JP5353450B2 - Heat exchange ventilator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem wherein a heat exchange ventilating device has not only a normal heat exchange ventilation operation mode but also an air supply intermittent operation mode and an air supply forced stop operation mode etc. and much information to be informed such as filter cleaning time and maintenance information in an abnormal state etc. is distinguished by lighting, extinction and several types of blinking with different cycles of a pilot lamp and is displayed. <P>SOLUTION: This heat exchange ventilating device includes: a control circuit for outputting first display information and second display information corresponding to an operating state; a first display means for displaying the operating state based on the first display information; and a second display means for displaying the operating state based on the second display information. By combination of the display by the first display means and the display by the second display means, the precise operating state can be recognized. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a heat exchange ventilator having display means for notifying a user of operating conditions, abnormalities, maintenance information, and the like.

Various types of ventilators are known, such as a ventilation fan that only exhausts indoor air, a range hood that exhausts cooking areas, and a heat exchange ventilator that supplies and exhausts air at the same time and exchanges heat between them. ing.
These ventilators have filters in the exhaust passage and air supply passage to prevent oily smoke and indoor dust from adhering to the inside of the device during exhaust operation, and to prevent outside air dust and pollen from being taken into the room during air supply operation. Many types are equipped with The filter needs to be cleaned because it will become dirty and clogged with long-term use, reducing its function. For this reason, notification of urging filter cleaning is performed by a method such as detecting a clogged state with a sensor or determining that the cleaning time has come when a predetermined operating time is exceeded. Such notification is generally performed by turning on a pilot lamp or the like.
For example, Patent Document 1 discloses a ventilator that flashes a lamp incorporated in a wall switch unit to notify a filter maintenance time.

Japanese Unexamined Patent Publication No. 2009-177610 (page 4, Fig. 2)

Ventilators are often installed at high locations on the ceiling and walls, so the switch for operating / stopping the ventilator is mounted on a wall that is accessible to the user and connected to the ventilator body by wiring. ing. Turn this switch on when you want to operate the ventilator, and turn it off when you want to stop it. In the case of a heat exchange ventilator, a heat exchange ventilating operation in which the air supply blower and the exhaust air blower are simultaneously operated is performed as a normal operation by turning on the switch.
By the way, in the heat exchange ventilation operation described above, if the air supply operation is continued for a long time when the outside air is at a low temperature, the ventilator main body may be cooled, resulting in a problem of condensation or freezing of the heat exchanger. Therefore, in order to prevent condensation and freezing, it is necessary to intermittently operate the air supply fan so that the main body and the like do not get too cold. In particular, in a ventilator that performs 24-hour ventilation, the outside air is always supplied, so the outside air temperature is constantly monitored and the intermittent operation is automatically performed.
However, for the user, since it is not known from the outside whether the heat exchange ventilator is performing intermittent operation or normal heat exchange operation, it indicates which operation mode it is operating, etc. It is desirable to be able to grasp by.
In addition to the difference in operation mode, maintenance information is also required, such as operation in a clogged condition that requires filter cleaning, and operation in the presence of some abnormality such as a failure in the ventilator. Is information necessary to effectively operate the ventilator in a normal state by cleaning the filter or requesting repair, and must be able to be grasped by display or the like.

  When trying to report each operation mode and each operation state information using the lamp built in the switch unit installed on the wall like a conventional ventilator, if there is a lot of information like a heat exchange ventilator Since it cannot be expressed only by lighting / extinguishing / flashing of the lamp, it can be considered that a plurality of flashing periods are prepared and information to be notified is assigned to each of them. However, the difference in the blinking cycle that can be grasped intuitively by the user is limited to fast blinking and slow blinking at most, so it is difficult for the user to grasp if there are several types of blinking with different cycles. Does not make sense. In other words, it has been difficult to notify various operation modes and maintenance information with a display using a conventional switch built-in lamp.

  The present invention provides a heat exchange ventilator capable of easily and easily informing a user of various operation states such as various operation modes and maintenance information of the ventilator.

In the heat exchange ventilator according to the present invention, the main body of the heat exchange ventilator has a main body, an air supply air passage for supplying outdoor air into the room, and an exhaust air passage for exhausting indoor air to the outside. A supply air blower provided in the supply air passage to form a supply air flow; an exhaust blower provided in the exhaust air passage to form an exhaust flow; air in the supply air passage and air in the exhaust air passage The first display information and the first operating state according to one classification for controlling the operation of the heat exchanger that exchanges heat with the air, the air supply fan and the exhaust air fan, and notifying the type of the operating state And a control circuit for outputting second display information according to another classification for notifying the type different from the display information of the first display information, and displaying a driving state based on the first display information outside the main body. comprising a display means, and second display means for displaying an operating state based on the second display information, First display means and the second display means is obtained by placed away from each other.

