JP2014163551A - Heat exchange ventilator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchange ventilator which suppresses infiltration of outside air, and which, even in 24-hour ventilation, suppresses unnecessary stop of ventilation and enables a continuous operation in the 24-hour ventilation while solving failure caused by intake of highly humid outside air such as frost and the like.SOLUTION: A heat exchange ventilator 1 has: a humidity sensor disposed in an air supply air passage 9 which supplies outdoor air to the indoors and detecting outdoor humidity; a COsensor disposed in an exhaust air passage 8 which exhausts indoor air to the outdoors and detecting indoor COconcentration; and a control unit. When the outdoor humidity is equal to or greater than a humidity threshold value and the indoor COconcentration is equal to or less than a COconcentration threshold value, the control unit controls so that a blower 11 for air supply installed in the air supply air passage 9 and a blower 10 for exhaust installed in the exhaust air passage 8 perform a low air quantity operation where the air quantity is lower than the maximum air quantity.

Description

  The present invention relates to a heat exchange ventilator having a heat exchanger that exchanges heat between two fluids.

  In the conventional heat exchange ventilator, when fog is generated outside the room, when the outside air is taken into the room, the fog is also sucked in at the same time, and the condensation inside the heat exchange ventilator is caused by the suction of the fog. There was a problem that the spilled water leaked out of the plane. For this reason, for the purpose of removing water droplets contained in the mist, for example, the internal air passage of the outdoor hood that takes in outside air is folded in a complicated manner and the air collides with the air in the air passage, thereby removing the water droplets contained in the mist. The method of removing has been taken.

  Further, conventionally, a method has been studied in which the state of air, for example, humidity is detected by a sensor and the ventilation fan is controlled based on the detected humidity. For example, Japanese Patent Laid-Open No. 2004-228561 has “an outdoor humidity detector that detects outdoor humidity and a control unit that controls the operation of the ventilation unit, and a predetermined value stored in advance in the control unit and the outdoor humidity. An indoor automatic ventilation device is disclosed that compares the outside air humidity detected by a detector and activates the ventilation means when the outside air humidity falls below the predetermined value.

  Patent Document 2 states that “a sensor that detects indoor humidity, a sensor that detects outdoor humidity, and a humidity detected by these two humidity sensors in a main body having a sensible heat exchanger, an air supply fan, and an exhaust fan. The humidity determination means for comparing the indoor / outdoor humidity level and the indoor humidity with a reference value, and a drive for operating and stopping the air supply blower and the exhaust blower based on the humidity determination means An automatic air-conditioning ventilator with means is disclosed.

  Patent Document 3 states that “a ventilation fan provided in a room, a humidity sensor and a temperature sensor disposed in the vicinity of the ventilation fan in the room, and the ventilation fan are intermittently operated, and the indoor humidity caused by the intermittent operation is also described. A power control device that switches to continuous operation when the change is greater than or equal to a predetermined value, and switches to intermittent operation when the humidity change due to the continuous operation is smaller than the value or the indoor temperature change is greater than or equal to a predetermined value; An indoor automatic ventilation system is disclosed.

  Further, Patent Document 4 states that “an air supply passage that connects the outside of the building and the room through an outdoor air inlet and an indoor outlet, and an exhaust passage that connects the room and the outside of the building through an indoor air inlet and an outdoor air outlet. An air supply blower that forms a supply airflow from the outdoor suction port to the indoor outlet in the air supply passage; an exhaust fan that forms an exhaust flow from the indoor suction port to the outdoor outlet in the exhaust passage; an air supply passage and an exhaust passage; In a heat exchange ventilator having a heat exchanger for exchanging heat between airflows flowing through the air and a control unit for controlling the operation of the air supply fan and the exhaust air blower, the state of the air supply taken in from the outdoor suction port is detected An air supply state detector is provided in the air supply passage, and the control unit stops or intermittently operates the air supply blower when the outside air is not good based on the detection result of the air supply state detector. A ventilation device is disclosed.

