JP6074651B2 - Total heat exchange ventilator - Google Patents

Description

  The present invention relates to a total heat exchanger type ventilation device that is installed mainly in an office building or factory and used for energy saving of a plurality of air conditioners.

  Conventionally, this type of total heat exchange type ventilator is integrated with an air conditioner and has a sensor for measuring the temperature of the room and the temperature of the outside air when the outside air is introduced, and measures the temperature inside and outside the room. Thus, an air conditioner that attempts to obtain an energy saving effect has been proposed. (For example, refer to Patent Document 1).

  Hereinafter, an example of the total heat exchange type ventilator will be described with reference to the drawings.

  About patent document 1, as shown in FIG. 5, in the air conditioner provided with the air conditioner 100 and the total heat exchanger 200 integrated with this air conditioner, it is preset at the start of the operation of the air conditioner 100. If the temperature difference between the set temperature and the room temperature is greater than or equal to the specified value, stop the total heat exchanger or reduce the air volume, and the air-conditioning priority operation will be performed, the rise of the room temperature will be faster, and ventilation will be performed Compared with the case, the air conditioning performance can be improved.

JP-A-10-274425

  In such a conventional total heat exchange type ventilator, the conditions of the room temperature and the indoor temperature set value are compared only at the start of the operation of the air conditioner, and the air conditioner priority operation is performed. And when the air conditioner has stopped, it had the subject that it cannot respond to an air-conditioning load increase.

  Therefore, the present invention solves the above-described conventional problems, and even when the total heat exchange type ventilator is stopped, the outdoor temperature and the indoor temperature are sampled and measured at regular intervals to obtain temperature information. Even if the heat exchange type ventilator is installed separately, operating the ventilator independently reduces the amount of outside air introduced, even when the air conditioner is not running, and has an energy saving effect on the air conditioner. The object is to provide a total heat exchange ventilator that can be provided.

In order to achieve this object, the present invention includes a control unit that controls switching of the damper, operation of the fan motor, and stop, and this control unit automatically operates after a certain period of time has elapsed since the main unit stopped. The main body is operated for a short time, the outdoor temperature provided in the main body, the difference between the outdoor temperature and the indoor temperature obtained by the means for detecting the indoor temperature is judged, and the indoor temperature in the summer > the outdoor temperature or the indoor temperature in the winter < In the case of outdoor temperature, the damper is switched to bypass ventilation, and the outdoor air is directly taken into the room, so that the load on the indoor air conditioner can be reduced, thereby achieving the intended purpose.

According to the present invention, also in this body during the stop, scheduled to outdoor temperature, the room temperature was sampled measured by determining the temperature difference to obtain outdoor temperature and indoor temperature information, a bypass ventilation without heat exchange It is possible to determine whether to perform an operation to reduce the load of the indoor air conditioner by the outside air, and as a result of the determination, it is possible to obtain an effect that the air conditioning load can be reduced by performing bypass ventilation.

The figure which shows the structure of the total heat exchanger type ventilation apparatus of Embodiment 1 of this invention. The figure which shows the control action of the bypass ventilation operation of the total heat exchanger type ventilation device The figure which shows the control action which controls the fan rotation speed of bypass ventilation operation of the total heat exchanger type ventilation device The figure which shows the structure of the total heat exchanger type ventilation apparatus of Embodiment 2 of this invention. The figure which shows the structure of the conventional total heat exchanger integrated air conditioning apparatus.

A total heat exchange ventilator according to the present invention includes a total heat exchange element for exchanging heat when ventilating indoor air and outdoor air, and an air supply fan motor for taking outdoor air indoors In the total heat exchange type ventilator having an exhaust fan motor for discharging indoor air to the outdoors, and a damper for switching bypass ventilation for directly taking in outside air without heat exchange ventilation and heat exchange, the switching of the damper, A control unit that controls the operation and stop of the fan motor is provided. This control unit automatically operates the main unit for a short time after a certain period of time has elapsed since the main unit is stopped, and the outdoor temperature and the indoor temperature provided in the main unit. of determining the temperature difference between the outdoor and indoor obtained information by the detection means, when the indoor temperature> outdoor temperature or in winter, indoor temperature <outdoor temperature in summer, switching the damper in the bypass ventilation For example, it has the structure that was possible to reduce the indoor air conditioner load by incorporating directly outside air into the room. Thereby, even when the main body is stopped, the outdoor temperature and the indoor temperature are sampled and measured regularly, and the temperature difference is determined by obtaining the outdoor temperature / indoor temperature information. Based on this determination, it is possible to determine whether to perform bypass ventilation without heat exchange and to reduce the load on the indoor air conditioner due to outside air, and as a result, it is possible to reduce the air conditioning load by performing bypass ventilation Play.

  In addition, when the control unit obtains information that the temperature difference between the outdoor temperature and the indoor temperature is equal to or greater than a predetermined temperature difference, the control unit increases the rotation speed of the supply fan motor and increases the rotation speed of the exhaust fan motor. It may be configured to reduce. As a result, by increasing the number of rotations of the supply fan motor and decreasing the number of rotations of the exhaust fan motor, it is possible to take in a larger amount of supply air than the amount of exhaust air. The effect that the utilized air-conditioning load reduction effect can be acquired is produced.