  Since the present invention is configured to output the first display information and the second display information from the control circuit of the heat exchange ventilator, the user can use a combination of the first display information and the second display information. Various operating states of the ventilator can be easily recognized.

It is a block diagram of the heat exchange ventilation apparatus which shows Embodiment 1 of this invention. It is a switch circuit attachment external view of the heat exchange ventilation apparatus which shows Embodiment 1 of this invention. It is a 2nd pilot lamp attachment external view of the heat exchange ventilation apparatus which shows Embodiment 1 of this invention. It is a circuit diagram of the heat exchange ventilation apparatus which shows Embodiment 1 of this invention. It is an operation state-display correspondence table | surface of the heat exchange ventilation apparatus which shows Embodiment 1 of this invention. It is a circuit diagram of the heat exchange ventilation apparatus which shows Embodiment 2 of this invention. It is a driving | operation state-display correspondence table | surface of the heat exchange ventilation apparatus which shows Embodiment 2 of this invention.

Embodiment 1 FIG.
FIG. 1 is a block diagram of a heat exchange ventilator showing a first embodiment of the present invention.
First, the outline of the configuration of the heat exchange ventilator will be described with reference to FIG. The main body 1 of the heat exchange ventilator includes a supply air passage 2 for supplying outdoor air to the room and an exhaust air passage 3 for exhausting the indoor air to the outside. An outdoor suction port 1 a and an outdoor air outlet 1 d are provided on the side of the main body 1 that communicates with the outside, and communicate with the supply air passage 2 and the exhaust air passage 3, respectively. In addition, an indoor outlet 1b and an indoor suction port 1c are provided on the side of the main body 1 that communicates with the room, and communicate with the supply air passage 2 and the exhaust air passage 3, respectively. Further, an air supply fan 4 that forms a supply airflow (arrow A in FIG. 1) is formed in the supply air passage 2, and an exhaust fan 5 that forms an exhaust flow (arrow B in FIG. 1) is formed in the exhaust air passage 3. Each is provided. The supply air passage 2 and the exhaust air passage 3 partially intersect with each other, and a heat exchanger 6 that performs heat exchange between air and air is incorporated in the intersection.

The commercial AC power supply 7 supplies power to the air supply fan 4, the exhaust fan 5, and the control circuit 8 of the heat exchange ventilator in the main body 1 of the heat exchange ventilator. The main body 1 of the heat exchange ventilator is installed on the upper part of the wall on the outdoor side or on the ceiling (the outside and the supply / exhaust air passage are connected by a duct). The switch circuit 9 outputs an operation / stop instruction of the heat exchange ventilator and an air volume switching instruction to the control circuit 8 in the main body 1 when operated by the user. The control circuit 8 controls the air supply fan 4 and the exhaust fan 5 based on the command. Further, the control circuit 8 sends and displays the operation state of the heat exchange ventilator to the first display means incorporated in the switch circuit 9 and the second display means outside the switch circuit 9. In the first embodiment, the first pilot lamp 10 is used as the first display means, and the second pilot lamp 11 is used as the second display means. The switch circuit 9 is housed in a switch box installed on a wall having an appropriate height so that it can be easily operated by the user. Similarly, the second pilot lamp 11 is housed in another switch box installed on a wall or the like. FIG. 2 is a mounting external view of the switch circuit, and FIG. 3 is a mounting external view of the second pilot lamp.
The main body 1, the commercial AC power source 7, the switch circuit 9, and the second pilot lamp 11 are connected by a power line and a signal line. Further, an air supply filter 12 for removing dust, pollen and the like contained in the outside air is installed in the air supply air passage 2 at the upstream entrance of the heat exchanger 6, and the exhaust air passage 3 is provided with clothes and the like contained in room air. An exhaust filter 13 that removes the cotton dust and the like is installed at the upstream entrance of the heat exchanger 6. A thermistor 14 for detecting the temperature of the outside air taken in from the outdoor air supply port is installed in the vicinity of the outdoor air supply port of the air supply path 2.

