layer 22 that generates heat when the heat transfer plate 16 is energized. Therefore, the translucent conductive layer 22 formed on the heat transfer plate 16 generates heat, so that the surface of the heat transfer plate 16 is heated and the occurrence of dew condensation in the exhaust air passage 17 can be suppressed. Further, even when dew condensation occurs on the surface of the heat transfer plate 16 in the exhaust air passage 17, dew condensation water can be removed from the surface of the heat transfer plate 16. As a result, in the heat exchange type ventilation device 1, it is possible to suppress diffused reflection of light transmitted through the heat exchange part 5 (diffuse reflection of light caused by dew condensation water). As a result, when the temperature of the outdoor air 7 is low, such as in winter, it is possible to suppress a decrease in visibility due to dew condensation inside the heat exchange section 5 (the surface of the heat transfer plate 16 in the exhaust air passage 17). The heat exchange type ventilation device 1 can be used.

(7) The translucent conductive layer 22 is formed on the surface side of the heat transfer plate 16 on the exhaust air passage 17 side. For this reason, since the translucent conductive layer 22 generates heat in the exhaust air passage 17 where dew condensation is likely to occur, it is effective to reduce the visibility due to the dew condensation on the surface of the heat transfer plate 16 in the exhaust air passage 17. Can be suppressed.

(8) The heat exchange type ventilation device 1 is configured such that the controller 25 controls the energization of the translucent conductive layer 22. Therefore, when suppressing the reduction in visibility due to the occurrence of dew condensation on the surface of the heat transfer plate 16 in the exhaust air passage 17, the control unit 25 efficiently conducts electricity to the translucent conductive layer 22. Therefore, it can be realized with energy saving as compared with the case of energizing the translucent conductive layer 22 regardless of the occurrence of dew condensation.

(9) The outdoor side lighting part 15 is composed of a pair of second lighting plates 15b facing each other with the second hollow layer 15a interposed therebetween. For this reason, the outdoor daylighting section 15 can suppress heat transfer from the outdoor to the heat exchange section 5 (the outdoor air 7 flowing through the air supply air passage 18). That is, in the winter season, the temperature of the outdoor air 7 (the outdoor air 7 whose temperature has risen by exchanging heat with the indoor air 6) flowing through the air supply air passage 18 is equal to the outdoor air on the outdoor side of the outdoor daylighting section 15. Since the decrease is suppressed by 7, the temperature of the indoor air 6 flowing through the exhaust air passage 17 can be increased as a result. As a result, in combination with the above (5), the heat exchange type ventilation device 1 in which the occurrence of dew condensation on the surface of the heat transfer plate 16 in the exhaust air passage 17 is further suppressed and the reduction in visibility is further suppressed is provided. You can

On the other hand, in the summer, the temperature of the outdoor air 7 (the outdoor air 7 whose temperature has risen by exchanging heat with the indoor air 6) flowing through the air supply air passage 18 is equal to the outdoor air on the outdoor side of the outdoor daylighting section 15. Further increase by 7 is suppressed. Therefore, it is possible to suppress an increase in the indoor temperature that occurs when the outdoor air 7 is introduced into the room. As a result, the heat exchange type ventilation device 1 can reduce the load of the indoor cooling for compensating the increase in the indoor temperature due to the introduction of the outdoor air 7.

(10) In the heat exchange type ventilation device 1, an exhaust gas filter is installed at the exhaust gas inlet 8 and an air supply filter is installed at the air supply inlet 10. Therefore, it is possible to prevent solid matters such as dust in the indoor space and the outdoor space from flowing into the heat exchange section 5. As a result, solid matter is clogged inside the heat exchanging portion 5, and the solid matter serves as ventilation resistance to prevent the exhaust air volume and the air supply air volume from decreasing, and also to prevent the dirt adhering to the surface of the heat transfer plate 16. It is possible to prevent the deterioration of the daylighting function (or visibility) of the window.

Although the present invention has been described based on the embodiments, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention. It can be easily guessed. For example, in each embodiment, a part or a plurality of parts of the configuration of another embodiment is added to the embodiment or a part or a plurality of parts of the configuration of the embodiment is exchanged. Therefore, the embodiment may be modified and configured. Further, the numerical values given in the above-mentioned respective embodiments are examples, and it is naturally possible to adopt other numerical values.

In the present embodiment, the translucent conductive layer 22 is provided on the surface side of the heat transfer plate 16 on the exhaust air passage 17 side, but the configuration is not limited to this. For example, the translucent conductive layer 22 may be provided on the surface of the heat transfer plate 16 on the air supply air passage 18 side. With such a configuration as well, the heat transfer plate 16 is heated, so that the occurrence of dew condensation on the surface of the heat transfer plate 16 in the exhaust air passage 17 can be suppressed. Further, since the temperature of the outdoor air 7 flowing through the air supply air passage 18 can be raised by the heat generation of the translucent conductive layer 22, the occurrence of dew condensation on the surface of the heat transfer plate 16 in the exhaust air passage 17 is further increased. Can be suppressed.

In the present embodiment, the daylighting section 4 is configured to include the indoor side daylighting section 14 having the first hollow layer 14a and the outdoor side daylighting section 15 having the second hollow layer 15a, but the present invention is not limited to this. For example, the daylighting section 4 may be configured to include an indoor daylighting section 14 having no hollow layer (for example, only the single first daylighting plate 14b) and an outdoor side daylighting section 15 having a second hollow layer 15a. Good.