Japanese Patent Laid-Open No. 08-014611 (Claim 1, FIG. 1) JP 05-280774 A (Claim 1, FIG. 3) Japanese Patent Laid-Open No. 05-311956 (Claim 1, FIG. 1) JP 2009-293880 A (Claim 1, FIG. 2)

  As described above, in the supply type ventilation fan, the fog is condensed inside the ventilation fan product due to the intrusion of the mist inside the ventilation fan, and water is generated. This water flows out of the machine and wets the surroundings of the product. Etc. had occurred. In particular, when the ventilation fan is a ceiling-embedded type, there is a problem because it wets the ceiling. For these, as described above, the mist can be removed by the method of dropping the mist with the outdoor hood member. However, this conventional technique causes the air to collide with air in the air path by bending the air path abruptly. Therefore, there is a problem that the pressure loss inside the outdoor hood increases.

  In addition, after installing the product, if it is found that the place of installation is a place where a lot of fog is generated, it is necessary to replace the outdoor hood with an outdoor hood that can remove the fog. It was difficult to replace this outdoor hood in places above the third floor of the building.

  Furthermore, in recent years, with the increasing needs for 24-hour ventilation, the possibility of supplying high-humidity air such as fog that occurs frequently in the early morning and late night is increasing in the early morning and late night. Intrusion of fog into the product has been a major issue.

  In order to solve this problem, in Patent Document 4, when the dew condensation sensor provided in the air supply passage detects an outside air humidity of a predetermined value or more, the air supply blower is stopped or intermittently operated. Thereby, this patent document 4 has suppressed the penetration | invasion of the mist to the inside of a ventilator.

  However, when the operation or stop of the air supply blower is determined based on the humidity of the outside air as in Patent Document 4, the humidity increase of the outside air is not only caused by the generation of high-humidity air such as fog, but also in the daytime. Since it occurs even in the case of rain, a problem has been pointed out that ventilation is stopped even in such a humidity increase due to rain during the daytime.

  Further, as in Patent Document 4, when the operation of the exhaust air blower is continued when the supply air blower is stopped or intermittently operated, the air supply blower is stopped or intermittently operated because the room has a negative pressure with respect to the outdoor. However, outside air will flow into the room from the air supply path. Thereby, the effect of suppressing the intrusion of outside air is reduced by stopping or intermittently operating the air supply blower.

  The present invention has been made against the background of the above problems, and suppresses the intrusion of outside air, and even in 24-hour ventilation, it eliminates the problems caused by the intake of high-humidity outside air such as mist and eliminates unnecessary ventilation. The heat exchange ventilator which suppresses a stop and enables the driving | operation continuation in 24-hour ventilation is provided.

The heat exchange ventilator according to the present invention includes an air supply air passage serving as a passage through which outdoor air sucked from an outdoor air inlet is supplied into the room from an indoor air outlet, and the outdoor air is supplied to the indoor air outlet. An air supply blower for supplying air into the room, an exhaust air passage serving as a passage through which the indoor air sucked from the indoor air inlet is exhausted from the outdoor air outlet, and the indoor air An exhaust fan for exhausting the air from the outlet to the outside, a heat exchanger for exchanging heat between the outdoor air passing through the supply air passage and the indoor air passing through the exhaust air passage, and detecting outdoor humidity and humidity sensor, a CO ₂ sensor for detecting the CO ₂ concentration in the room, together with the outdoor humidity detected to determine whether it is more humidity threshold value using the humidity sensor, with the CO ₂ sensor detected room CO ₂ concentration CO It determines whether a less density threshold, the and the outdoor humidity is higher the humidity threshold value, and wherein when the indoor CO ₂ concentration is less than the CO ₂ concentration threshold, the air supply blower and for the exhaust And a control unit that controls the blower to perform a low air flow operation that is lower than the maximum air flow.

