JP2017145997A - Ventilation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ventilation system capable of improving the environment of a perimeter portion and reducing air conditioning load.SOLUTION: A ventilation system includes: a double portion 1 having a double structure; a heat exchange ventilation device 10 having a heat-transfer element 13; and an opening/closing portion 33. The heat exchange ventilation device 10 includes an outdoor air intake port 5, an indoor side blowout port 11, an air supply air course 31, an indoor air intake port 12, an outdoor side blowout port 6, and an air exhaust air course 32. The double portion 1 includes: a first outdoor communication port 2d and a second outdoor communication port 2u for communicating an inner space and an outdoor side with each other; a first indoor communication port 7d for communicating the air exhaust air course 32 downstream of the heat-transfer element 13 and the inner space with each other with the indoor air intake port 12 not interposed therein; and a second indoor communication port 7u for communicating the air supply air course 31 upstream of the heat-transfer element 13 with the inner space 1c with each other with the outdoor air intake port 5 not interposed therein. The opening/closing portion 33 can switch opening/closing of the first outdoor communication port 2d, and the like.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a ventilation system installed on an outer wall of a building.

  Conventionally, in the vicinity of the outer skin of a building including a building, that is, in a region near a window called a perimeter unit, comfort may be impaired due to heat load caused by heat generated by external light irradiation. In particular, it is known that the heat load in the summer increases in the perimeter part compared to the part away from the outer skin of the building called the interior part, which is an impediment to energy saving in air conditioning.

  In order to solve this problem, there is a method of taking a double skin structure in which the outer skin of the building has a double structure. However, in order to make the outer skin part of the building have a double structure, it is a problem that the construction cost becomes higher in order to increase the number of walls covering the entire outer skin by one.

  As an improvement measure, an air flow window that focuses on a window that takes in external light and improves heat insulation by increasing the heat insulation by making the window double is patented. It is disclosed in Document 1.

Japanese Laid-Open Patent Publication No. 2008-2775

  In such a ventilation system that allows air to pass through the internal space of the outer skin portion of the double structure, there is a demand for further improving the environment of the perimeter portion and reducing the air conditioning load.

  This invention is made in view of the above, Comprising: It aims at obtaining the ventilation system which can aim at the improvement of the environment of a perimeter part, and reduction of an air-conditioning load.

  In order to solve the above-mentioned problems and achieve the object, the present invention provides a heat exchange ventilation that includes a double part provided with an internal space through which air can pass and a heat exchange element to perform heat exchange ventilation. An apparatus and an opening / closing part are provided. The heat exchange ventilator has an outdoor air intake for taking in outdoor air, an indoor air outlet for blowing the outdoor air taken in from the outdoor air intake, and an air supply connecting the outdoor air intake and the indoor air outlet. An air air passage, an indoor air intake for taking in indoor air, an outdoor air outlet for blowing out indoor air taken in from the indoor air intake, and an exhaust air passage connecting the indoor air intake and the outdoor air outlet. Are provided. In the double part, the first outdoor communication port and the second outdoor communication port that connect the internal space and the outdoor, and the exhaust air that is downstream of the heat exchange element without passing through the indoor air intake port A first indoor communication port in which the passage and the internal space are communicated with each other, and a second indoor chamber in which the air supply air passage on the upstream side of the heat exchange element and the internal space are communicated without passing through the outdoor air intake port. And a communication port. The opening and closing unit can switch between opening and closing of the first outdoor communication port, the second outdoor communication port, the first indoor communication port, the second indoor communication port, the outdoor air intake port, and the outdoor air outlet.

  According to the ventilation system concerning this invention, there exists an effect that the improvement of the environment of a perimeter part and reduction of an air-conditioning load can be aimed at.

The perspective view which shows schematic structure of the ventilation system concerning Embodiment 1 of this invention. The figure which simplifies and shows the ventilation system concerning Embodiment 1 It is a figure explaining operation | movement of the opening-and-closing part in Embodiment 1, Comprising: The figure which shows the state in winter It is a figure explaining operation | movement of the opening-and-closing part in Embodiment 1, Comprising: The figure which shows the state in summer It is a perspective view which shows schematic structure of the ventilation system concerning Embodiment 1, Comprising: The figure which shows the flow of air in winter It is a perspective view which shows schematic structure of the ventilation system concerning Embodiment 1, Comprising: The figure which shows the flow of the air in summer The figure which shows the example which allows air to pass inside space The figure which shows the example which allows air to pass inside space The figure which shows the example which allows air to pass inside space The figure which shows the hardware constitutions of the control part in Embodiment 1. The perspective view which shows schematic structure of the whole ventilation system concerning Embodiment 2 of this invention. The figure which simplifies and shows the ventilation system concerning Embodiment 2. The figure which shows the example of control by the control part in Embodiment 2. It is a perspective view which shows schematic structure of the ventilation system concerning Embodiment 2, Comprising: The figure which shows the example which allows room air to pass through interior space It is a perspective view which shows schematic structure of the ventilation system concerning Embodiment 2, Comprising: The figure which shows the example which lets outdoor air pass through interior space It is a perspective view which shows schematic structure of the ventilation system concerning Embodiment 2, Comprising: The figure which shows the example which used internal space as sealed space

  Below, a ventilation system concerning an embodiment of the invention is explained in detail based on a drawing. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
1 is a perspective view showing a schematic configuration of a ventilation system according to a first embodiment of the present invention. FIG. 2 is a simplified diagram of the ventilation system according to the first embodiment. In FIG. 1, the inside of a ventilation system is permeate | transmitted and shown.

