JP2586878B2 - Ventilation control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ventilation control device for efficiently ventilating indoor air.

[0002]

2. Description of the Related Art When a room is wide, ventilation of the room is performed by an exhaust fan for exhausting indoor air to the outside and an air supply fan for supplying outdoor air to the room. The exhaust fan and the air supply fan are operated so that the amount and the air supply amount of the air by the air supply fan are always substantially balanced.

[0003] Actually, the amount of air supplied by the air supply fan slightly exceeds the amount of air exhausted by the exhaust fan, thereby increasing the air pressure in the room and making it difficult for outdoor dust and dirt to enter the room.

[0004]

By the way, indoor ventilation is often suppressed appropriately. This is because indoor ventilation and air conditioning are closely related. For example,
When the outdoor temperature is far from the proper indoor temperature, the indoor temperature tends to fluctuate due to ventilation, so that the energy consumed by cooling and heating is increased and the cost is increased. For this reason, ventilation is suppressed.

[0005] However, if the ventilation is suppressed, the original purpose of the ventilation, that is, the purification of indoor air cannot be achieved, so that it is not sufficient to suppress the ventilation alone.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a ventilation control device capable of reducing energy consumption by cooling and heating and positively purifying indoor air.

[0007]

In order to solve the above-mentioned problems, a ventilation control device according to the present invention comprises a ventilating means for ventilating a room, an outdoor temperature detecting means for detecting an outdoor temperature, and a room for detecting an indoor temperature. The temperature detection unit compares the absolute value of the difference between the outdoor temperature detected by the outdoor temperature detection unit and a predetermined reference temperature, and the absolute value of the difference between the indoor temperature and the reference temperature detected by the indoor temperature detection unit. If the absolute value of the difference between the outdoor temperature and the reference temperature is smaller, a control means is provided for controlling the ventilation means to increase the amount of air supplied from outside to the room.

Further, the apparatus further comprises humidity detecting means for detecting outdoor humidity, wherein the control means has an absolute value of a difference between the outdoor temperature and the reference temperature smaller than an absolute value of a difference between the indoor temperature and the reference temperature, and When the humidity detected by the humidity detecting means is equal to or less than a predetermined threshold, controlling the ventilation means,
The amount of air supplied from the outdoors to the indoors may be increased.

[0009]

According to the present invention, the control means controls the absolute value of the difference between the outdoor temperature and the reference temperature detected by the outdoor temperature detection means, and the absolute value of the difference between the indoor temperature and the reference temperature detected by the indoor temperature detection means. If the absolute value of the difference between the outdoor temperature and the reference temperature is smaller, the ventilation means is controlled to increase the amount of air supplied from outside to the room.
That is, if the outdoor temperature is closer to the reference temperature than the indoor temperature, the amount of air supplied from the outside to the room increases, and the air purification is actively performed. As a result, the indoor temperature gradually approaches the reference temperature, so that the energy consumption for cooling and heating can be reduced.

When the apparatus further comprises humidity detecting means,
In addition to saying that the outdoor temperature is closer to the reference temperature than the indoor temperature, if the humidity detected by the humidity detecting means is not less than the threshold value, the amount of air supplied from the outdoors to the room is not increased. .

[0011]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 shows an embodiment of a ventilation control device according to the present invention. Here, ventilation of the room is performed by the exhaust fan 1 and the air supply fan 2. The exhaust fan 1
The indoor air is exhausted outside through the heat exchanger 3. The air supply fan 2 supplies outdoor air to the room through the heat exchanger 3. The heat exchanger 3 includes a path for air exhausted from indoors to the outdoors and a path for air supplied from indoors to the indoors. The heat exchanger 3 conducts heat between the two paths to supply the indoors from the outdoor. Bring the temperature of the air to be approached to room temperature.

Each of the driver circuits 4 and 5 outputs a rotational speed command signal in accordance with the level of the input signal. Can be Each of the inverters 6 and 7 outputs an AC signal having a frequency indicated by the rotation speed command signal when the rotation speed command signal is input. The AC signals of these inverters 6 and 7 are applied to the motor of the exhaust fan 1 and the motor of the air supply fan 2. As a result, the motor of the exhaust fan 1 rotates at a rotation speed according to the rotation speed command signal of the driver circuit 4, and the motor of the air supply fan 2 rotates at a rotation speed according to the rotation speed command signal of the driver circuit 5.

