JP3924377B2 - Ventilation device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a ventilation device provided with an air volume detecting means for detecting an air volume circulating in a main body frame.
[0002]
[Problems to be solved by the invention]
For example, some ventilation fans have a structure in which a fan mechanism is disposed in a main body frame and indoor air is discharged to the outside through the inside of the main body frame. In the case of this configuration, the air volume in the main body frame is detected by an air volume detecting means such as a differential pressure sensor, and the exhaust air volume is adjusted by controlling the rotational speed of the fan mechanism based on the output signal of the air volume detecting means. .
[0003]
In the case of the ventilation fan, the air volume detecting means is affected by the ambient temperature, and an error occurs in the output signal of the air volume detecting means. For this reason, although the output signal of the air volume detecting means is corrected based on the output signal of the temperature sensor, there is a possibility that the output signal of the air volume detecting means may not be corrected accurately because the characteristics of the temperature sensor vary. In addition, when the air volume detection means has changed over time, the output signal of the air volume detection means cannot be corrected.
[0004]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a ventilation device that can accurately detect the air volume while suppressing the influence of the ambient temperature of the air volume detecting means and the secular change.
[0005]
[Means for Solving the Problems]
  Claim1The described ventilation device isInstalled on the ceiling of the houseBody frame,A ventilation path that is provided inside the main body frame and that connects an air intake chamber inside the main body frame and a fan storage chamber located above the air intake chamber, and an air inside the house that is provided in the fan storage chamber. A fan mechanism that sequentially passes through the intake chamber and the ventilation path and discharges the fan from the fan storage chamber, and a damper that is rotatably provided between the horizontal fully closed state and the vertical fully opened state inside the ventilation path; A damper mechanism having a damper motor that rotates the damper between a fully closed state and a fully open state; a first pressure sensor that detects an internal pressure of the intake chamber; and a second pressure sensor that detects an internal pressure of the ventilation path And an arithmetic circuit for outputting a differential pressure signal at a voltage level corresponding to the differential pressure between the detection result of the first pressure sensor and the detection result of the second pressure sensor, and the tolerance of the initial differential pressure signal and the initial differential pressure signal And a control device that drives and controls each of the fan mechanism and the damper mechanism, and the control device fully opens the damper and turns on the fan mechanism. The differential pressure signal output from the arithmetic circuit is detected in a state where the fan mechanism is turned off and the damper is fully closed. The pressure signal is compared with the added value of the initial differential pressure signal and the allowable value stored in the storage means, and is detected when the detected differential pressure signal is less than or equal to the added value of the initial differential pressure signal and the allowed value. The rotational pressure of the fan mechanism is controlled according to the comparison result between the differential pressure signal output from the arithmetic circuit and the stored differential pressure signal, and the detected differential pressure signal is the initial difference. Pressure signal and tolerance To control the rotational speed of the fan mechanism in accordance with the comparison result between the differential pressure signal outputted from further said arithmetic circuit and the initial differential pressure signal when greater than the next instruction andHowever, it has the characteristics.
  According to the above means,Differential pressure output from the arithmetic circuit in a non-ventilated state with the damper fully closedSignal as zero pointDifferential pressure output from the arithmetic circuit with the damper fully ventilatedThe signal can be corrected. For this reason,Differential pressure output from the arithmetic circuitEven if the signal drifts due to the influence of the ambient temperature and aging, the air volume in the main body frame is accurately detected.
According to the above means, since the differential pressure signal in the ventilation state can be corrected based on the latest differential pressure signal in the non-ventilation state, the air volume in the main body frame can be detected more accurately.
  According to the above means, for example, when the air volume in the main body frame is large, the fan mechanism is stopped and the damper mechanism is opened, so that the indoor air can be naturally exhausted. For this reason, since it is not necessary to always operate a fan mechanism, power consumption is reduced.