  Next, the outline of the operation of the heat exchange ventilator will be described with reference to FIG. When the user switches the operation switch 9a of the switch circuit 9 from OFF (“stop”) to ON (“operation”), the control circuit 8 detects this and both the air supply fan 4 and the exhaust fan 5 are detected. Drive. When the air supply fan 4 is operated, an air supply airflow (arrow A in FIG. 1) is generated in the air supply air passage 2, and fresh outdoor air is taken in from the outdoor suction port 1a. Is supplied into the room from the indoor outlet 1b. Similarly, an exhaust flow (arrow B in FIG. 1) is generated in the exhaust air passage 3 by the operation of the exhaust blower 5, and dirty air in the room is taken in from the indoor suction port 1c, and the exhaust filter 13 and the heat exchanger 6 is discharged to the outside from the outdoor outlet 1d. At this time, since heat is exchanged between the supply air and the exhaust gas by the heat exchanger 6, ventilation with less heat loss during cooling and heating can be performed by heat recovery. This is the normal heat exchange ventilation operation performed by the heat exchange ventilator.

By operating the strong / weak switching switch 9b of the switch circuit 9, it is possible to select the high air flow operation or the low air flow operation of the heat exchange ventilation operation. By turning ON / OFF the strong / weak switch 9b ("strong"), the notches of the air supply blower 4 and the exhaust blower 5 are both selected as "strong", and the operation of the heat exchange ventilator is a high air flow operation. . Further, by turning off the strong / weak switching switch 9b ("weak"), the notches of the air supply fan 4 and the exhaust fan 5 are both selected as "weak", and the heat exchange ventilator is operated with a low air flow. It becomes.

When heat exchange ventilation operation is performed when the outside air temperature is low, such as in winter, the temperature difference between the outside and the room is too large, and the temperature of the air supplied to the room from the indoor outlet 1b is low even if heat exchange is performed. The user may feel a cold wind. In order to relieve the cold air feeling, the forced air supply stop operation can be selected. By turning ON (“ON”) the air supply stop switch 9 c of the switch circuit 9, the control circuit 8 forcibly stops the air supply fan 4. Therefore, cold air from the outside is not taken in, and the cold wind feeling is alleviated.

Moreover, if the heat exchange ventilation operation is continued in a state where the outside air temperature is low, the heat exchange ventilator main body and the heat exchanger may be cooled by the low-temperature outside air taken in, and condensation or freezing may occur. In order to prevent this, the outside air temperature is detected by the thermistor 14 installed in the air supply path 2 and sent to the control circuit 8. When the outside air temperature is lower than a predetermined value, the control circuit 8 performs intermittent operation in which the air supply fan 4 repeats operation / stop. In addition, the ratio of the operation time and the stop time of the intermittent operation is “50 minutes operation / 10 minutes stop” when the outside air temperature is not lower than the predetermined value but is not so low, or the outside air temperature is considerably lower than the predetermined value. In such a case, “5 minutes operation / 55 minutes stop” is set so that minimum ventilation can be secured while preventing condensation and freezing. This operation mode is automatically executed when the thermistor 14 detects the outside air temperature.

As described above, the heat exchange ventilator removes dust and pollen contained in the outside air by the air supply filter 12 to prevent the dust and pollen from adhering to the heat exchanger 6 or entering the indoor side. Moreover, the dust etc. from the clothing etc. which are contained in room air are removed by the exhaust filter 13, and it prevents that it adheres to the heat exchanger 6. FIG. When the heat exchanging ventilator is operated for a long time, the dust, pollen and cotton dust adhere to the air supply filter 12 and the exhaust filter 13 and become dirty or clogged, thereby reducing the performance. Maintenance such as periodic cleaning or replacement is required for the filter 12 and the exhaust filter 13. The control circuit 8 of the heat exchanging ventilator counts the accumulated operation time of the heat exchanging ventilator and determines whether or not the predetermined time has been exceeded. The first pilot lamp 10 informs the user.

FIG. 4 is a circuit diagram of the heat exchange ventilator showing Embodiment 1 of the present invention.
The configuration in the control circuit 8 will be described with reference to FIG. A terminal block 15 is mounted on the control circuit 8. The commercial AC power supply 7 is connected between the terminal 15a and the terminal 15b of the terminal block 15, and the operation switch 9a and the first pilot lamp 10 are connected in series between the terminal 15a and the terminal 15c. A strength changeover switch 9b is connected between the terminals 15a and 15d, and an air supply stop switch 9c is connected between the terminals 15a and 15e. Further, the second pilot lamp 11 is connected between the terminal 15f and the terminal 15g.
In the control circuit 8, a power supply circuit 16 is connected to the terminals 15a and 15b via current fuses. The power supply circuit 16 generates a control power supply (DC 5 V, DC 12 V, etc.) and supplies it to each circuit unit in the control circuit 8.