  The ventilation system includes a heat exchange ventilator 10 and a double part 1. The heat exchange ventilator 10 and the double part 1 are arranged next to each other. The ventilation system is provided in the outer skin part of the building.

  First, the configuration of the duplex unit 1 will be described. The double portion 1 is a so-called double window in which two wall members that transmit visible light, for example, two glasses are arranged to face each other. One of the two wall members of the double part 1 is provided on the outdoor side, and the other is provided on the indoor side. In the following description, the wall member provided on the outdoor side is referred to as the outdoor wall 1a, and the wall member provided on the indoor side is referred to as the indoor wall 1b. The outdoor wall 1a and the indoor wall 1b are collectively referred to as a double window 30. In the double part 1, the space between the outdoor wall 1a and the indoor wall 1b is an internal space 1c through which air can pass.

  Further, the double part 1 is provided with a lower connection part 22 for connecting the internal space 1 c to the heat exchange ventilator 10 below the double window 30, and the internal space 1 c above the double window 30. An upper connection part 23 for connection with the heat exchange ventilator 10 is provided. A connection portion between the double window 30 and the lower connection portion 22 serves as a blowout port 3 that blows air into the internal space 1c. A connection portion between the double window 30 and the upper connection portion 23 serves as a suction port 4 for sucking air from the internal space 1c.

  The lower connection portion 22 is formed with a first outdoor communication port 2d that allows the internal space 1c to communicate with the outside. In addition, the lower connection portion 22 is formed with a first indoor communication port 7d that allows communication between an air passage provided inside the heat exchange ventilator 10 and the internal space 1c. In the ventilation system, since the heat exchange ventilator 10 and the double part 1 are adjacent to each other, it can be said that the first indoor communication port 7d is formed in the heat exchange ventilator 10. In FIG. 2, for ease of understanding, the heat exchange ventilator 10 and the double part 1 are shown apart from each other, so the first duct is connected as the duct connecting the heat exchange ventilator 10 and the double part 1. An indoor communication port 7d is shown. Actually, when the heat exchange ventilator 10 and the double part 1 are provided separately, a duct connecting the heat exchange ventilator 10 and the double part 1 may be provided as shown in FIG.

  The upper connection portion 23 is formed with a second outdoor communication port 2u that allows the internal space 1c to communicate with the outside. In addition, the upper connection portion 23 is formed with a second indoor communication port 7u that communicates an air passage provided inside the heat exchange ventilator 10 and the internal space 1c. In the ventilation system, since the heat exchange ventilator 10 and the double part 1 are adjacent to each other, it can be said that the second indoor communication port 7u is formed in the heat exchange ventilator 10. In FIG. 2, for ease of understanding, the heat exchange ventilator 10 and the double part 1 are shown apart from each other, so the second duct is connected as a duct connecting the heat exchange ventilator 10 and the double part 1. An indoor communication port 7u is shown. Actually, when the heat exchange ventilator 10 and the double part 1 are provided separately, a duct connecting the heat exchange ventilator 10 and the double part 1 may be provided as shown in FIG.

  Next, the configuration of the heat exchange ventilator 10 will be described. The casing of the heat exchanging ventilator 10 includes an outdoor air intake 5 that is connected to the outside without passing through the internal space 1 c of the double part 1 and takes in outdoor air, and outdoor air that is taken in from the outdoor air intake 5. And an air supply passage 31 connecting the outdoor air intake 5 and the indoor air outlet 11 are provided. Further, the casing of the heat exchange ventilator 10 was taken in from the indoor air intake 12 communicated to the outside without passing through the internal space 1c of the duplex portion 1 and the indoor air intake 12 for taking in indoor air. An outdoor air outlet 6 that blows out indoor air to the outside, and an exhaust air passage 32 that connects the indoor air intake 12 and the outdoor air outlet 6 are provided. The supply air passage 31 and the exhaust air passage 32 are formed by partitioning the inside of the housing by a partition wall 18.

  A heat exchange element 13 is provided at the intersection of the supply air passage 31 and the exhaust air passage 32. The supply air passage 31 is provided with an air supply blower 14 that generates a supply air flow from the outdoor air intake 5 toward the indoor outlet 11. The exhaust air passage 32 is provided with an exhaust blower 15 that generates an exhaust flow from the indoor air intake 12 toward the outdoor air outlet 6. The heat exchange element 13 performs heat exchange between the supply airflow and the exhaust flow. The heat exchange element 13 is formed by laminating a plurality of partition plates that partition between the air supply air flow and the exhaust air flow, and a plurality of interval holding plates that are provided between the partition plates and form a flow path through which the air supply air flow or the exhaust air flow can pass. Configured. In the first embodiment, in the heat exchange ventilator 10, the stacking direction of the partition plate and the spacing plate is the horizontal direction, more specifically, the direction from the room toward the outside. In the following description, the stacking direction of the partition plate and the spacing plate is also simply referred to as the stacking direction.