According to the present invention, when the outdoor humidity is equal to or higher than the humidity threshold and the indoor CO ₂ concentration is equal to or lower than the CO ₂ concentration, both the air supply blower and the exhaust blower are operated at a low air flow rate lower than the maximum air flow rate. I do. For this reason, it is possible to reduce the intake amount of unnecessary outside air such as high-humidity outside air while ensuring the necessary minimum ventilation amount. In addition, since the exhaust air blower and the exhaust air fan perform low air volume operation, it is possible to reduce the negative pressure in the room, so high humidity outside air such as fog from the air supply air path can be reduced by the negative air pressure in the room. Can be prevented from entering the room. Furthermore, when the CO ₂ concentration is detected by the CO ₂ sensor and the CO ₂ concentration is high, the supply blower and the exhaust blower do not operate at a low air volume, so that the increase in the indoor CO ₂ concentration is suppressed. be able to.

In the heat exchange ventilation apparatus 1 which concerns on Embodiment 1, it is a perspective view which shows the state which opened the upper cover 3. FIG. It is sectional drawing at the time of seeing the heat exchange ventilation apparatus 1 which concerns on Embodiment 1 from the side surface in which the opening 13 was provided. 3 is a flowchart showing the operation of the heat exchange ventilator 1 according to the first embodiment. (A) is sectional drawing which shows the operation | movement of the damper apparatus 15 in case the heat exchange ventilation apparatus 1 which concerns on Embodiment 2 performs heat exchange ventilation, and the flow of air, (b) is the air supply air supply at the time of heat exchange ventilation It is a schematic diagram which shows the path | route of an exhaust flow. (A) is sectional drawing which shows the operation | movement of the damper apparatus 15 and the flow of air in case the heat exchange ventilation apparatus 1 which concerns on Embodiment 2 performs normal ventilation, (b) is the supply airflow and exhaust_gas | exhaustion at the time of normal ventilation It is a schematic diagram which shows the path | route of a flow.

  Hereinafter, embodiments of a heat exchange ventilator according to the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below. Moreover, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one. Further, in the following description, terms for indicating directions (for example, “up”, “down”, “right”, “left”, “front”, “back”, etc.) are used as appropriate for easy understanding. This is for explanation and these terms do not limit the present invention.

Embodiment 1 FIG.
FIG. 1 is a perspective view showing a state where the upper lid 3 is opened in the heat exchange ventilation apparatus 1 according to the first embodiment. Based on this FIG. 1, the heat exchange ventilator 1 is demonstrated. As shown in FIG. 1, the heat exchange ventilator 1 has a main body box 2 that forms an outer shell of the apparatus. One of the opposing side surfaces of the main body box 2 has an indoor suction port 4. The outdoor side air outlet 6 and the outdoor side air outlet 5 and the outdoor side air outlet 7 are provided on the other of the opposing side surfaces. The main body box 2 is installed such that one of the opposing side surfaces is directed to the indoor side and the other of the opposing side surfaces is directed to the outdoor side.

  In the main body box 2, the indoor air sucked from the indoor air inlet 4 is exhausted from the outdoor air outlet 7 to the outside, and the exhaust air passage 8 (the indoor air inlet 4 and the outdoor air outlet). 7), and the outdoor air sucked from the outdoor suction port 5 is supplied to the room from the indoor air outlet 6 (including the outdoor air inlet 5 and the indoor air outlet 6). ) And are formed. In the vicinity of the outdoor air outlet 7 in the exhaust air passage 8, there is provided an exhaust fan 10 composed of a blade 10a for forming an exhaust flow and an electric motor 10b for driving the blade 10a. Yes. The vane 10a is covered with one end of the vane casing 10c, and the other end of the vane casing 10c is attached to the outdoor air outlet 7 so that the air flowing inside the vane casing 10c is allowed to flow outside the outdoor air outlet. 7 is exhausted. Also in the air supply air passage 9, an air supply blower 11 including a blade 11 a for forming a supply air flow and an electric motor 11 b for driving the blade 11 a is provided in the vicinity of the indoor air outlet 6. Is provided. Also in this air supply blower 11, the blade 11a is covered with one end portion of the blade casing 11c, the other end portion of the blade casing 11c is attached to the indoor air outlet 6, and the air supply air flows into the indoor air outlet. 6 is supplied to the room.