The control unit includes a CO ₂ sensor for detecting the CO ₂ concentration in the room, when smaller than the CO ₂ concentration to a predetermined increase the rotational speed of the air supply fan motor, rotation of the exhaust fan motor You may make it the structure of reducing a number. As a result, the CO ₂ sensor detects the CO ₂ concentration in the room, and if it is below the specified value, the necessary ventilation amount can be judged, the exhaust air volume can be reduced, and the supply air quantity can be increased. Therefore, there is an effect that the effect of reducing the air conditioning load using the outside air can be obtained in a short time while securing the necessary ventilation amount.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a diagram showing a configuration of a total heat exchange type ventilator according to the present embodiment.

The total heat exchange type ventilator 1 of the present embodiment is installed in the ceiling 10 of a room 11 of a building. In the main body, a total heat exchange element 4 for exchanging heat between indoor air and outdoor air, a supply fan motor 3 for taking outdoor air into the room, and exhausting indoor air to the outdoors The exhaust fan motor 2 is provided. The total heat exchange type ventilator 1 takes fresh outdoor air from an outdoor air inlet 24 through a duct from an outdoor air supply port (not shown). The dirty air in the room is sucked from the indoor exhaust port 25 and taken into the total heat exchanging ventilator 1 from the indoor air intake 21 through the duct (in some cases, the total heat is not passed through the duct. It is directly sucked into the indoor air intake 21 of the main body of the exchangeable ventilator 1). And when exhausting dirty air in the room, fresh air is taken in by exchanging the total heat of the indoor air whose temperature is adjusted by the air conditioner 7 and the total heat of the outdoor air that is the load of the air conditioner 7. However, the heat treatment load of the air conditioner 7 is reduced. The outdoor air after heat exchange is supplied to the room 11 from the indoor air supply port 22. The indoor air after the heat exchange is discharged to the outdoors from the outdoor exhaust port 23. On the other hand, the above-described air conditioner 7 is separately installed in the same ceiling 10 to adjust the indoor temperature. The air conditioner 7 consumes electric power in order to adjust the heat load generated indoors and the heat load of outside air taken in for ventilation to a target set temperature. The control unit 5 includes detection means 6 for obtaining information on the outdoor temperature and the indoor temperature of the air conditioner 7. In addition, a damper motor 14 that switches between the heat exchange ventilation damper 13 and the bypass ventilation damper 12 is provided at the indoor air intake 21 portion of the total heat exchange type ventilation device 1. Further, an air supply fan motor 3 and an exhaust fan motor 2 are provided in the main body. The controller 5 controls the damper motor 14, the air supply fan motor 3 and the exhaust fan motor 2 to operate, stop, and switch the speed of each fan motor between strong, medium, and weak.

  With the above configuration, the control unit 5 switches between the heat exchange ventilation A and the bypass ventilation B according to the output (outdoor temperature) of the outdoor temperature sensor 8 and the output (indoor temperature) of the indoor temperature sensor 9. That is, when performing the heat exchange ventilation A, the damper motor 14 is switched so that the bypass ventilation damper 12 is opened and the heat exchange ventilation damper 13 is closed. When the bypass ventilation B is performed, the damper motor 14 is switched so that the bypass ventilation damper 12 is closed and the heat exchange ventilation damper 13 is opened. Then, all the power consumption of the air conditioner 7 can be reduced by operating / stopping / switching the speed of the air supply fan motor 3 and the exhaust fan motor 2 and controlling the intake of outside air so as to be suitable for each case. The heat exchange type ventilator 1 is obtained.

  In the following, the outdoor temperature, the indoor temperature change and the damper, the operation of the air supply fan motor 3 and the exhaust fan motor 2 during cooling will be described with reference to FIG. The horizontal axis of the chart indicates time, and the vertical axis of the chart indicates, for example, the change in outdoor temperature and indoor temperature after the air conditioner is stopped, the position of the damper motor 14, the position of the damper motor 14, and the total heat exchange type ventilator 1. The rotation speeds of the supply fan motor 3 and the exhaust fan motor 2 are shown. Here, when the damper motor 14 is in the “bypass ventilation” position is a state in which the bypass ventilation damper 12 is closed and the heat exchange ventilation damper 13 is opened, that is, “bypass ventilation operation”. When the damper motor 14 is in the “heat exchange ventilation” position, the bypass ventilation damper 12 is opened and the heat exchange ventilation damper 13 is closed, that is, “heat exchange ventilation operation”.

  The time at the left end of the chart in FIG. 2 is the time when the total heat exchange ventilator 1 ends the heat exchange ventilation operation or the bypass ventilation operation, and the supply fan motor 3 and the exhaust fan motor 2 are stopped.