One end of a detection circuit 17 and a lighting / extinguishing control circuit 18 is connected to the terminal 15c. The detection circuit 17 includes a resistor 19, a light emitting unit 20 a of the photocoupler 20, and a diode 21. The on / off control circuit 18 includes a resistor 22, a diode bridge 23, and a light receiving unit 24 b of a photocoupler 24. The other ends of the detection circuit 17 and the lighting / extinguishing control circuit 18 are connected to a line on the terminal 15 b side, that is, one end of the commercial AC power supply 7. One end of a second detection circuit and a third detection circuit (not shown) are connected to the terminal 15d and the terminal 15e. The second detection circuit and the third detection circuit have the same configuration as the detection circuit 17. The other ends of the second detection circuit and the third detection circuit are connected to a line on the terminal 15 b side, that is, one end of the commercial AC power supply 7.
The light receiving unit 20b corresponding to the light emitting unit 20a of the photocoupler 20 of the detection circuit 17 is connected in series with a resistor between the control power supply (DC5V) and the circuit GND, and the emitter side terminal is connected to the input terminal 25a of the microcomputer 25. Is done. The photocoupler light receiving unit side in the second detection circuit and the third detection circuit (not shown) has the same configuration.
The light emitting unit 24a corresponding to the light receiving unit 24b of the photocoupler 24 of the on / off control circuit 18 is connected to the control power source (DC5V) on the anode side and to the output terminal 25b of the microcomputer 25 via the resistor on the cathode side. .

The terminal 15 f is connected to a line on the terminal 15 b side, that is, one end of the commercial AC power supply 7 through a contact portion 26 b of the relay 26. The terminal 15g is connected to a line on the terminal 15a side, that is, the other end of the commercial AC power supply 7. The coil portion 26a of the relay 26 is connected in series with a transistor between the control power supply (DC 12V) and the circuit GND, and the base of the transistor is connected to the output terminal 25c of the microcomputer 25 through a resistor.

The control circuit 8 is provided with a terminal block 28 for connecting the air supply fan 4 and a terminal block 29 for connecting the exhaust fan 5. A common terminal of the air supply fan 4 is connected to the terminal 28a of the terminal block 28, and a strong notch terminal and a weak notch terminal of the air supply fan 4 are connected to the terminals 28b and 28c, respectively. A common terminal of the exhaust fan 5 is connected to the terminal 29a of the terminal block 29, and a strong notch terminal and a weak notch terminal of the exhaust fan 5 are connected to the terminals 29b and 29c, respectively.
In the control circuit 8, the terminal 28a is connected to a line on the terminal 15a side, that is, the other end of the commercial AC power source 7. The terminal 28b and the terminal 28c are respectively connected to the NO terminal and the NC terminal of the contact 30b of the relay 30, and the common terminal of the contact 30b is connected to one end of the contact 31b of the relay 31. The other end of the contact portion 31b is connected to a line on the terminal 15b side, that is, one end of the commercial AC power source 7.
The coil portion 30a of the relay 30 is connected in series with a transistor between the control power supply (DC12V) and the circuit GND, and the base of the transistor is connected to the output terminal 25e of the microcomputer 25 via a resistor. The coil portion 31a of the relay 31 is connected in series with a transistor between the control power supply (DC12V) and the circuit GND, and the base of the transistor is connected to the output terminal 25f of the microcomputer 25 via a resistor.
The terminal 29a to terminal 29c have the same configuration (not shown).

  In addition, a terminal block 32 is mounted on the control circuit 8, and the thermistor 14 in the heat exchange ventilator is connected to the terminal block 32. In the control circuit 8, the terminal block 32 is connected to the input terminal 25 g of the microcomputer 25.

Next, the operation of the control circuit will be described.
First, a method in which the control circuit recognizes the open / close state of the operation switch 9a, the strength changeover switch 9b, and the air supply stop switch 9c will be described. When the operation switch 9a is closed, the commercial AC power supply 7 is applied to the operation switch 9a, the first pilot lamp 10, and the detection circuit 17, and the operation switch 9a, the first pilot lamp 10, the resistor 19, and the photocoupler A current flows through the path of the 20 light emitting units 20 a and the diode 21. The value of the current flowing through this path is determined by the value of the resistor 19. Therefore, the resistor is set so that the current value is insufficient for lighting the first pilot lamp 10 and sufficient for causing the light emitting portion 20a of the photocoupler 20 to emit light. A value of 19 is determined. When the light emitting unit 20a of the photocoupler 20 emits light, the light receiving unit 20b becomes conductive, and thus a Hi level voltage is input to the input terminal 25a of the microcomputer 25. When the operation switch 9a is open, no current flows through the light emitting unit 20a of the photocoupler 20, and the light receiving unit 20b is non-conductive. Therefore, a Lo level voltage is input to the input terminal 25a of the microcomputer 25. That is, the microcomputer 25 can know the open / closed state of the operation switch 9a by monitoring the input voltage of the input terminal 25a. The microcomputer 25 controls the air supply blower 4 and the exhaust blower 5 in accordance with the open / close state of the operation switch 9a.
The strength changeover switch 9b and the air supply stop switch 9c are also connected to a second detection circuit and a third detection circuit (both not shown) having the same configuration as the detection circuit 17, respectively. The open / closed state can be recognized.