Indicators 8 and 9 attached to these inverters 6 and 7 indicate the number of rotations of the motor of the exhaust fan 1 and the number of rotations of the motor of the air supply fan 2.

The smoke sensors 11-1 to 11-n are arranged at various places in the room, detect smoke in the air at these places, and output a signal of a level corresponding to the concentration of the smoke. I do. That is, each of the smoke sensors 11-1 to 11-n detects the degree of air pollution and outputs a signal indicating the degree of air pollution.

The signals output from the smoke sensors 11-1 to 11-n are applied to the maximum value selection circuit 13 via the buffers 12-1 to 12-n. When the signals from the smoke sensors 11-1 to 11-n are input, the maximum value selection circuit 13 selects the maximum level signal from these signals, and outputs the maximum level signal. This maximum level signal is the maximum level signal among the output signals of the smoke sensors 11-1 to 11-n, and therefore, the degree of the air pollution at one place in the room where the air is most polluted. Is shown.

This maximum level signal is supplied to the driver circuit 4
And to the level adjuster 14. When the driver circuit 4 receives this maximum level signal, it applies a rotation speed command signal to the inverter 6 according to the level of the signal as described above. The inverter 6
An AC signal having a frequency indicated by the rotation speed command signal is applied to the motor of the exhaust fan 1. The motor of the exhaust fan 1 rotates at a rotation speed according to the rotation speed command signal.

Accordingly, the rotation speed of the motor of the exhaust fan 1 is determined according to the degree of contamination of the air which is most severely polluted, and the amount of air exhausted by the exhaust fan 1 is determined. In other words, if the air is not too polluted, the amount of air exhausted from indoors to outdoors will decrease,
If the air is heavily polluted, the amount of air exhausted will be large. As a result, useless ventilation and insufficient ventilation are prevented, and energy consumption by cooling and heating is also reduced.

When the maximum level signal is input, the level adjuster 14 attenuates the level of this signal to, for example, 70%, and switches the attenuated signal to a changeover switch 15.
To the driver circuit 5 via. The driver circuit 5
A rotation speed command signal is applied to the inverter 7 according to the level of the attenuated signal. The inverter 7 applies an AC signal having a frequency indicated by the rotation speed command signal to the motor of the air supply fan 2. The motor of the air supply fan 2 rotates at a rotation speed according to the rotation speed command signal.

Here, the rotation speed command signal to the motor of the air supply fan 2 corresponds to the level of the signal obtained by attenuating the previous maximum level signal by 70%. Therefore, the rotation speed indicated by the rotation speed command signal is 70% of the rotation speed of the motor of the exhaust fan 1, and the motor of the air supply fan 2 rotates at 70% of the rotation speed of the motor of the exhaust fan 1. It will be.

The reason why the rotation speed of the motor of the supply fan 2 is set to 70% of the rotation speed of the motor of the exhaust fan 1 is that the capability of the exhaust fan 1 and the capability of the supply fan 2 are different from each other. This is because the capacity of the exhaust fan 1 is only 70% of the capacity of the air supply fan 2.
In this case, in order to substantially balance the amount of air exhausted indoors to the outdoors and the amount of air supplied indoors from the outdoors, the number of rotations of the motor of the air supply fan 2 is set to It must be set to 70% of the number, and this setting is performed by the level adjuster 14.

As a result, the amount of exhausted air and the amount of supplied air are substantially balanced, and ventilation is performed in this state.
This substantially balanced state is referred to as a “first ventilation mode”.

In the first ventilation mode, however, the amount of air supplied is increased in order to increase the air pressure in the room and to prevent dust and dirt from entering the room from the outside as described above. Slightly higher.

FIG. 2 shows the characteristics of the first ventilation mode. In this graph, the horizontal axis represents the degree of air pollution, and the vertical axis represents the rotation speed of the motor of the exhaust fan 1 and the rotation speed of the motor of the air supply fan 2 as a ratio to the maximum rotation speed. As is clear from this graph, the rotation speed of the motor of the exhaust fan 1 increases as the air pollution becomes severe, and reaches the maximum rotation speed.

The rotation speed of the motor of the air supply fan 2 is
It is always 70% of the rotation speed of the motor of the exhaust fan 1. As a result, the amount of exhausted air and the amount of supplied air are substantially balanced.

The signal attenuation rate by the level adjuster 14 is set in advance by adjusting the volume 14a. In addition, the display 16 indicates the degree of contamination of the air that is most severely contaminated.