  A filter 16 is provided on the inflow surface of the supply airflow and the inflow surface of the exhaust flow in the heat exchange element 13. The filter 16 collects dust and insects contained in the supply airflow and the exhaust airflow before flowing into the heat exchange element 13. In order to maintain the inside of the heat exchange ventilator 10, an opening for maintenance is provided on the surface facing the indoor side, and a maintenance panel 17 is provided so as to cover the opening.

  Further, the heat exchange ventilator 10 includes a control unit 20 including a power supply for operating the supply air blower 14 and the exhaust air blower 15. In addition, the heat exchange ventilator 10 may include an operation unit that transmits an operation signal to the control unit 20.

  Next, the opening / closing part provided in the ventilation system will be described. As shown in FIG. 2, the first outdoor communication port 2d, the second outdoor communication port 2u, the outdoor air intake port 5, the outdoor air outlet 6, the first indoor communication port 7d, and the second indoor communication port 7u is provided with an opening / closing part 33 for switching between opening and closing. The opening / closing part 33 is, for example, a damper or a shutter that opens and closes the air path.

  FIG. 3 is a diagram for explaining the operation of the opening / closing part 33 and showing a state in winter. FIG. 4 is a diagram for explaining the operation of the opening / closing unit 33 and showing a state in summer. In the first embodiment, as shown in FIG. 3 and FIG. 4, the second outdoor communication port 2 u, the outdoor air intake port 5, and the second indoor communication port 7 u are opened and closed by a damper device that is one open / close unit. The structure switched by 8 is employ | adopted.

  The damper device 8 includes a power unit 8a, a plate unit 8b, a power transmission unit 8c, and a rail 8d. The plate portion 8b is supported by the rail 8d so as to be movable up and down. The plate portion 8b moves up and down to close the second outdoor communication port 2u and the outdoor air intake port 5 shown in FIG. 3, or the second indoor communication port 7u shown in FIG. It will be in one of the closed states. Thus, the structure which can switch to the state which closed the 2nd outdoor communication port 2u and the outdoor air intake 5 and the state which closed the 2nd indoor communication port 7u by the vertical movement of the board part 8b. Is realized by making the height at which the second outdoor communication port 2u and the outdoor air intake port 5 are formed different from the height at which the indoor communication port 7u is formed.

  The power unit 8a is, for example, a geared motor, and moves the plate unit 8b up and down via the power transmission unit 8c. When the control unit 20 determines that it is winter, the control unit 20 operates the power unit 8a to move the plate unit 8b upward. If the control unit 20 determines that it is summer, the control unit 20 operates the power unit 8a to move the plate unit 8b downward.

  In the first embodiment, the second outdoor communication port 2u and the outdoor air intake port 5 are formed at a higher position than the indoor communication port 7u, but this may be in a reverse positional relationship. If the positional relationship is reversed, the movement direction of the plate portion 8b may be reversed in summer and winter.

  Further, as shown in FIG. 1, the first outdoor communication port 2d, the outdoor air outlet 6 and the first indoor communication port 7d are similarly opened and closed by one damper device 8a.

  Each of the first outdoor communication port 2d, the second outdoor communication port 2u, the outdoor air intake port 5, the outdoor air outlet 6, the first indoor communication port 7d, and the second indoor communication port 7u is separately provided. An opening / closing part that operates in the above may be provided. For example, a motor is provided for each of the first outdoor communication port 2d, the second outdoor communication port 2u, the outdoor air inlet 5, the outdoor air outlet 6, the first indoor communication port 7d, and the second indoor communication port 7u. A damper may be provided, and each motor damper may be configured to be opened and closed by the control unit 20.

  Next, the operation of the ventilation system will be described. Since the ventilation system has different effects expected in summer and winter, it will be described separately for summer and winter operations.

  As shown in FIG. 2, in the upper part of the ventilation system, when it is determined by the control unit 20 that it is winter, the second outdoor communication port 2u and the outdoor air intake 5 are closed by the plate portion 8b. The indoor communication port 7u is opened. Further, below the ventilation system, the first indoor communication port 7d is closed by the plate portion 8b, and first, the outdoor communication port 2d and the outdoor air outlet 6 are opened.

  FIG. 5 is a perspective view illustrating a schematic configuration of the ventilation system according to the first embodiment and illustrates a flow of air in winter. In the state of the opening / closing part 33 in winter, the supply air blower 14 and the exhaust blower 15 operate, so that the outdoor air is supplied to the first outdoor communication port 2d, the lower connection part 22, the internal space 1c as shown in FIG. The upper connection portion 23, the second indoor communication port 7 u, the filter 16, the heat exchange element 13, the air supply blower 14, and the indoor side air outlet 11 are passed through in this order to be supplied to the room. The room air passes through the room air intake 12, the filter 16, the heat exchange element 13, the exhaust blower 15, and the outdoor air outlet 6 in this order, and is exhausted outside the room. The driving in the state shown in FIG. 5 is called driving in the winter mode.