[0007]
  According to the above means, in the ventilation stateDifferential pressure signalIs big,In arithmetic circuitThere is a risk of wind flowing in a non-ventilated state (in a non-ventilated stateDifferential pressure signalIn the case of non-ventilated condition)Differential pressure signalIs not updated. For this reason, it included errorsDifferential pressure signalIs prevented from being used for correction, the air volume in the main body frame is detected more accurately.In addition, since the differential pressure signal in the ventilation state can be corrected based on the latest differential pressure signal that does not include an error in the non-ventilation state, the air volume in the main body frame can be detected more accurately.
[0009]
  According to the above means, in a non-ventilated stateDifferential pressure signalContains the above error,Value obtained by adding an allowable value to the differential pressure signal output from the arithmetic circuit and the initial differential pressure signal of the storage meansAnd the difference betweenDifferential pressure signal output from the arithmetic circuitIs invalidated. For this reason, it included errorsDifferential pressure signalIs prevented from being used for correction, the air volume in the main body frame is detected more accurately.
[0010]
  The ventilation device according to claim 2, wherein when the test mode is set, the control device fully closes the damper when the fan mechanism is on, and fully closes the damper when the fan mechanism is on. Comparing the difference between the differential pressure signal output from the arithmetic circuit and the differential pressure signal output from the arithmetic circuit when the damper is fully opened in the on state of the fan mechanism with a judgment value stored in advance. It is characterized in that the presence or absence of an abnormality is detected based on the above.
  According to the above means, for exampleArithmetic circuitIn non-ventilated stateDifferential pressure signalAnd in ventilationDifferential pressure signalBased on the small difference betweenDamper mechanismCan be detected.In addition, since the differential pressure signal in the ventilation state is detected when the fan mechanism is activated, the difference between the differential pressure signal in the ventilation state and the differential pressure signal in the non-ventilation state becomes large, and the malfunction of the damper mechanism is determined. It becomes easy.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. First, in FIG. 6, the house 1 is provided with a left chamber 2, a hall 3, and a right chamber 4, and the ceiling plate 5 has an opening 5 a located above the hall 3 as shown in FIG. 2. The body frame 6 is inserted into the opening 5a from the hole 3 side. The main body frame 6 has a cylindrical shape, and a hole-shaped main intake port 6a is provided on the lower surface of the main body frame 6, and a hole-shaped exhaust port 6b is formed on the upper surface.
[0015]
A decorative panel 7 is detachably attached to the lower end of the main body frame 6. This decorative panel 7 covers the main air inlet 6a of the main body frame 6 from the hole 3 side, and a rectangular frame hole-shaped intake opening 7a is formed at the peripheral edge of the decorative panel 7. Reference numeral 8 denotes a ceiling behind the main body frame 6.
[0016]
A partition plate 9 is disposed in the main body frame 6. This partition plate 9 divides the inside of the main body frame 6 into a fan storage chamber 10 and an intake chamber 11, and a cylindrical ventilation path 9 a is integrally formed at a substantially central portion of the partition plate 9. The damper 12 is housed so as to be rotatable about a shaft 12a.
[0017]
A damper motor 13 is fixed to the outer surface of the ventilation path 9a. A shaft 12a of the damper 12 is connected to a rotation shaft (not shown) of the damper motor 13, and when the damper motor 13 is operated, the damper 12 rotates about the shaft 12a. Reference numeral 14 denotes a damper mechanism (corresponding to a ventilation control mechanism) composed of the damper 12 and the damper motor 13.
[0018]
Hole-shaped auxiliary intake ports 6 c and 6 c are formed at the lower end of the main body frame 6. A cylindrical intake port body 15 is fixed to the peripheral portion of each auxiliary intake port 6 c, and one end portion of the intake duct 16 is connected to the outer peripheral surface of each intake port body 15. The ceiling plate 5 is formed with two openings 5b. Of these, one opening 5b is located above the left chamber 2, the other opening 5b is located above the right chamber 4, and the other end of each intake duct 16 is inserted into the opening 5b. ing. Each intake duct 16 is constituted by a flexible duct.