After the total heat exchange ventilator 1 has stopped the heat exchange ventilation operation or the bypass ventilation operation, when the preset time T1 is exceeded, the control unit 5 switches the damper motor 14 to the bypass ventilation position, The supply fan motor 3 and the exhaust fan motor 2 are operated until time T2 (bypass ventilation operation). Then, the information on the outdoor temperature and the indoor temperature is processed, and when the outdoor temperature is lower than the indoor temperature, that is, when the outdoor temperature <the indoor temperature, the bypass ventilation operation is continued as it is, and the outdoor air is introduced into the room. In this way, the indoor temperature can be brought close to the low outdoor temperature, and the bypass ventilation operation of the total heat exchanging ventilator 1 is stopped at the time t3 when the difference between the outdoor temperature and the indoor temperature disappears. By controlling as described above, it is possible to reduce the heat treatment load at the start of the operation of the air conditioner 7 and to obtain the effect that the power consumption of the air conditioner 7 can be reduced.

  FIG. 3 shows an operation in which the supply air volume is made larger than the exhaust air volume when the predetermined time T1 is set, compared to FIG. 2, that is, “the rotation speed of the supply fan motor 3”> “exhaust fan” The control unit 5 controls the rotational speed of each fan motor so that the rotational speed of the motor 2 is reached. By controlling in this way, it is possible to reduce the indoor temperature in a short time by taking in more outdoor air having a low temperature, and reducing the power consumption of the air conditioner 7 while taking in fresh outdoor air. Is obtained.

  The time T1 refers to the time when a predetermined time has elapsed since the heat exchange ventilation operation (or bypass ventilation operation) of the total heat exchange type ventilator 1 is completed. The time T2 indicates the time when a predetermined time has elapsed since the start of the bypass ventilation operation.

  In addition, the condition for stopping the bypass ventilation operation “the difference between the outdoor temperature and the room temperature has disappeared” refers to when the difference between the outdoor temperature and the room temperature is smaller than the predetermined temperature difference set in advance. Yes.

  In FIGS. 2 and 3, the period when the room is in a cooling load (summer period, intermediate period) has been described as an example. During the winter season when the room is subject to heating load, when processing the outdoor temperature and indoor temperature information, the bypass ventilation operation is performed when the outdoor temperature is higher than the indoor temperature, that is, when the outdoor temperature is higher than the indoor temperature. .

  In the present embodiment, the bypass ventilation damper 12 and the heat exchange ventilation damper 13 are operated by the damper motor 14, but a configuration may be adopted in which the bypass ventilation and the heat exchange ventilation are switched by one damper.

(Embodiment 2)
Next, a second embodiment will be described with reference to FIG. The controller 5 in the second embodiment includes a carbon dioxide sensor 15 that measures the indoor carbon dioxide concentration (CO ₂ concentration). The control unit 5 reduces the ventilation amount of the total heat exchange type ventilator 1 only when it is determined that the ventilation may be stopped, for example, the indoor carbon dioxide concentration measured by the carbon dioxide sensor 15 is 500 ppm or less. To control. In this way, it is possible to perform ventilation with an emphasis on the concentration of carbon dioxide in the room, and the effect of providing energy saving operation with an emphasis on the cleanliness of the air can be obtained.

  The total heat exchange type ventilator according to the present invention is useful for reliably reducing the power consumption of an air conditioner at the peak of air conditioning power in summer.

DESCRIPTION OF SYMBOLS 1 Total heat exchange type ventilator 2 Exhaust fan motor 3 Supply air fan motor 4 Total heat exchange element 5 Control part 6 Detection means 7 Air conditioner 8 Outdoor temperature sensor 9 Indoor temperature sensor 10 Back of ceiling 11 Indoor 12 Bypass ventilation damper 13 Heat exchange Ventilation damper 14 Damper motor 15 Carbon dioxide sensor

Claims (3)

A total heat exchange element for exchanging heat when ventilating indoor air and outdoor air;
An air supply fan motor for taking outdoor air indoors;
An exhaust fan motor for discharging indoor air to the outdoors;
In the total heat exchange type ventilator equipped with a damper that switches between heat exchange ventilation operation and bypass ventilation operation that directly takes in outside air without heat exchange,
A control unit that controls switching of the damper, operation of the fan motor, and stopping,
The control unit automatically operates the main body for a short time after a certain time has elapsed after the main body is stopped, and detects the outdoor temperature provided in the main body and the temperature difference between the outdoor and the indoor obtained by the indoor temperature detection means. If the indoor temperature> outdoor temperature in summer or the indoor temperature <outdoor temperature in winter , the damper is switched to the bypass ventilation operation , and the outside air is directly taken into the room, and then the difference between the outdoor temperature and the room temperature is It lost the bypass ventilation operation is stopped total heat exchange type ventilator characterized by Rukoto when. When the control unit obtains information that the temperature difference between the outdoor temperature and the room temperature is equal to or greater than a predetermined temperature difference, the control unit increases the rotation speed of the supply fan motor and decreases the rotation speed of the exhaust fan motor. The total heat exchange type ventilator according to claim 1, wherein Control unit includes a CO ₂ sensor for detecting the CO ₂ concentration in the room, when smaller than the CO ₂ concentration predetermined according to claim 1 which is characterized by reducing the rotational speed of the exhaust fan motor Total heat exchange type ventilator.

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