Next, the operation of the lighting / extinguishing control circuit 18 will be described. When it is desired to turn on the first pilot lamp 10, the microcomputer 25 sets the output terminal 25b to Lo. As a result, a current flows through the light emitting unit 24 a of the photocoupler 24, so that the light emitting unit 24 a emits light, the light receiving unit 24 b conducts, and the DC side terminal (+, −) of the diode bridge 23 is short-circuited. That is, even when the diode bridge 23 is viewed from the AC side terminal, it is still in a short-circuited state, so that the full wave current flows through the first pilot lamp 10 via the resistor 22 and the diode bridge 23. The value of this current is determined by the resistor 22. Therefore, the value of the resistor 22 is determined so that the current value is sufficient to turn on the first pilot lamp 10.
When it is desired to turn off the first pilot lamp 10, the microcomputer 25 sets the output terminal 25b to Hi. As a result, no current flows through the light emitting portion 24a of the photocoupler 24, so that the light emitting portion 24a does not emit light and the light receiving portion 24b is disabled. Accordingly, when the diode bridge 23 is viewed from the AC side terminal, the diode bridge 23 is in an open state, so that no current flows through the first pilot lamp 10 and the light is extinguished.
Further, when the first pilot lamp 10 is desired to blink, the microcomputer 25 switches Lo / Hi of the output terminal 25b at a certain cycle (for example, 0.5 seconds Lo / 0.5 seconds Hi). As a result, the state where the current flows through the first pilot lamp 10 for 0.5 seconds and does not flow for 0.5 seconds is repeated. That is, the first pilot lamp 10 is in a blinking state (0.5 seconds on / 0.5 seconds off).
If the operation switch 9a is opened, no current flows through the first pilot lamp 10 regardless of the state of the output terminal 25b by the microcomputer 25, and the light is turned off.
As described above, if the operation switch 9a is in a closed state, the microcomputer 25 can control the first pilot lamp 10 to any state of lighting / extinguishing / flashing by controlling the output terminal 25b. .

Next, the output operation to the second pilot lamp 11 will be described. When it is desired to turn on the second pilot lamp 11, the microcomputer 25 sets the output terminal 25c to Hi. As a result, the transistor connected to the output terminal 25c is turned on, and a current flows through the coil portion 26a of the relay 26, so that the contact portion 26b is closed. Therefore, AC 100 V is output between the terminal 15 f and the terminal 15 g of the terminal block 15. That is, the second pilot lamp 11 connected between the terminal 15f and the terminal 15g is turned on. Here, the second pilot lamp 11 is a pilot lamp that is turned on by applying AC 100V.
When it is desired to turn off the second pilot lamp 11, the microcomputer 25 sets the output terminal 25c to Lo. As a result, the transistor connected to the output terminal 25c is turned off, and no current flows through the coil portion 26a of the relay 26, so that the contact portion 26b is opened. Therefore, AC 100 V is not output between the terminal 15 f and the terminal 15 g of the terminal block 15. That is, the second pilot lamp 11 connected between the terminal 15f and the terminal 15g is turned off.

Next, driving of the air supply fan 4 and the exhaust fan 5 will be described.
When the air supply fan 4 is operated (strong air volume operation), the microcomputer 25 sets the output terminal 25f and the output terminal 25e to Hi. The transistors connected to the respective output terminals are both turned on, and current flows through the coil portion 31a of the relay 31 and the coil portion 30a of the relay 30. Therefore, the contact part 31b of the relay 31 is closed, and the contact part 30b of the relay 30 is closed to the NO terminal side. That is, AC 100 V is applied between the common terminal and the strong notch terminal of the air supply blower 4, and the high air flow operation is executed.
When the air supply fan 4 is operated at a low air flow rate, the microcomputer 25 sets the output terminal 25f to Hi and sets the output terminal 25e to Lo. Since current flows through the coil portion 31a of the relay 31 and no current flows through the coil portion 30a of the relay 30, the contact portion 31b of the relay 31 is closed, and the contact portion 30b of the relay 30 is closed to the NC terminal side. That is, AC 100 V is applied between the common terminal and the weak notch terminal of the air supply blower 4, and the weak air volume operation is executed.
When the air supply fan 4 is stopped, the microcomputer 25 sets the output terminal 25f to Lo. Since no current flows through the coil portion 31a of the relay 31, the contact portion 31b of the relay 31 opens. That is, AC100V is not applied to the air supply fan 4, and the operation is stopped.
The exhaust fan 5 is also connected to a relay circuit (not shown) having the same configuration as the relay 30 and the relay 31, and the microcomputer 25 similarly controls the exhaust fan 5 (strong air volume operation, low air volume operation). Can be stopped).