In contrast to the present embodiment, a hydrophilic protective layer may be provided on the surface of the heat transfer plate 16 on the exhaust air passage 17 side. Due to this hydrophilic protective layer, on the surface of the heat transfer plate 16 in the exhaust air passage 17, the dew condensation water generated on the surface of the heat transfer plate 16 does not become polka dots (water droplets), and the surface of the heat transfer plate 16 It becomes a thinly spread state. Thereby, the heat from the translucent conductive layer 22 is easily transferred to the condensed water, and the condensed water can be more effectively removed from the surface of the heat transfer plate 16.

Further, a hydrophilic protective layer may be provided not only on the surface of the heat transfer plate 16 but also on the surface of the indoor side lighting section 14 on the exhaust air passage 17 side. As a result, in the heat exchange type ventilation device 1, it is possible to suppress a decrease in visibility due to dew condensation on the surface of the indoor side lighting portion 14 in the exhaust air passage 17.

As the protective layer, for example, a silicon oxide layer in which particles having photocatalytic activity are dispersed may be used. Here, the particles having photocatalytic activity are particles of photocatalyst that generate hydrophilic groups (hydroxyl groups) by irradiation with light (for example, ultraviolet rays). As the photocatalyst, for example, titanium oxide, tungsten oxide or the like may be used. In addition, "having hydrophilicity" means a state in which a contact angle with water is at least about 10° or less.

In the present embodiment, the exhaust filter is attached to the exhaust inlet 8 (or the vicinity of the exhaust inlet 8) and the intake filter is attached to the supply air inlet 10 (or the vicinity of the supply air inlet 10). It is not limited to this. For example, since solid matter such as pollen or dust exists in the outdoor space more than in the indoor space, the air supply filter may be attached only to the air supply inlet 10 side. As a result, it is possible to prevent at least the inflow of the solid matter into the air supply air passage 18 (the decrease of the air supply air volume of the air supply air passage 18) in which the solid matter is more easily clogged than the exhaust air passage 17.

INDUSTRIAL APPLICABILITY The heat exchange type ventilation device according to the present invention is useful as a heat exchange type ventilation device that enables heat exchange between indoor air and outdoor air. It has an effect mainly when used in the windows of buildings.

1 Heat Exchange Ventilator 2 House Wall 3 Window Frame 3a Upper Side 3b Lower Side 3c Left Side 3d Right Side 4 Daylighting Section 5 Heat Exchange Section 6 Indoor Air 7 Outdoor Air 8 Exhaust Inlet 9 Exhaust Outlet 10 Inlet Inlet 11 Air Supply Outlet 12 Exhaust Air Blower 13 Air Supply Blower 14 Indoor Side Lighting Part 14a First Hollow Layer 14b First Lighting Plate 14c First Spacer Member 15 Outdoor Side Lighting Part 15a Second Hollow Layer 15b Second Lighting Plate 15c Second Spacer Member 16 Heat transfer plate 17 Exhaust air passage 18 Air supply air passage 19 Inlet 20 Air passage switching unit 22 Translucent conductive layer 23 Temperature/humidity sensor 24 Temperature sensor 25 Control unit 25a Input unit 25b Storage unit 25c Judgment unit 25d Output unit 101 Heat exchange type ventilation device 102 Window frame 103 Exhaust air inlet 104 Exhaust air outlet 105 Heat exchange element 106 Exhaust air blower 107 Air supply inlet 108 Air supply outlet 109 Air supply blower

Claims (3)

Window frame,
A lighting unit provided at a position surrounded by the window frame and having an indoor side lighting unit located on the indoor side and an outdoor side lighting unit located on the outdoor side,
Indoor air that is provided in parallel with the lighting unit at a position sandwiched between the indoor lighting unit and the outdoor lighting unit and that is taken in from the indoor side and exhausted to the outdoor side, and that takes in from the outdoor side and supplies to the indoor side And a heat exchange section that exchanges heat with the outdoor air,
The window frame is
An exhaust air inlet provided on the indoor side to take in the indoor air,
An exhaust outlet provided on the outside of the room for blowing out the indoor air,
An air supply inlet provided on the outside of the room to take in the outdoor air,
An air supply outlet provided on the indoor side to blow out the outdoor air,
An exhaust blower that blows the indoor air from the exhaust inlet to the exhaust outlet,
An air supply blower that blows the outdoor air from the air supply inlet to the air supply outlet,
The heat exchange section,
A light-transmitting heat transfer plate provided between the indoor side lighting section and the outdoor side lighting section,
An exhaust air passage provided between the indoor side lighting section and the heat transfer plate, which communicates the exhaust inlet and the exhaust outlet,
Provided between the heat transfer plate and the outdoor daylighting section, and having an air supply air passage communicating the air supply inlet and the air supply outlet,
The heat transfer plate performs heat exchange between the indoor air flowing through the exhaust air passage and the outdoor air flowing through the air supply air passage,
The exhaust air passage is
An inlet that can introduce the indoor air after heat exchange into the air supply air passage,
An air passage switching unit that switches an air passage communicating with the exhaust outlet to an air passage communicating with the inlet is formed,
The heat exchange ventilation device, wherein the air passage switching unit switches to an air passage communicating with the inlet when it is determined that dew condensation occurs in the exhaust air passage. The heat exchange ventilator according to claim 1, further comprising a translucent conductive layer formed on a surface of the heat transfer plate on the exhaust air passage side and generating heat when an electric current flows. The heat-exchanging ventilation device according to claim 1 or 2, wherein the outdoor daylighting section is composed of a pair of daylighting plates facing each other with a hollow layer in between.

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