On the other hand, an outdoor temperature sensor 17, an indoor temperature sensor 18, and a humidity sensor 19 are provided, and detection outputs of these sensors are applied to the control circuit 24 via the buffers 21, 22, and 23.

Outdoor temperature sensor 17 and indoor temperature sensor 18
, A sensor using a thermistor or a thermocouple is applied. The outdoor temperature sensor 17 is installed outdoors and detects outdoor temperature. The indoor temperature sensor 18 is installed indoors and detects the indoor temperature.

The humidity sensor 19 is, for example, a pair of comb-shaped electrodes arranged on an alumina substrate, and a polymeric moisture-sensitive agent is applied between these comb-shaped electrodes. The humidity is detected based on the capacitance of the humidity. The humidity sensor 19 is installed outdoors and detects outdoor humidity.

Each of the indicators 25, 26, and 27 includes an outdoor temperature detected by the outdoor temperature sensor 17, an indoor temperature detected by the indoor temperature sensor 18, and a humidity sensor 1.
9 displays the humidity detected.

The control circuit 24 has two lamps 28, 2
9 and four volumes 31, 32, 33, 34 are connected.

The two volumes 31, 32 are for setting an appropriate temperature range as an outdoor temperature.
By adjusting the volume 31, to specify the minimum temperature t ₁₁ a proper temperature range, by adjusting the volume 32, you can specify the maximum temperature t ₂₂ a proper temperature range.

Further, volume 33 is for designating the most preferred reference temperature t _s. Furthermore, the volume 34 is used for designating a threshold h ₁ for humidity.

Now, with such a configuration, the control circuit 24 performs the following ventilation control.

First, assuming that the outdoor temperature detected by the outdoor temperature sensor 17 is T ₁ , the control circuit 24 determines the outdoor temperature T ₁ , the lower limit temperature t ₁₁ and the upper limit temperature t ₂₂ specified by the respective volumes 31 and 32. And the outdoor temperature T
It determines whether ₁ is in the proper temperature range t ₁₁ ~t _22.

At the same time, assuming that the humidity detected by the humidity sensor 19 is H, the control circuit 24
Is compared with the threshold value h ₁ for the humidity designated by the volume 34 to determine whether or not the outdoor humidity H is lower than the threshold value h ₁ .

The control circuit 24 determines whether at least one of them is “No”
Is determined, the first ventilation mode, that is, normal ventilation is continued. At this time, the control circuit 24
Is displayed to indicate that the first ventilation mode is being performed.

In the first ventilation mode, as described above, the number of rotations of the motor of the exhaust fan 1 is determined according to the degree of contamination of the air, and the number of rotations of the motor of the air supply fan 2 is adjusted. 1 set to 70% of the number of revolutions of the motor, whereby the amount of air exhausted outdoors,
Approximately balance the amount of air supplied to the room.

When the control circuit 24 determines that the outdoor temperature T ₁ falls within the appropriate temperature range t _{11 to} t ₂₂ and that the outdoor humidity H is lower than the threshold h ₁ , the control circuit 24 switches the first ventilation mode. Interrupt and transfer to the second ventilation mode. At this time, the control circuit 24 turns on the lamp 29, displays that the first ventilation mode has been interrupted and another ventilation mode has been entered.

In order to execute the second ventilation mode, the control circuit 24 switches the movable section 15a of the changeover switch 15 from the contact 15b to the contact 15c. Thus, the level adjuster 14 and the driver circuit 5 are disconnected, and the driver circuit 5 is connected to the control circuit 24.

However, since the connection between the maximum value selection circuit 13 and the driver circuit 4 remains connected, there is no change in the point that the rotation speed of the motor of the exhaust fan 1 is determined according to the degree of air pollution.

The control circuit 24 includes the control circuit 24
Reference data corresponding to the graph of FIG. 3 which has been previously stored in the built-in memory to determine the number of revolutions of the air supply fan 2 motor corresponding to the outdoor temperature T _1.

In the graph of FIG. 3, the horizontal axis represents the outdoor temperature T ₁ , and the vertical axis represents the number of rotations of the motor of the air supply fan 2 relative to the maximum number of rotations. According to the data of the graph, the outdoor temperature T ₁ is a proper temperature range t ₁₁ ~
when entering the t _22, the rotational speed of the air supply fan 2 motor 70
It is indicated in the range of ~ 90%.