Next, the operation of the thermistor 14 will be described. The resistance value of the thermistor 14 changes in accordance with the ambient temperature. The resistance value is converted into a voltage value by a control power source, a resistor connected in series, and the like, and is given to the input terminal 25g of the microcomputer 25. The microcomputer 25 converts the analog value input from the input terminal 25g into a digital value. Thereby, the microcomputer 25 can detect the temperature of the air in the vicinity of the thermistor 14, that is, the temperature of the outside air.

FIG. 5 is an operation state-display correspondence table of the heat exchange ventilation apparatus showing Embodiment 1 of the present invention.
Hereinafter, the relationship between each operation mode and maintenance information and display in the heat exchange ventilator shown in FIG. 5 will be described.
First, in the heat exchange ventilator, the operation switch 9a is in an ON state (“operation”), the air supply stop switch 9c is in an OFF state (“OFF”), and the operation time counted in the microcomputer 25 is a predetermined value or less (filter cleaning). If the temperature of the thermistor 14 is equal to or higher than a predetermined value (condensation and freezing temperature range) and the operation is normal (no abnormality), the microcomputer 25 is in a normal operation state of a normal heat exchange ventilation operation mode. The first pilot lamp 10 is turned on and the second pilot lamp 11 is turned off as shown in “Heat exchange ventilation operation” in FIG.
In addition, the operation switch 9a is in the ON state ("operation"), the air supply stop switch 9c is in the OFF state ("OFF"), and the operation time counted in the microcomputer 25 is a predetermined value or more (exceeding the filter cleaning guide time). If the temperature of the thermistor 14 is equal to or higher than a predetermined value (condensation and out of the freezing temperature range) and the operation is normal (no abnormality), the microcomputer 25 is in a normal heat exchange ventilation operation mode and requires filter cleaning. As shown in the “filter maintenance sign” of FIG. 5, the first pilot lamp 10 is “blinking for 2 seconds” (2 seconds on / 2 seconds off), and the second pilot lamp 11 is “off”. "
Further, the operation switch 9a is in the ON state ("operation"), the air supply stop switch 9c is in the OFF state ("OFF"), the operation time counted in the microcomputer 25 is less than a predetermined value (before the filter cleaning guide time), the thermistor If the temperature of 14 is equal to or lower than a predetermined value (entering a temperature range in which condensation or freezing is a concern) and the operation is normal (no abnormality), the microcomputer 25 determines that the intermittent air supply operation is necessary, While the air supply blower 4 is intermittently operated, the first pilot lamp 10 is “lighted” and the second pilot lamp 11 is “lighted” as shown in “intermittent air supply operation” in FIG.
Further, when the operation switch 9a is in the ON state ("operation"), the air supply stop switch 9c is in the ON state ("ON"), the operation time counted in the microcomputer 25 is less than a predetermined value (before the filter cleaning guide time), Is normal (no abnormality), the microcomputer 25 stops the air supply blower 4 and “lights” the first pilot lamp 10 as shown in the “air supply forced stop operation” of FIG. The second pilot lamp 11 is turned on.
When the microcomputer 25 detects any abnormality (such as failure of a part in the control circuit or operation of a safety device), the microcomputer 25 detects the first pilot lamp 10 as shown in “abnormality” in FIG. Is “0.5 seconds blinking” (0.5 seconds on / 0.5 seconds off), and the second pilot lamp 11 is turned “on”.