[0019]
An air intake grille 17 is detachably mounted on the ceiling plate 5 in the left chamber 2 and the right chamber 4. Each of the intake grilles 17 has a rectangular frame hole-like intake opening portion 17a at the peripheral portion. One intake grille 17 covers one intake duct 16 from the left chamber 2 side, and the other intake grille 17 The other intake duct 16 is covered from the right chamber 4 side.
[0020]
A motor mounting base 18b is disposed in the fan housing chamber 10, and the fan motor 18 is fixed to the motor mounting base 18b. A sirocco fan 19 is fixed to the rotating shaft 18a of the fan motor 18, and when the fan motor 18 operates, the sirocco fan 19 rotates. Reference numeral 20 denotes a fan mechanism (corresponding to an air volume control mechanism) composed of a fan motor 18 and a sirocco fan 19.
[0021]
A fan casing 21 surrounding the fan 19 is disposed in the fan storage chamber 10, and when the fan 19 rotates in the open state of the ventilation path 9 a, the air in the hole 3 becomes the intake opening 7 a of the decorative panel 7. Then, the air is sucked into the intake chamber 11, the ventilation path 9 a, and the fan casing 21 through the main intake port 6 a of the main body frame 6. At the same time, the air in the left ventricle 2 and the air in the right ventricle 4 pass through the intake duct 16 and the auxiliary intake port 6c of the main body frame 6 from the intake opening 17a of the intake grille 17 in the intake chamber 11, the ventilation path 9a, It is sucked into the fan casing 21.
[0022]
A cylindrical exhaust port body 22 is fixed to the upper surface of the main body frame 6 so as to be positioned at the peripheral edge of the exhaust port 6b. A lower end portion of an exhaust duct 23 is connected to the outer peripheral surface of the exhaust port body 22, and an exhaust tower 24 is attached to the upper end portion of the exhaust duct 23 as shown in FIG. The exhaust duct 23 is a flexible duct, and the air sucked into the fan casing 21 is discharged to the outside from the exhaust port 6 b of the main body frame 6 through the exhaust duct 23 and the exhaust tower 24. In addition, the arrow of FIG. 6 has shown the flow of the wind.
[0023]
As shown in FIG. 3, the partition plate 9 is integrally formed with a first insertion port 9b. The insertion port 9 b has a cylindrical shape. The lower end of the insertion port 9 b is located in the intake chamber 11, and the upper end is located in the fan storage chamber 10. Moreover, the 2nd insertion port 9c is integrally formed by the ventilation path 9a. The insertion port 9 c has a cylindrical shape, and the left end portion of the insertion port 9 c is located in the ventilation path 9 a and the right end portion is located in the fan storage chamber 10.
[0024]
The lower end portion of the first air tube 25 is connected to the upper end portion of the first insertion port 9b, and the left end portion of the second air tube 26 is connected to the right end portion of the second insertion port 9c. Yes. Further, a differential pressure sensor 27 is disposed in the fan storage chamber 10. The differential pressure sensor 27 corresponds to an air volume detecting means, and the upper end portion of the first air tube 25 and the right end portion of the second air tube 26 are both connected to the differential pressure sensor 27.
[0025]
As shown in FIG. 4, the differential pressure sensor 27 mainly includes a first pressure sensor 27 a, a second pressure sensor 27 b, and an arithmetic circuit 27 c, and the first pressure sensor 27 a is the intake chamber 11. Is detected through the first air tube 25, and a pressure signal having a voltage level corresponding to the detected pressure is output. The second pressure sensor 27b detects the internal pressure of the ventilation path 9a through the second air tube 26, and outputs a pressure signal having a voltage level corresponding to the detected pressure.