  Further, the main body box 2 is provided with a heat exchanger 12 between the indoor inlet 4 and the indoor outlet 6 and the outdoor inlet 5 and the outdoor outlet 7, and this heat The exchanger 12 exchanges heat between the air supply flow and the exhaust flow. In addition, in the main body box 2, an opening 13 is provided on a side surface other than the side surface on which the indoor side inlet port 4 and the indoor side outlet port 6 and the outdoor side inlet port 5 and the outdoor side outlet port 7 are provided. The heat exchanger 12 can be inserted and removed from the opening 13. The opening 13 is closed by a maintenance cover 14 after the heat exchanger 12 is attached to the main body box 2.

  Next, the flow of air supply and exhaust in the heat exchange ventilator 1 will be described. FIG. 2 is a cross-sectional view of the heat exchange ventilator 1 as viewed from the side surface where the opening 13 is provided. As shown in FIGS. 1 and 2, the indoor air flowing through the exhaust air passage 8 is sucked from the indoor suction port 4 through a duct (not shown) as indicated by an arrow A, and the heat exchanger 12 is After passing, the air enters the blade casing 10c as indicated by an arrow B and is exhausted from the outdoor air outlet 7 to the outside by the exhaust fan 10 as indicated by an arrow C. Also, the outdoor air flowing through the supply air passage 9 is sucked from the outdoor suction port 5 through a duct (not shown) as indicated by an arrow D, and the heat exchanger 12 is crossed with the indoor air. Pass through. At that time, as described above, heat exchange is performed between the supply airflow and the exhaust flow, whereby the exhaust heat is recovered, so that the cooling / heating load can be reduced. After passing through the heat exchanger 12, the indoor air enters the vane casing 11c as indicated by an arrow E, and a duct (not shown) from the indoor outlet 6 as indicated by an arrow F by the air supply blower 11. The air is supplied to the room via

Further, in the exhaust air passage 8, for example, a CO ₂ sensor 22 is attached between the indoor suction port 4 and the heat exchanger 12, and this CO ₂ sensor 22 is used to control the indoor CO ₂ concentration. To detect. Further, a humidity sensor 21 is attached to the supply air passage 9 between, for example, the outdoor suction port 5 and the heat exchanger 12, and the humidity outside the room is detected using the humidity sensor 21. In order to drive the CO ₂ sensor 22 and the humidity sensor 21 and the exhaust fan 10 and the air supply fan 11 provided in the main body box 2, for example, the control unit 23 is provided on the lower surface of the main body box 2. Is provided. A remote controller 24 for operating the heat exchanging ventilator 1 is connected to the control unit 23. The control unit 23 incorporates a CPU, a non-volatile memory and the like (both not shown), and the control unit 23 is based on a control program stored in advance in response to a signal input from the remote controller 24. Then, the air supply fan 11 and the exhaust air fan 10 are operated.

  Next, operation | movement of the heat exchange ventilation apparatus 1 which concerns on this Embodiment 1 is demonstrated. FIG. 3 is a flowchart showing the operation of the heat exchange ventilator 1. As shown in FIG. 3, in a state where normal operation is performed, first, it is determined whether or not the outside air temperature is 0 ° C. or higher (step S1). At this time, when the outside air temperature is lower than 0 ° C., fog does not occur, so normal operation is continued (No in step S1). On the other hand, when the outside air temperature is 0 ° C. or higher, fog may be generated, and the process proceeds to the next step (Yes in step S1).