In FIG. 5, the first pilot lamp 10 can roughly grasp whether the heat exchange ventilator is “normal operation”, “abnormal condition”, or “stop”. . That is, the normal heat exchange ventilation operation indicated by “lighting”, intermittent supply air operation, and forced air supply stop operation are all normal operations although there are differences in operation modes. Moreover, it can be said that it is an abnormal state because it causes clogging and performance degradation if the operation with the filter maintenance sign is left as it is, as well as the occurrence of the abnormality indicated by “blinking”. In addition, “light-off” is a stop of operation. The first pilot lamp 10 can recognize a rough operation state of such a heat exchange ventilator.
The second pilot lamp 11 can roughly grasp whether the heat exchange ventilator is “normal operation” or “special operation”. That is, the normal heat exchange ventilation operation indicated by “extinguish” and the operation with the filter maintenance sign appear are both in the normal operation mode although there are differences in the operation state. On the other hand, intermittent air supply operation and forced air supply stop operation indicated by “lit” are special operation modes to prevent condensation and freezing, and to reduce the feeling of cold air. It can be said that it is a driving state. With the second pilot lamp 11, it is possible to recognize a rough difference in operating state of such a heat exchange ventilator.
As described above, it is possible to grasp a rough state even if only one of the first pilot lamp 10 and the second pilot lamp 11 is viewed. However, the details shown in FIG. Can recognize the difference in various driving conditions.

In the heat exchange ventilator configured in this way, in addition to the normal heat exchange ventilation operation, intermittent operation of the air supply blower to prevent condensation and freezing, and forced air supply stop operation to reduce the feeling of cold air There are various maintenance information such as various operation modes such as filter maintenance and occurrence of abnormality, etc., but the user can easily recognize various operation states by the combination display of the first pilot lamp 10 and the second pilot lamp 11. There is an effect that can be.
In addition, since it is possible to grasp a rough driving state only by looking at either the first pilot lamp 10 or the second pilot lamp 11, the first pilot lamp 10 and the second pilot lamp 11 are placed in the room. Even if the first pilot lamp 10 is installed on a certain wall surface and the second pilot lamp 11 is installed on another wall surface opposite to the wall surface. By looking at only the pilot lamp that is easy to see, it is possible to capture a rough driving state.

The first pilot lamp 10 and the second pilot lamp 11 have been described as being installed in the same room, but this need not be the case. For example, the second pilot lamp 11 may be installed in a room in which a heat exchange ventilator is installed, and the first pilot lamp 10 may be installed in a corridor near the entrance of the room. Whether in the room or in the hallway, the user can capture the general operating condition of the heat exchange ventilator.
In addition, the first pilot lamp 10 integrated with the switch circuit 9 needs to be installed in a place where the user can reach, such as a wall, but the second pilot lamp 11 is not limited to the place where the hand can reach, and the wall It is also possible to install it near a heat exchanging ventilator main body installed on a high position or on the ceiling or outside of the heat exchanging ventilator main body. In this case, since it is installed near the device, it is easier for the user to understand what is displayed intuitively.

Embodiment 2. FIG.
FIG. 6 is a circuit diagram of a heat exchange ventilator showing a second embodiment of the present invention. In the second embodiment, the display pattern of each operation mode and maintenance information displayed by the first pilot lamp and the second pilot lamp can be arbitrarily changed to a display pattern preferred by the user. . The configuration will be described below with reference to FIG. The control circuit 8 is provided with a switch 33 and a switch 34 which are display output switching means. The first pole 33a, the second pole 33b, the third pole 33c, the fourth pole 33d, and the common pole 33e of the switch 33 are the input terminal 25h, the input terminal 25i, the input terminal 25j, and the input terminal of the microcomputer 25, respectively. 25k, connected to circuit GND. Each input terminal is connected to a pull-up resistor. The first pole 34a, the second pole 34b, the third pole 34c, the fourth pole 34d, and the common pole 34e of the switch 34 are the input terminal 25l, the input terminal 25m, the input terminal 25n, and the input terminal of the microcomputer 25, respectively. 25o, connected to circuit GND. Each input terminal is connected to a pull-up resistor. Other parts are the same as the circuit diagram shown in FIG.

Next, the operation will be described. By switching the switch 33, any one of the first pole 33a to the fourth pole 33d and the common pole 33e can be short-circuited. At this time, a switch state in which the common pole 33e and the first pole 33a are short-circuited is defined as a position 1. Similarly, switch states in which the common electrode 33e and the second,..., And fourth electrodes are short-circuited are referred to as position 2,. The input terminal connected to the pole shorted with the common pole 33e has the same potential as the circuit GND. DC5V is input to the input terminal connected to the other pole by a pull-up resistor.
Similarly, by switching the switch 34, any one of the first pole 34a to the fourth pole 34d and the common pole 34e can be short-circuited. At this time, a switch state in which the common pole 34e and the first pole 34a are short-circuited is defined as a position 1. Similarly, switch states in which the common pole 34e and the second,..., Fourth poles are short-circuited are referred to as position 2,. The input terminal connected to the pole shorted with the common pole 34e has the same potential as the circuit GND. DC5V is input to the input terminal connected to the other pole by a pull-up resistor.