  In such operation in the winter mode, the outdoor air passes through the internal space 1c of the double part 1 before being taken into the heat exchange ventilator 10. The temperature of the outdoor wall 1a and the indoor wall 1b of the double part 1 rises due to solar radiation. Therefore, outdoor air is warmed by taking heat away from the outdoor wall 1a and the indoor wall 1b while passing through the internal space 1c. That is, the outdoor air is preheated before being taken into the heat exchange ventilator 10. Therefore, the temperature of the air supplied from the indoor air outlet 11 is higher than the temperature of the air supplied without passing through the internal space 1c, so that the heating load in winter can be reduced. .

  FIG. 6 is a perspective view illustrating a schematic configuration of the ventilation system according to the first embodiment and illustrates a flow of air in summer. When the supply air blower 14 and the exhaust air blower 15 operate in the state of the opening / closing part 33 in the summer season, as shown in FIG. 6, the outdoor air is supplied from the outdoor air intake 5, the filter 16, the heat exchange element 13, the air supply The air passes through the blower 14 and the indoor outlet 11 in this order, and is supplied to the room. The indoor air is supplied from the indoor air inlet 12, the filter 16, the heat exchange element 13, the exhaust blower 15, the first indoor communication port 7d, the lower connection portion 22, the internal space 1c, the upper connection portion 23, and the second outdoor. It passes through the communication port 2u in this order and is exhausted outside the room. The driving in the state shown in FIG. 6 is called driving in summer mode.

  In such operation in the summer mode, the room air passes through the heat exchange ventilator 10 and then passes through the internal space 1c of the double part 1 and is exhausted. The temperature of the outdoor wall 1a and the indoor wall 1b of the double part 1 rises due to solar radiation. Therefore, the temperature of the outdoor wall 1a and the indoor wall 1b of the double part 1 is lowered by the indoor air passing through the internal space 1c. Therefore, the radiant heat from the outdoor wall 1a and the indoor wall 1b is reduced, and a local temperature rise in the perimeter unit can be suppressed. Thereby, the reduction of the air conditioning load in summer and the improvement of the comfort of the perimeter unit can be achieved.

  In general, the temperature of indoor air taken into a ventilation system from an air-conditioned room in summer is lower than that of outdoor air. Therefore, rather than allowing outdoor air to pass through the internal space 1c, the temperature of the outdoor wall 1a and the indoor wall 1b is lowered to further reduce the air-conditioning load in summer and further improve the comfort of the perimeter unit. Can be achieved.

  However, the temperature of the outdoor air may be lower than the temperature of the indoor air even in summer and at night. In that case, the outdoor wall 1a and the indoor wall 1b are cooled by using outdoor air, so that the air conditioning load can be more effectively reduced and the comfort of the perimeter unit can be improved. That is, even in the summer, when the temperature of the outdoor air is lower than the temperature of the indoor air, the air conditioning load can be more effectively reduced and the perimeter unit can be comfortably operated by operating in the winter mode shown in FIG. It is possible to improve the performance.

  Further, even in the winter, in the severe winter season or in a cold region, when the outdoor air is passed through the internal space 1c, the indoor wall 1b is excessively cooled, reaches the dew point of the indoor air, and dew condensation occurs on the surface on the indoor side of the indoor wall 1b. May occur (see FIG. 7). However, since the surface on the indoor side of the indoor wall 1b is a surface exposed to the room, it is easy to take a countermeasure against wiping.

  On the other hand, when indoor air is passed through the internal space 1c and returned to the room in winter, the dew point is reached in the internal space 1c and condensation occurs on the surface of the outdoor wall 1a on the side of the internal space 1c. There are cases (see FIG. 8). In this case, it is difficult to wipe off the condensation generated in the internal space 1c, and it is difficult to eliminate the condensation.

  Further, when condensation occurs on the surface of the indoor wall 1b on the indoor side in the winter (see FIG. 7), the room heated in the internal space 1c is switched to the operation in the summer mode shown in FIG. Air can be passed through to increase the temperature of the indoor wall 1b to eliminate condensation (see FIG. 9). In this way, even in winter, switching to operation in the summer mode as necessary enables operation in winter to preheat outdoor air even in cold regions, reducing the air conditioning load. Both elimination of condensation can be achieved.

  In order to automatically switch the driving state in winter, a dew condensation sensor that detects dew condensation on the surface of the indoor wall 1b on the indoor side and above the outlet 3 as shown in FIGS. 9b may be arranged. Condensation sensor 9b has various methods such as a method using a small amount of current when condensation is deposited on two separate electrodes, a method utilizing a change in light transmittance when condensation is deposited, etc. There are various methods, but any method can be used as long as it can detect the dew condensation in the target part and issue a signal. When condensation occurs, the control unit 20 controls the damper device 8 based on a signal issued from the condensation sensor 9b to switch from the winter driving state to the summer driving state. When the signal issued from the dew condensation sensor 9b is stopped, the control unit 20 controls the damper device 8 to switch from the summer driving state to the winter driving state.

  By installing and operating such a ventilation system side by side, for example, on the outer skin of a building, it is possible to reduce the heat load on the perimeter section. Further, since the heat exchanging ventilator 10 is installed below the ceiling, there is no need to work with a stepladder during maintenance like the heat exchanging ventilator installed in the ceiling. Therefore, the workability and safety of maintenance work can be improved. Moreover, since air can be directly sucked in or blown out from the outer skin portion, duct piping can be omitted. Thereby, the installation cost of a ventilation system can be reduced. Moreover, since the solar radiation to a room | chamber is interrupted | blocked by the heat exchange ventilation apparatus 10 installed in the outer skin, the heat load by solar radiation can be reduced. Thereby, reduction of an air-conditioning load can be aimed at.