Here, the outdoor temperature T ₁ is within an appropriate temperature range t.
₁₁ because Once in ~t ₂₂ has already been determined, the control circuit 2
4 refers to the data corresponding to the graph of FIG. 3, as the number of revolutions of the air supply fan 2 motor corresponding to the outdoor temperature T _1, and thus determining the rotational speed to fall within the scope of 70 to 90 percent. Then, the control circuit 24 applies a signal of a level corresponding to the rotation speed to the driver circuit 5 via the changeover switch 15. In response, the driver circuit 5
The inverter 7 applies a rotation speed command signal to the inverter 7, and the inverter 7 applies an AC signal to the motor of the air supply fan 2. Thereby, the motor of the air supply fan 2 rotates at a rotation speed of 70 to 90% of the maximum rotation speed.

At this time, even if the exhaust fan 1 rotates at the maximum rotation speed, the amount of air supplied into the room by the air supply fan 2 exceeds the amount of air exhausted to the outside by the exhaust fan 1. The balance of the amount of air is broken.

Therefore, in the second ventilation mode,
The amount of air supplied from the outdoors to the room is greater than in the first ventilation mode. This actively purifies the indoor air. Moreover, since the outdoor temperatures T ₁ is in the proper temperature range t ₁₁ ~t _22, it is possible to maintain proper indoor temperature, energy consumed by air conditioning is not increased.

In the second ventilation mode, the outdoor temperature T
₁ or outside the proper temperature range t ₁₁ ~t _22, the outdoor humidity H is higher than the threshold h _1, the control circuit 24
Returns from the second ventilation mode to the first ventilation mode.

Next, another ventilation control by this ventilation control device will be described.

First, assuming that the outdoor temperature detected by the outdoor temperature sensor 17 is T ₁ and the indoor temperature detected by the indoor temperature sensor 18 is T ₂ , the control circuit 24
The absolute value of the difference between the reference temperature t _s specified by the outdoor temperatures T ₁ and Volume 33 | T ₁ -t _s | with obtaining the absolute value of the difference between the room temperature T ₂ and the reference temperature t _s | T ₂ -
t _s |. Then, the control circuit 24 calculates | T ₁ −t
_s | <| T ₂ −t _s |, that is, the outdoor temperature T
Towards ₁ determines whether close to the reference temperature t _s than the room temperature T _2.

At the same time, the control circuit 24 compares the humidity H detected by the humidity sensor 19 with the threshold value h ₁ for the humidity designated by the volume 34 and determines that the outdoor humidity H is equal to the threshold value h. Determine if it is lower than ₁ .

The control circuit 24 determines that at least one of them is “No”
Is determined, the first ventilation mode, that is, normal ventilation is continued.

[0052] The control circuit 24 is close to the outdoor temperature T ₁ of the it is the reference temperature t _s than the room temperature T _2, and the outdoor humidity H is determined to be lower than the threshold h _1, the first The ventilation mode is interrupted and the mode is shifted to the third ventilation mode. At this time, the control circuit 24 turns on the lamp 29, displays that the first ventilation mode has been interrupted and another ventilation mode has been entered.

In order to execute the third ventilation mode, the control circuit 24 switches the changeover switch 15 to cut off the connection between the level adjuster 14 and the driver circuit 5, and connects the control circuit 24 to the driver circuit 5. . And the control circuit 2
4 applies a signal of a level corresponding to 100% of the rotation speed of the motor of the air supply fan 2, that is, the maximum rotation speed, to the driver circuit 5 via the changeover switch 15. Thereby, the motor of the air supply fan 2 rotates at the maximum rotation speed.

As a result, in the third ventilation mode, the amount of air supplied from the outdoors to the room is larger than in the first and second ventilation modes, and the amount of the supplied air is reduced. It becomes the maximum, and the air in the room is more positively purified.

Moreover, the outdoor temperature T ₁ is larger than the indoor temperature T ₂
Since the temperature is closer to the reference temperature t _s , the room temperature T ₂ quickly approaches the most preferable reference temperature t _s , and the energy consumption for cooling and heating is reliably reduced.

In the third ventilation mode, | T ₁ -t
_{s | <| T 2 -t s} | or become a rather, the outdoor humidity H is higher than the threshold h _1, the control circuit 24, the third
Return from the ventilation mode to the first ventilation mode.