In the next step, it is determined whether or not the indoor CO ₂ concentration detected by the CO ₂ sensor 22 provided in the exhaust air passage 8 is equal to or less than a predetermined CO ₂ concentration threshold (step S2). This CO ₂ concentration threshold value can be set to 1000 ppm, which is a reference value determined by the Building Sanitation Law, for example. When the indoor CO ₂ concentration exceeds 1000 ppm, it is necessary to continue the normal operation and reduce the CO ₂ concentration in order to satisfy the standard value of 1000 ppm of the Building Sanitation Law (No in step S2). On the other hand, when the indoor CO ₂ concentration is 1000 ppm or less, the process proceeds to the next step (Yes in step S2), and the humidity of the outside air is determined.

  This outside air humidity is detected by a humidity sensor 21 provided in the air supply air passage 9, and it is determined whether or not the humidity of the detected outside air is a predetermined humidity threshold, for example, 80% RH or more. Determine (step S3). When the humidity of the outside air is less than 80% RH, it is difficult to think that fog is generated, so normal operation is continued (No in step S3), but when the humidity of the outside air is 80% RH or more. Since the occurrence of fog is considered, the process proceeds to the next step (Yes in step S3).

Thus, when the outside air temperature is 0 ° C. or higher (Yes in Step S1), the indoor CO ₂ concentration is 1000 ppm or lower (Yes in Step S2), and the outside air humidity is 80% RH or higher (Yes in Step S3), for example, The supply blower 11 is always changed to the minimum air flow operation (weak operation), and the exhaust blower 10 is always changed to the minimum air flow operation (weak operation) (step S4). Thereby, it is possible to suppress the high humidity outside air of 80% RH or more from entering the heat exchange ventilator 1 while maintaining the minimum indoor ventilation. Further, in the present embodiment, not only the supply air blower 11 is set to the minimum air flow operation but also the exhaust air blower 10 is set to the minimum air flow operation, so that the negative pressure in the room can be suppressed. For this reason, it is possible to suppress the high humidity outside air from entering the room from the supply air passage 9.

  And the operation | movement of step S1-step S4 is repeated at intervals of 5-10 minutes, for example until 10 hours passes (step S5). If 10 hours have not elapsed, the process returns to step S1, and steps S1 to S4 are sequentially performed (No in step S5). When these operations are performed continuously for 10 hours, the process proceeds to the next step (Yes in step S5).

  In the next step, both the air supply blower 11 and the exhaust blower 10 are stopped for 55 minutes, for example (step S6). This is because fog is continuously generated when the outside air temperature exceeds 0 ° C. (Yes in Step S1) and the outside air humidity satisfies 80% RH or more (Yes in Step S3) for more than 10 hours. This is because it is judged that In step S6, the supply air blower 11 and the exhaust air blower 10 are stopped to prevent the mist from entering the heat exchange ventilator 1 and the room.

  In step S6, after the supply air blower 11 and the exhaust air blower 10 are stopped for 55 minutes, the outdoor air is taken in by the supply air blower 11, and the humidity sensor 21 provided in the supply air passage 9 The sensing operation for operating the air supply blower 11 while measuring the humidity is performed for 5 minutes with the minimum air flow, and the exhaust air blower 10 is operated with the minimum air flow (step S7).

As in step S6 and step S7, the indoor CO ₂ detected by the CO ₂ sensor 22 provided in the exhaust air passage 8 while the supply fan 11 and the exhaust fan 10 are intermittently operated. When the concentration exceeds 1000 ppm, it does not satisfy the standard value of the Building Sanitation Law, that is, the CO ₂ concentration is 1000 ppm or less, so it is determined that ventilation is necessary, and the supply blower 11 and the exhaust blower 10 Returns to normal operation (No in step S2).

  Furthermore, when the humidity of the taken-in outside air is detected by the 5-minute sensing operation of the air supply blower 11 and the detection result is less than 80% RH, it is determined that the mist has settled, and the air supply The intermittent operation of the blower 11 for exhaust and the blower 10 for exhaust is terminated, and the normal operation is resumed (No in step S3).