  Note that the summer and winter determinations may be made automatically by the control unit 20. For example, the temperature sensor 9a is provided upstream of the heat exchange element 13 in the supply air passage of the heat exchange ventilator 10, and the temperature of the outdoor air is measured. If the measured outdoor air temperature is equal to or higher than a predetermined reference temperature, the control unit 20 determines that it is summer, and if it is lower than the reference temperature, the control unit 20 determines that it is winter and controls the opening / closing unit 33. May be. In addition, a signal indicating an operation state of an air conditioner (not shown) is received, and if the air conditioner is performing a cooling operation, the summer and the control unit 20 determine, and if performing a heating operation, the winter and the control unit 20 The opening / closing unit 33 may be controlled based on the determination.

  FIG. 10 is a diagram illustrating a hardware configuration of the control unit 20. The control unit 20 includes, for example, a CPU (Central Processing Unit) 20a and a memory 20b. In the control unit 20, by executing a program, the CPU 20a detects a condensation detection unit that detects the occurrence of condensation, a season determination unit that determines whether it is in the summer or winter, a switch control unit that controls the switching unit, an air supply It functions as a blower control unit that controls the operation of the blower 14 and the exhaust blower 15. In addition, a memory 20b such as a ROM (Read Only Memory) functions as a storage unit that stores a reference temperature serving as a reference for determining whether it is in the summer or winter. Further, the program executed by the CPU 20a may be stored in the memory 20b, or may be stored in another storage medium.

  In addition, a visual field can be ensured by using glass for the outdoor wall 1a and the indoor wall 1b of the double part 1. Alternatively, the outdoor wall 1a and the outdoor wall 1b may be provided with a special coating such as Low-E (Essitivity) glass coated with a metal film. By reducing the thermal load by coating, the environment of the perimeter can be improved.

  The blower outlet 3 may be formed with the entire lower surface of the double window 30 as an opening, or may be formed with a part of the lower surface of the double window 30 as an opening. Further, the suction port 4 may be formed with the entire upper surface of the double window 30 as an opening, or may be formed with a part of the upper surface of the double window 30 as an opening.

  The blowout port 3 and the suction port 4 may be provided with a member that causes pressure loss for rectification, for example, a rectification grid. Thereby, it can suppress that the bias which arises in the air which flows through the internal space of the double part 2 arises.

  What is necessary is just to provide the indoor side blower outlet 11 and the indoor air intake 12 of the heat exchange ventilator 10 in a desirable position according to the indoor condition. For example, when importance is attached to the exhaust heat effect of the perimeter part in summer, it is possible to exhaust high temperature air by providing the indoor air intake 12 at a position as high as possible. Moreover, the indoor air outlet 11 may be raised to some extent in consideration of the winter season when the feet are easily cooled. Further, the indoor air outlet 11 and the indoor air intake 12 are separated from each other as much as possible, and the air provided from the indoor air outlet 11 immediately becomes more indoor when the surfaces provided as shown in FIG. 1 are different. A short circuit that is sucked into the air intake 12 is less likely to occur, which is desirable. However, the indoor outlet 11 and the indoor air intake 12 may be formed on the same surface.

  The supply air blower 14 and the exhaust air blower 15 are not particularly limited with respect to the positional relationship with respect to the heat exchange element 13, and only need to be able to generate a supply air flow and an exhaust flow. For example, the air supply blower 14 and the exhaust blower 15 may be provided outside the housing of the heat exchange ventilator 10. Note that if the air supply blower 14 and the exhaust air blower 15 are provided on the downstream side of the heat exchange element 13, the air after passing through the filter 16 flows, so that dust adheres to the air supply blower 14 and the exhaust air blower 15. It becomes difficult to do. Further, by providing the air supply blower 14 and the exhaust blower 15 at a height close to the floor surface, the center of gravity of the heat exchange ventilator 10 is lowered and the stability is increased by the weight of the air supply blower 14 and the exhaust blower 15. In addition, it can be easily taken out from the housing, and maintenance can be improved.

Embodiment 2. FIG.
FIG. 11: is a perspective view which shows schematic structure of the whole ventilation system concerning Embodiment 2 of this invention. FIG. 12 is a simplified diagram of the ventilation system according to the second embodiment. In FIG. 11, the inside of a ventilation system is permeate | transmitted and shown. About the structure similar to the said Embodiment 1, the same code | symbol is attached | subjected and detailed description is abbreviate | omitted.

  In the second embodiment, the posture of the heat exchange element 13 is different from that in the first embodiment. Specifically, the heat exchanging element 13 is provided inside the heat exchanging ventilator 10 in a posture in which the stacking direction of the partition plate and the spacing plate is the vertical direction.

  In the ventilation system, the heat exchanging ventilator 10 is considered to be installed beside the double window 30. Therefore, in order to increase the room area in the room, the heat exchange ventilator 10 is configured to be thin in the thickness direction of the outer skin of the building. It is preferable. Here, in the heat exchange element 13, the length along the stacking direction of the partition plate and the spacing plate is generally larger than the length in the direction perpendicular to the stacking direction of the partition plate and the spacing plate. is there. Therefore, as in the ventilation system according to the second embodiment, the ventilation system can be thinned by providing the heat exchange element 13 so that the stacking direction of the partition plate and the spacing plate is the vertical direction. It becomes possible to further increase the indoor living room area.