By the way, not only the ventilation control combining the first ventilation mode and the second ventilation mode, the ventilation control combining the first ventilation mode and the third ventilation mode, but also the ventilation control combining all three ventilation modes. Is also possible. For example, from the first ventilation mode to the second ventilation mode, from the second ventilation mode to the third ventilation mode, and in the reverse order from the third ventilation mode to the second ventilation mode, from the second ventilation mode to the second ventilation mode. 1 Return to ventilation mode.

In this embodiment, the air supply fan 2 is controlled to increase the amount of air supplied to the room. However, both the exhaust fan 1 and the air supply fan 2 are controlled to May be increased.

Although a pair of exhaust fans 1 and air supply fans 2 are shown here, the number of exhaust fans and air supply fans is arbitrary. Furthermore, ventilation may be performed by either the exhaust fan or the air supply fan to increase or decrease the amount of air supplied into the room.

Further, in this case, a smoke sensor is used to detect the degree of air pollution, but various sensors for detecting impurity gas in the air can be applied.

[0061] The sensor of this kind, there are for example metal oxides _{(S n O 2, Z n} O , etc.) (the one electrode is also used as a heater) a pair of electrodes to the sintered body by embedding a. In this sensor, when the reducing gas comes into contact with the sintered body, chemical adsorption occurs, and the electric conductivity of the sintered body increases. This is detected between the electrodes.

As another sensor of this type, there is a sensor obtained by applying a metal oxide semiconductor to a platinum wire coil and then sintering it. In this sensor, when the gas is adsorbed by the semiconductor, the combined resistance of the semiconductor and the platinum wire coil changes, and this is detected.

Such a sensor is installed, for example, in a factory that handles organic solvents, and the amount of exhausted air is increased or decreased in accordance with the detection output of the sensor to reduce the amount of organic solvent dispersed in the air. If it is suppressed, the deterioration of the working environment can be prevented.

[0064]

As described above, in the ventilation control device according to the present invention, the amount of air supplied from the outside to the room is appropriately increased according to the outdoor temperature, the indoor temperature, and the humidity. Active purification and saving of energy consumption by cooling and heating.

[Brief description of the drawings]

FIG. 1 is a block diagram showing one embodiment of a ventilation control device of the present invention.

FIG. 2 is a table showing characteristics of a first ventilation mode in the device of this embodiment.

FIG. 3 is a table showing characteristics of a second ventilation mode in the device of this embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Exhaust fan 2 Air supply fan 3 Heat exchanger 4,5 Driver circuit 6,7 Inverter 11-1 to 11-n Smoke sensor 13 Maximum value selection circuit 14 Level adjuster 15 Changeover switch 17 Outdoor temperature sensor 18 Indoor temperature sensor 19 Humidity sensor 24 control circuit

 ──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-61-243232 (JP, A) JP-A-4-283333 (JP, A) JP-A-2-267439 (JP, A) JP-A 55-243 81516 (JP, A) JP-A-4-241800 (JP, A) JP-A-3-14012 (JP, A) JP-A 64-23046 (JP, A) JP-A-4-32637 (JP, A) Japanese Utility Model Showa 50-140246 (JP, U) Japanese Utility Model Showa 53-148556 (JP, U) Japanese Utility Model Showa 62-67134 (JP, U) Japanese Utility Model Showa 57-93731 (JP, U) Japanese Utility Model Hei 4-68936 (JP, U)

Claims (2)

(57) [Claims] 1. A ventilation means for ventilating a room, an outdoor temperature detecting means for detecting an outdoor temperature, an indoor temperature detecting means for detecting an indoor temperature, and an outdoor temperature detected by the outdoor temperature detecting means. The absolute value of the difference between the reference temperatures, and the absolute value of the difference between the indoor temperature and the reference temperature detected by the indoor temperature detecting means are compared. If the absolute value of the difference between the outdoor temperature and the reference temperature is smaller, ventilation is performed. Control means for controlling the means to increase the amount of air supplied from the outdoors to the room. 2. The apparatus further comprises humidity detecting means for detecting outdoor humidity, wherein the control means has an absolute value of a difference between the outdoor temperature and the reference temperature smaller than an absolute value of a difference between the indoor temperature and the reference temperature, and The ventilation control according to claim 1, wherein when the humidity detected by the humidity detection means is equal to or less than a predetermined threshold value, the ventilation means is controlled to increase the amount of air supplied from the outdoors to the room. apparatus.