[0026]
The arithmetic circuit 27c is electrically connected to the output side of the first pressure sensor 27a and the second pressure sensor 27b, and the pressure signal from the first pressure sensor 27a and the second pressure sensor 27b A differential pressure signal “V” having a voltage level corresponding to the difference from the pressure signal is output. The first differential pressure sensor 27a and the second differential pressure sensor 27b are semiconductor pressure sensors.
[0027]
As shown in FIG. 2, a circuit box 28 is disposed in the fan storage chamber 10, and a control device 29 corresponding to correction means is stored in the circuit box 28 as shown in FIG. ing. The control device 29 includes a CPU 29a, a ROM 29b corresponding to the storage means, an EEPROM 29c corresponding to the storage means, a RAM 29d, an input interface 29e, an output interface 29f and the like (consisting mainly of a microcomputer). The differential pressure “P” between the internal pressure of the ventilation path 9 a and the internal pressure of the intake chamber 11 is calculated based on the differential pressure signal “V” of the differential pressure sensor 27.
[0028]
The damper motor 13 is connected to the output interface 29f of the control device 29 via the damper motor drive circuit 30. The control device 29 controls the position of the damper motor 13 through the damper motor drive circuit 30, and the damper 12 is shown as a solid line in FIG. Is rotated between a fully open position (90 ° rotation position) indicated by (2) and a fully closed position (0 ° rotation position) indicated by a two-dot chain line to open and close the ventilation path 9a.
[0029]
As shown in FIG. 4, the fan motor 18 is connected to the output interface 29 f of the control device 29 via the fan motor drive circuit 31, and the control device 29 drives and controls the fan motor 18 through the fan motor drive circuit 31. As a result, the rotation speed of the fan 19 is adjusted in three stages: “strong”, “medium”, and “weak”.
[0030]
A test switch 32 is connected to the input interface 29e of the control device 29. The control device 29 sets a test mode based on detecting the operation of the test switch 32, and the damper mechanism 14 operates normally. Test whether The LED 34 is connected to the output interface 29 f of the control device 29 via the LED drive circuit 33. The LED 34 corresponds to a notification unit, and the control device 29 turns on the LED 34 when the test result of the damper mechanism 14 is abnormal, and notifies the user of the abnormality.
[0031]
Next, the operation of the above configuration will be described. The following operation is executed by the control device 29 based on an operation control program stored in advance in the ROM 29b. The EEPROM 29c functions as a storage location for the zero point data of the differential pressure sensor 27, and the RAM 29d serves as a work area. Function.
[0032]
When the power is turned on, the control device 29 proceeds to step S1 in FIG. 1, reads the initial differential pressure signal “Va” from the ROM 29b, and writes it into the RAM 29d. Then, the process proceeds to step S2, and the inclination data “k” is read from the ROM 29b and written to the RAM 29d. The initial differential pressure signal “Va” and the slope data “k” are stored in the ROM 29b in advance, and the initial differential pressure signal “Va” is the initial differential pressure that is not affected by temperature or aging. It is output from the sensor 27.
[0033]
As shown in FIG. 5, the inclination data “k” is an experiment of “a differential pressure signal V of the differential pressure sensor 27 / a differential pressure P between the internal pressure of the ventilation passage 9a and the internal pressure of the intake chamber 11 (unit: mmH 2 O)”. When the controller 29 reads the inclination data “k”, the process proceeds to step S3 in FIG.
[0034]
When the control device 29 proceeds to step S3, it turns off the fan motor 18 and proceeds to step S4. Then, the damper motor 13 is driven and controlled, and as shown by a two-dot chain line in FIG. 3, the damper 12 is fully closed, and the process proceeds to step S5 in FIG.
[0035]
When the control device 29 proceeds to step S5, it detects the differential pressure signal “V” of the differential pressure sensor 27 and writes it to the RAM 29d. Then, the process proceeds to step S6, and the differential pressure signal “V” detected in step S5 is compared with “Va + ΔVa”. Note that “ΔVa” is stored in advance in the ROM 29b, and indicates an allowable value of the initial differential pressure signal “Va”.