FIG. 7 is an operation state-display correspondence table of the heat exchange ventilator showing the second embodiment of the present invention. Assume that the correspondence relationship in FIG. 7 is stored in the microcomputer 25 in advance. The microcomputer 25 confirms the input voltage level to the input terminals 25h to 25k and the input terminals 25l to 25o, and can recognize which position of each switch is selected depending on which input terminal is at the Lo level. The microcomputer 25 determines a display pattern for each operation state based on the position of each selected switch and the correspondence relationship in FIG. Then, display is performed according to the determined display pattern. For example, in the switch 33, if the switch state in which the position 2, that is, the second pole 33b and the common pole 33e is short-circuited is selected, the input terminal 25i becomes Lo level, and the input terminals 25h, 25j, and 25k become Hi level. . Accordingly, the microcomputer 25 recognizes that the switch 33 is at the position of the second pole 33b, that is, the position 2, and performs display according to the display pattern of the position 2 of the switch 33 in FIG. That is, the first pilot lamp is “lighted” in the case of the filter maintenance sign, and the first pilot lamp is “flashed for 0.5 seconds” in the abnormal state.
As described above, the microcomputer 25 switches the display pattern for each operation mode and each maintenance information according to the correspondence relationship of FIG. 7 stored in advance and the position selected by each switch. , Display according to the pattern. The switch 33 is a switch for switching the display pattern of the first pilot lamp 10, and the switch 34 is a switch for switching the display pattern of the second display means.

The position of the above-described switch 33 and switch 34, that is, the common pole and which pole is short-circuited is set in advance by the user. Thereby, the user can select and use his / her favorite display pattern. For example, a user who dislikes blinking of the display means stops the standard pattern of position 1 in the switch 33 and selects one of position 2, position 3, or position 4. Position 2 is suitable for users who want to avoid blinking, but blinking when there is an abnormality is unavoidable in order to use the equipment normally. Position 3 still wants to avoid blinking but wants to know filter maintenance. This is suitable for the user who is not interested in slow flashing, and position 4 is suitable for the user who does not like flashing in any case. (See Figure 7)
In the standard pattern of the position 1 of the switch 34, the light is turned on during the special operation and is turned off during the normal operation. However, the user who wants to turn it on during the normal operation and turn off the light during the special operation can be set to the position 2. In addition, in the display pattern of position 1 and position 2, even when combined with the switch 33, it is not known whether the operation is in intermittent operation or forced air supply stop operation. In such a case, it is possible to select position 3 to clarify which is being performed in the intermittent operation or the forced air supply stop operation.

As described above, in the present embodiment, the operation mode and maintenance information displayed by the first pilot lamp and the second pilot lamp can be changed to an arbitrary pattern by the user switching the switch. Thereby, for example, it is possible to select and use a display pattern that meets the needs of the user, such as not wanting the display to blink.

DESCRIPTION OF SYMBOLS 1 Main body 2 Supply air path 3 Exhaust air path 4 Supply air blower 5 Exhaust air blower 6 Heat exchanger 8 Control circuit 10 1st pilot lamp 11 which is 1st display means 2nd which is 2nd display means Pilot lamp 33 Switch as display output switching means 34 Switch as display output switching means 100 Heat exchange ventilator

Claims (2)

Having the body of a heat exchange ventilator,
In the body,
An air supply passage for supplying outdoor air into the room;
An exhaust air passage for exhausting indoor air to the outside;
An air supply blower that is provided in the air supply air passage to form an air supply airflow;
An exhaust fan provided in the exhaust air passage to form an exhaust flow;
A heat exchanger for exchanging heat between the air in the supply air passage and the air in the exhaust air passage;
Controls the operation of the air supply blower and the exhaust air blower, and notifies the first display information according to one classification for notifying the type of operation state and the type different from the first display information of the operation state. A control circuit for outputting second display information according to another classification,
Outside the body,
First display means for displaying an operating state based on the first display information;
Second display means for displaying an operation state based on the second display information,
Installing the first display means and the second display means apart from each other ;
The control circuit includes display output switching means for changing a display pattern of the first display information and the second display information by a user operation,
The heat exchange ventilator characterized in that the control circuit changes and outputs the display pattern of the first display information and the display pattern of the second display information according to the output of the display output switching means. The heat exchange according to claim 1 , wherein a detailed operation state is reported by combining an operation state display based on the first display information and an operation state display based on the second display information. Ventilation device.

Images