  The heat exchange efficiencies of heat exchange elements exhibiting the same rectangular parallelepiped shape are approximately the same if the ratio of the volume of the heat exchange element to the amount of air to be heat exchanged is approximately the same. For example, when the heat exchange element 13 is arranged as in the ventilation system according to the first embodiment, the width of the heat exchange ventilator 10 is 600 mm, the thickness (depth) is 300 mm, and the height is a standard ceiling height. In this case, the maximum dimension of the heat exchange element 13 that can be mounted is 420 mm square × 300 mm stacked height. Here, the square dimension is the length of one side in a square shape when the heat exchange element 13 is viewed along the stacking direction.

  On the other hand, in the second embodiment, in order to make the heat exchange efficiency comparable to that of the first embodiment, the dimensions of the heat exchange element 13 are obtained as follows. That is, in order to ensure the volume of the heat exchange element 13 equivalent to that of the first embodiment, the maximum height of the heat exchange element 13 is considered in consideration of the height of the space for installing the air supply blower 14 and the exhaust blower 15. The thickness is 1700 mm, and the angular dimension is 177 mm. The width | variety and thickness (depth) of the heat exchange ventilation apparatus 10 calculated | required from the dimension of this heat exchange element 13 will be 250 mm. Therefore, with respect to the heat exchanging ventilator 10 according to the first embodiment, the width is 41% and the thickness is 83%, so that the width can be reduced in addition to the thinning. Actually, since it is necessary to consider the thickness of the material to be used and the shape of the air passage, the dimensions are not as described above, but the width and depth are reduced due to the difference in the arrangement direction of the heat exchange element 13. The superiority does not change.

  In the second embodiment, a bypass air passage 34 that directly connects the upstream side and the downstream side of the heat exchange element 13 in the air supply air passage is provided inside the heat exchange ventilator 10. In FIG. 12, a bypass air passage 34 is shown outside the housing of the heat exchange ventilator 10 for easy understanding.

  An air supply port 19 that can be opened and closed by an opening / closing unit (not shown) is provided inside the heat exchange ventilator 10. By opening the air supply port 19, outdoor air can be supplied indoors without passing through the heat exchange element 13. On the other hand, by closing the air supply port 19, the outdoor air can be supplied indoors through the heat exchange element 13. The operation of the opening / closing unit that opens and closes the air supply port 19 is controlled by the control unit 20. In the second embodiment, since the heat exchange element 13 is provided with the stacking direction being the vertical direction, as shown in FIG. 11, the side adjacent to the heat exchange element 13 along the stacking direction is more specific. Specifically, if the bypass air passage 34 is provided above the heat exchange element 13, the bypass air passage 34 can be provided without increasing the thickness of the heat exchange ventilator 10.

  In the ventilation system according to the second embodiment, by providing the bypass air passage 34 in which the air supply opening 19 that can be opened and closed is provided, in addition to the operation in the winter mode and the summer mode described in the first embodiment, Operation in interim mode is performed. In the intermediate period mode, the air supply port 19 is opened, so that the heat exchange element 13 is not passed through in the intermediate period such as spring or autumn, or in the time when heat exchange is not necessary, such as summer night and early winter daytime. It is possible to supply air without applying unnecessary pressure loss. Thus, by supplying air without passing through the heat exchange element 13, the load on the air supply blower 14 is reduced, and there is an effect that leads to a reduction in power consumption and an increase in ventilation.

  Further, the control unit 20 controls the opening and closing of the air supply port 19 and the control of the damper device 8 based on the information from the temperature sensor 9a, the dew condensation sensor 9b, and the air conditioner and the operation of the damper device 8 and the air supply port 19. By controlling the opening and closing, the ventilation state according to the season and situation is automatically selected. Thereby, it is possible to further reduce the air conditioning load and the power consumption.

  For example, the temperature sensor 9a can detect the temperature of indoor air (for example, upstream of the heat exchange element 13 in the exhaust air passage), and can detect the temperature of outdoor air (for example, the heat exchange element 13 in the air supply air passage). Of the internal space 1c of the double part 1 at a position where the temperature (in-window temperature) can be detected. Further, the dew condensation sensor 9b is disposed in the internal space 1c.

  In addition, when a signal indicating the cooling operation is received from the air conditioner, or when the outside air is equal to or higher than a certain temperature (reference temperature, for example, 20 ° C.), it is determined that it is summer. When it is determined that it is summer, the first outdoor communication port 2d, the second outdoor communication port 2u, and the like are opened and closed as shown in FIG. That is, in the summer, room air after passing through the heat exchange element 13 is allowed to pass through the internal space 1c. Further, when the outdoor temperature is higher than the indoor temperature, if the outdoor outdoor air is taken in as it is, the air conditioning load is large, so the air supply port 19 is closed and heat exchange ventilation is performed.