[0036]
When detecting “V ≦ Va + ΔVa” in step S6, the control device 29 proceeds to step S7. Then, “differential pressure signal V → V0” is executed and written to the EEPROM 29c, and then the process proceeds to step S8. If “V> Va + ΔVa” is detected in step S6, the process proceeds to step S9, “initial differential pressure signal Va → V0” is executed and written to the EEPROM 29c, and then the process proceeds to step S8.
[0037]
When the process proceeds to step S8, the control device 29 drives and controls the damper motor 13, and rotates the damper 12 to the fully open state as shown by the solid line in FIG. Then, the process proceeds to step S10 in FIG. 1, the power is supplied to the fan motor 18, and the fan 19 is rotated at the speed “medium”. Then, the air in the left chamber 2, the hall 3, and the right chamber 4 is exhausted to the outside through the exhaust duct 24 from the ventilation path 9a, and the forced ventilation operation is started.
[0038]
When the forced ventilation operation is started, the control device 29 proceeds to step S <b> 11 and detects the differential pressure signal “V” of the differential pressure sensor 27. Then, the process proceeds to step S12 to execute “differential pressure signal V → V1”. Thereafter, the process proceeds to step S13 to execute “V1−V0 → V2”, and the process proceeds to step S14. Here, with the calculation of “k × V 2 → P (mmH 2 O)”, the voltage increase amount “V 2” is converted into the pressure increase amount “P”, and the process proceeds to step S 15.
[0039]
When the control device 29 proceeds to step S15, it determines “Pc−ΔPc ≦ P ≦ Pc + ΔPc”. “Pc” is a pressure target value stored in advance in the ROM 29b, “ΔPc” is an allowable amount of the pressure target value, and the control device 29 detects exhaust gas when “Pc−ΔPc ≦ P ≦ Pc + ΔPc” is detected in step S15. It is determined that the air volume is an appropriate value, and the process proceeds to step 16.
[0040]
When determining “NO” in step S15, the control device 29 proceeds to step S17. Here, when “Pc−ΔPc> P” is detected, the process proceeds to step S18, and the rotational speed of the fan motor 18 is switched to “fast”. And after increasing exhaust air volume, it transfers to step S16. If “NO” is determined in the step S17, the process proceeds to a step S19. Then, after the rotational speed of the fan motor 18 is switched to “slow” and the exhaust amount is reduced, the routine proceeds to step 16.
[0041]
When the process proceeds to step S16, the control device 29 determines whether or not a time “T (for example, 4 hours)” has elapsed since the fan motor 18 was turned on in step S10. This time “T” is stored in advance in the ROM 28b, and when the control device 29 determines that the time “T” has not elapsed, the control device 29 proceeds to step S20 and determines whether the test mode is set. .
[0042]
The test mode is set based on the fact that the control device 29 detects the operation of the test switch 32 in the interrupt routine. When the control device 29 determines in step S20 that the test mode is not set, the step S11 is performed. To return to step S11 to S20. Then, the differential pressure “P” is detected based on the differential pressure signal “V” of the differential pressure sensor 27, and the fan motor 18 is driven and controlled in accordance with the comparison result between the differential pressure “P” and the target value “Pc”. .
[0043]
When the control device 29 detects the setting of the test mode in step S20, the control device 29 proceeds to step S21 and rotates the damper 12 to the fully closed state. Then, the process proceeds to step S22, the differential pressure signal “V” of the differential pressure sensor 27 is detected, and the process proceeds to step S23. Here, after “differential pressure signal V → Vt” is executed, the process proceeds to step S24 to determine “V1−Vt> V3”. "V3" is a judgment value stored in advance in the ROM 28b.