On the other hand, even during the 5-minute sensing operation of the air supply blower 11, if the indoor CO ₂ concentration is 1000 ppm or less and the outside air humidity is 80% RH or more, the air supply blower 11 and the exhaust blower 10 are again turned on. Stop for 55 minutes (step S6). Thereafter, the sensing operation of the air supply fan 11 and the minimum air volume operation of the exhaust air fan 10 are performed again for 5 minutes (step S7), and during this time, the indoor CO ₂ concentration and the outside air humidity are determined as described above. In the present embodiment, the air supply fan 11 and the exhaust air fan 10 are stopped in step S6. However, the air supply fan 11 and the exhaust air fan 10 are not stopped, and these are further reduced in air volume. You may control to drive.

  In step S4 and step S7 described above, the exhaust blower 10 continues ventilation in the room by exhausting at the minimum air volume, but this exhaust air volume has a minimum required ventilation volume. It is preferable to reduce it to such an extent that it can be secured. The ventilation frequency is preferably 0.3 times / h or 0.5 times / h or more as defined in the Building Standard Law.

  In this embodiment, the sensing operation time for intermittent operation is set to 5 minutes, and the stop time (intermittent time) is set to 55 minutes. These times are arbitrarily set and changed according to the needs of the user. be able to. At that time, the sensing operation time is preferably selected from 1 to 30 minutes, and the stop time is preferably selected from 30 to 90 minutes.

  In the present embodiment, the humidity of the outside air is detected using the humidity sensor 21 provided in the supply air passage 9, but a temperature / humidity sensor may be used instead of the humidity sensor 21. Thereby, the detection of the temperature of the outside air in step S1 of FIG. 3 can be performed simultaneously with the detection of the humidity of the outside air.

Embodiment 2. FIG.
Next, the heat exchange ventilation apparatus 1 which concerns on Embodiment 2 is demonstrated. In the present embodiment, a configuration example is shown in which a damper device 15 serving as a path switching device for changing the path of the exhaust flow is provided in the middle of the exhaust air path 8 in the heat exchange ventilation apparatus 1 according to the first embodiment. In the second embodiment, differences from the first embodiment will be mainly described, and the same or corresponding components as those in FIGS. 1, 2, and 3 described above are denoted by the same reference numerals.

  FIG. 4A is a cross-sectional view showing the operation of the damper device 15 and the flow of air when the heat exchange ventilation apparatus 1 according to the second embodiment performs heat exchange ventilation, and FIG. 4B is this heat exchange. It is a schematic diagram which shows the path | route of the supply air flow and exhaust flow in the case of ventilating. 5A is a cross-sectional view showing the operation of the damper device 15 and the flow of air when the heat exchange ventilator 1 performs normal ventilation (ventilation that is not heat exchange ventilation), and FIG. 5B. These are the schematic diagrams which show the path | route of the supply air flow and exhaust flow at the time of normal ventilation. Based on these FIG.4 and FIG.5, the heat exchange ventilation apparatus 1 is demonstrated. As shown in FIG. 4A, when heat exchange is performed between the supply airflow and the exhaust flow, the damper device 15 is opened, and the first passage through which the room air passes through the heat exchanger 12 passes through the exhaust flow path. Let it be path 8a. As a result, the exhaust flow sucked from the indoor suction port 4 as indicated by the arrow A passes through the heat exchanger 12 as indicated by the arrow B, and the outdoor blower outlet as indicated by the arrow C by the exhaust fan 10. 7 is exhausted. For this reason, as shown in FIG. 4 (b), the supply airflow (arrows D, E, F) and the exhaust flow (arrows A, B, C) intersect at the portion of the heat exchanger 12, and heat is generated between the two. Exchange is performed.

  On the other hand, as shown in FIG. 5A, when normal ventilation is performed without exchanging heat between the supply airflow and the exhaust flow, the damper device 15 is closed and the indoor air is heated in the exhaust flow path. The second path 8b does not pass through the exchanger 12. As a result, the exhaust flow that has entered the heat exchanging ventilator 1 from the indoor suction port 4 as indicated by an arrow A is bypassed without passing through the heat exchanger 12 as indicated by an arrow B, and as indicated by an arrow C. Since air is exhausted from the outdoor air outlet 7 to the outside, heat exchange is performed between the supply airflow (arrows D, E, F) and the exhaust airflow (arrows A, B, C) as shown in FIG. Is not done.