  Further, in such a case, there is sufficient solar radiation as in the daytime in summer, and the temperature of the internal space 1c is likely to rise, so the second outdoor communication port 2u is opened and the first outdoor communication port 2d is opened. close up. Moreover, the outdoor air intake 5 is opened and the outdoor air outlet 6 is closed. Further, the second indoor communication port 7u is closed and the first indoor communication port 7d is opened. By doing so, it is possible to flow the indoor air that has passed through the heat exchange element 13 into the internal space 1c of the double part 1 shown in FIG. 14 and to suppress an increase in the temperature of the indoor wall 1b in particular. Thereby, while being able to suppress the discomfort by the radiation from the indoor wall 1b, the air conditioning load can be reduced.

  On the other hand, even in summer, when the outdoor temperature is lower than the indoor temperature, it is possible to perform outdoor air cooling that takes in outdoor air as it is. Therefore, the air supply port 19 of the bypass air passage 34 is opened, and normal ventilation without heat exchange is performed. In such a case, since the temperature in the window is high, the exhaust from the living room can be sufficiently cooled, so the second outdoor communication port 2u is opened and the first outdoor communication port 2d is closed. Moreover, the outdoor air intake 5 is opened and the outdoor air outlet 6 is closed. Further, the second indoor communication port 7u is closed and the first indoor communication port 7d is opened. In this way, by flowing indoor air through the internal space 1c, suppressing uncomfortable feeling caused by radiation from the indoor wall 1b, and reducing the air conditioning load, and supplying outdoor air through the bypass air passage 34 Further, it is possible to further reduce the air load, reduce the power consumption by reducing the load of the supply air blower 14, and increase the ventilation amount.

  Further, when a signal indicating heating operation is received from the air conditioner, or when the outside air is below a certain temperature (reference temperature, for example, 20 ° C.), it is determined that it is an intermediate period or winter season. When it is determined that it is a winter season or an intermediate season, the opening / closing control is performed as shown in FIG.

  When it is determined that it is in the winter or intermediate period, and the temperature inside the window is higher than the room temperature, the outdoor air can be heated by the double part 1 to obtain a heating effect. Normal ventilation is performed, the second outdoor communication port 2u is closed, and the first outdoor communication port 2d is opened. In addition, the outdoor air intake 5 is closed and the outdoor air outlet 6 is opened. Further, the second indoor communication port 7u is opened, and the first indoor communication port 7d is closed. By doing in this way, as shown in FIG. 15, outdoor air can be supplied after it preheats through the internal space 1c. Thereby, reduction of an air-conditioning load can be aimed at.

  Further, when it is determined that it is winter or intermediate period, and the temperature inside the window is lower than the indoor temperature and higher than the outdoor temperature, the outdoor air is not only heated in the double section 1 but also exchanged with the indoor air. By performing the above, it becomes possible to further reduce the air conditioning load. Therefore, the air supply port 19 is closed to perform heat exchange ventilation, the second outdoor communication port 2u is closed, and the first outdoor communication port 2d is opened. In addition, the outdoor air intake 5 is closed and the outdoor air outlet 6 is opened. Further, the second indoor communication port 7u is opened, and the first indoor communication port 7d is closed. By doing in this way, since the air preheated by the double part 1 can be passed through the heat exchange element 13 and the air can be supplied after further raising the temperature, the air conditioning load can be further reduced. be able to.

  In addition, when the temperature of the outdoor air is too low, the temperature difference between the inner space side and the indoor side of the indoor wall 1b of the double part 1 increases, and condensation may occur on the indoor surface. This can be recognized by the reaction of the dew condensation sensor 9b attached to the indoor side of the indoor wall 1b. In this case, in order to relieve the temperature difference between the interior space 1c side of the indoor wall 1b and the indoor side, the air supply port 19 is closed, heat exchange ventilation is performed, the second outdoor communication port 2u is opened, 1 outdoor communication port 2d is closed. Moreover, the outdoor air intake 5 is opened and the outdoor air outlet 6 is closed. Further, the second indoor communication port 7u is closed and the first indoor communication port 7d is opened. By doing in this way, even in winter or an intermediate period, indoor air can be allowed to pass through the internal space 1c of the double part 1 and the temperature of the internal space 1c can be brought close to the indoor temperature. As a result, it is possible to eliminate condensation on the indoor side surface of the indoor wall 1b.

  Moreover, when indoor air is passed through the internal space 1c as described above, a temperature difference between the outdoor space 1a on the internal space 1c side and the outdoor side increases, and condensation occurs on the internal space 1c side of the outdoor wall 1a. There is a case. This can be recognized by the reaction of the dew condensation sensor 9b attached to the outdoor side of the outdoor wall 1a. In this case, if outdoor air is allowed to pass through the internal space 1c, condensation occurs on the indoor side, and if indoor air is allowed to pass, condensation occurs on the internal space 1c side. That is, condensation occurs even when outdoor air is passed through the internal space 1c or indoor air is passed.

  In such a case, the second outdoor communication port 2u is closed and the first outdoor communication port 2d is closed while the air supply port 19 is closed and heat exchange ventilation is performed. In addition, the outdoor air intake 5 is opened, and the outdoor air outlet 6 is opened. Further, the second indoor communication port 7u is closed, and the first indoor communication port 7d is closed. By doing in this way, as shown in FIG. 16, the internal space 1c of the double part 1 can be made into sealed space. Condensation that has occurred can be eliminated by allowing room air or outdoor air to pass through the internal space when the surrounding environmental conditions have eased, that is, when other operating conditions have been satisfied.

  Before the internal space 1c is closed, the second outdoor communication port 2u is closed for a short time, the first outdoor communication port 2d is opened, the outdoor air intake 5 is closed, and the outdoor air outlet 6 is opened. A step of opening the second indoor communication port 7u, closing the first indoor communication port 7d, and allowing outdoor air to pass through the internal space to eliminate condensation generated in the internal space 1c may be included.

  In this way, by adjusting the operation of the equipment by combining the temperature sensor 9a, the dew condensation sensor 9b, and the signal from the air conditioner, etc., appropriate ventilation suitable for indoor and outdoor conditions throughout the summer, winter and intermediate periods The system can be operated.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

  DESCRIPTION OF SYMBOLS 1 Duplex part, 1a Outdoor wall, 1b Indoor wall, 1c Internal space, 2d 1st outdoor communication port, 2u 2nd outdoor communication port, 3 Air outlet, 4 Suction port, 5 Outdoor air intake, 6 Outdoor side Air outlet, 7d First indoor communication port, 7u Second indoor communication port, 8 Damper device, 8a Power unit, 9a Temperature sensor, 9b Condensation sensor, 10 Heat exchange ventilator, 11 Indoor air outlet, 12 Indoor air Intake port, 13 Heat exchange element, 14 Supply air blower, 15 Exhaust air blower, 16 Filter, 18 Bulkhead, 19 Supply port, 20 Control part, 20a CPU, 20b Memory, 22 Lower connection part, 23 Upper connection part, 30 2 Heavy window, 31 supply air passage, 32 exhaust air passage, 33 opening / closing part, 34 bypass air passage.

Claims (10)

A double part provided with an internal space through which air can pass;
A heat exchange ventilator with a heat exchange element for performing heat exchange ventilation;
An opening and closing part,
In the heat exchange ventilator,
An outdoor air intake for taking in outdoor air;
An indoor outlet that blows outdoor air taken in from the outdoor air inlet;
A supply air passage connecting the outdoor air inlet and the indoor outlet;
An indoor air intake for taking in indoor air;
An outdoor air outlet that blows out indoor air taken in from the indoor air inlet;
An exhaust air passage connecting the indoor air intake and the outdoor air outlet is provided,
In the double part,
A first outdoor communication port and a second outdoor communication port communicating the internal space with the outdoor;
A first indoor communication port that communicates the exhaust air passage and the internal space downstream of the heat exchange element without passing through the indoor air intake port;
Without passing through the outdoor air intake, a second indoor communication port that communicates the supply air path that is upstream of the heat exchange element and the internal space;
Is provided,
The opening / closing portion includes a first outdoor communication port, a second outdoor communication port, the first indoor communication port, the second indoor communication port, the outdoor air intake port, and the outdoor air outlet port. A ventilation system that can be switched between open and closed. A control unit for controlling the opening and closing unit;
The controller is
Opening the first outdoor communication port, the second indoor communication port, and the outdoor air outlet, closing the second outdoor communication port, the first indoor communication port, and the outdoor air intake port, A mode for allowing outdoor air to pass through the internal space;
Closing the first outdoor communication port, the second indoor communication port, and the outdoor outlet, and opening the second outdoor communication port, the first indoor communication port, and the outdoor air intake port; The ventilation system according to claim 1, wherein the ventilation system is switched to a mode in which room air passes through the internal space.   The first outdoor communication port and the first indoor communication port are formed at positions lower than the second outdoor communication port and the second indoor communication port. The ventilation system according to claim 2, wherein outdoor air flows upward from below. It further includes a sensor that measures the outdoor temperature that is the temperature of the outdoor air,
The ventilation system according to claim 2, wherein the control unit controls the opening / closing unit based on the outdoor temperature. A sensor that measures the indoor temperature, which is the temperature of the indoor air,
A sensor that measures the temperature in the window that is the temperature of the internal space, and
The ventilation system according to claim 4, wherein the control unit controls the opening / closing unit based on the outdoor temperature, the indoor temperature, and the window temperature. A sensor for detecting a dew condensation state on the indoor side surface of the double part;
A sensor for detecting a dew condensation state in the internal space,
The ventilation system according to claim 5, wherein the control unit controls the opening / closing unit based on the outdoor temperature, the indoor temperature, the window temperature, and the dew condensation state.   The controller closes the first outdoor communication port, the second outdoor communication port, the first indoor communication port, and the second indoor communication port when dew condensation is detected in the internal space. The ventilation system according to claim 6.   The said control part judges that it is winter when it receives a heating signal from another apparatus, and judges that it is summer when it receives a cooling signal. A ventilation system according to claim 1. The heat exchange ventilator is provided with a bypass air passage connecting the upstream side and the downstream side of the heat exchange element in the air supply air passage,
The ventilation system according to claim 1, wherein an air supply opening that is opened and closed by the control of the control unit is formed in the bypass air passage. The heat exchange element is provided so that the stacking direction of the partition plates is the vertical direction,
The ventilation system according to claim 9, wherein the bypass air passage is provided at a position passing over the heat exchange element.

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