  Next, operation | movement of the heat exchange ventilation apparatus 1 which concerns on this Embodiment 2 is demonstrated. As in the first embodiment, the present embodiment controls the operation and stop of the air supply blower 11 and the exhaust blower 10 according to the flowchart shown in FIG. As in step S7, when the air supply blower 11 and the exhaust blower 10 are intermittently operated, the damper device 15 is opened to perform heat exchange ventilation. In this way, when the air supply blower 11 and the exhaust blower 10 are intermittently operated, by switching to the heat exchange ventilation, the relatively dry air in the room flows into the heat exchanger 12, so that the heat exchanger 12 is Can be dried.

  As described above, the heat exchange ventilator according to the present invention is useful as a heat exchange ventilator installed in a building in an area with high humidity.

DESCRIPTION OF SYMBOLS 1 Heat exchange ventilator, 2 Main body box, 3 Top cover, 4 Indoor side inlet, 5 Outdoor side inlet, 6 Indoor side outlet, 7 Outdoor side outlet, 8 Exhaust air path, 8a 1st path, 8b 1st 2 routes, 9 air supply air passage, 10 exhaust fan, 10a blade, 10b motor, 10c blade casing, 11 air supply fan, 11a blade, 11b motor, 11c blade casing, 12 heat exchanger, 13 opening, 14 maintenance cover , 15 damper device, 21 humidity sensor, 22 CO ₂ sensor, 23 control unit, 24 remote control.

Claims (4)

An air supply air passage serving as a passage through which outdoor air sucked from the outdoor air inlet is supplied into the room from the indoor side outlet;
An air supply blower for supplying the outdoor air into the room from the indoor air outlet;
An exhaust air passage serving as a passage through which the indoor air sucked from the indoor suction port is exhausted from the outdoor air outlet to the outside;
An exhaust fan for exhausting the indoor air from the outdoor outlet to the outside;
A heat exchanger for exchanging heat between the outdoor air passing through the supply air passage and the indoor air passing through the exhaust air passage;
A humidity sensor for detecting outdoor humidity;
A CO ₂ sensor for detecting the indoor CO ₂ concentration;
It is determined whether the outdoor humidity detected using the humidity sensor is equal to or higher than a humidity threshold, and whether the indoor CO ₂ concentration detected using the CO ₂ sensor is equal to or lower than a CO ₂ concentration threshold. And when the outdoor humidity is equal to or higher than the humidity threshold and the indoor CO ₂ concentration is equal to or lower than the CO ₂ concentration threshold, the supply blower and the exhaust blower are lower than the maximum air flow. A heat exchanging ventilator, comprising: a control unit that controls the air volume operation. A path switching device that switches a path in the exhaust air passage through which the room air flows to a first path through which the room air passes through the heat exchanger, or a second path through which the room air does not pass through the heat exchanger. Have
The control unit controls the path switching device so that a path through which the indoor air flows becomes the first path when the outdoor humidity detected using the humidity sensor is equal to or higher than a second humidity threshold. The heat exchange ventilator according to claim 1. When the low air flow operation of the air supply blower and the exhaust air blower is continuously performed for a predetermined time, the control unit is configured such that the air supply blower and the exhaust air blower are more than the low air flow operation. The air supply fan and the exhaust fan are controlled to stop, and then the air supply fan and the exhaust fan return to the low air flow operation. The heat exchange ventilator according to claim 1 or 2, wherein When the indoor CO ₂ concentration exceeds a _second CO ₂ concentration threshold while the air supply blower and the exhaust air blower are performing the low air flow operation, the control unit, when the indoor CO ₂ concentration exceeds a _second CO ₂ concentration threshold, The heat exchange ventilator according to any one of claims 1 to 3, wherein the low air volume operation of the exhaust fan is canceled.

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