[0044]
When detecting “V1−Vt> V3” in step S24, the control device 29 determines that the damper 12 is normally opened and closed, and proceeds to step S25. Then, the setting of the test mode is canceled and the process returns to step S11. If “V1−Vt ≦ V3” is detected in step S24, it is determined that the damper 12 is not normally opened and closed, and the process proceeds to step S26. Here, after the setting of the test mode is canceled and the abnormal mode is set, the process proceeds to step S27, the LED 34 is turned on, and the process returns to step S11.
[0045]
When the control device 29 detects that the time “T” has elapsed in step S16, the control device 29 proceeds to step S28 and determines “P> Pd”. This “Pd” is a determination value stored in advance in the ROM 28b, and when “P> Pd” is detected, the control device 29 proceeds to step S20 and detects whether the test mode is set. If "YES" is determined here, steps S21 to S24 are executed. If an abnormality is detected, the LED 34 is turned on in step S27.
[0046]
When detecting “P ≦ Pd” in step S28, the control device 29 returns to step S3 to turn off the fan motor 18, and proceeds to step S4 to rotate the damper 12 to the fully closed state. Thereafter, the process proceeds to step S5, where the differential pressure signal “V” of the differential pressure sensor 27 is detected, and “differential pressure signal V → V0” of step S7 is selectively executed according to the comparison result of step S6.
[0047]
In FIG. 5, α is a change in the initial differential pressure signal “V”, and β and γ are experimental changes in the differential pressure signal “V” when the differential pressure sensor 27 changes over time or is affected by the ambient temperature. The differential pressure signal “V” moves in parallel along the V axis due to the influence of secular change or the like. On the other hand, in the above embodiment, the differential pressure signal “V” in the ventilation state is subtracted from the differential pressure signal “V” in the ventilation state of the differential pressure sensor 27 to correct the differential pressure signal “V” in the ventilation state. Therefore (step S13), the air volume (differential pressure “P”) in the ventilation path 9a is accurately detected without being affected by the ambient temperature of the differential pressure sensor 27 and the secular change.
[0048]
The differential pressure signal “V” in the ventilation state of the differential pressure sensor 27 refers to the differential pressure signal “V” output from the differential pressure sensor 27 when the damper 12 is fully opened. Further, the differential pressure signal “V” when the differential pressure sensor 27 is in the non-ventilated state refers to the differential pressure signal “V” output from the differential pressure sensor 27 when the damper 12 is fully closed.
[0049]
Further, when the differential pressure signal “V” in the non-ventilated state of the differential pressure sensor 27 is detected, the fan 19 is set to the non-rotating state (step S3). For this reason, since the differential pressure signal “V” including the forced exhaust flow is prevented from being used for correction, the air volume in the ventilation path 9a is detected more accurately.
[0050]
Further, the differential pressure signal “V” in the non-ventilated state of the differential pressure sensor 27 is updated every predetermined time “T”. For this reason, since the differential pressure signal “V” in the ventilation state can be corrected based on the latest differential pressure signal “V” in the non-ventilation state, the air volume in the ventilation path 9a can be detected more accurately from this point. Is done.
[0051]
When the pressure difference between the inside and outside of the left chamber 2, the hall 3, and the right chamber 4 is large and the differential pressure “P” when the ventilation path 9a is open exceeds a predetermined value, the fan 19 stops rotating and the damper 12 Even if is closed, there is a possibility that air leaks from between the inner peripheral surface of the ventilation path 9a and the damper 12. In contrast, in the above-described embodiment, only when the differential pressure “P” in the ventilation state of the differential pressure sensor 27 is equal to or less than the predetermined value “Pd” (step S28), the differential pressure signal “V” in the non-ventilation state. Was updated. For this reason, since the differential pressure signal “V” including the air leakage described above is prevented from being used for correction, the air volume in the ventilation path 9a is detected more accurately from this point.
[0052]
Further, when the difference between the differential pressure signal “V” in the non-ventilated state of the differential pressure sensor 27 and the initial output signal “Va” of the ROM 29b is a predetermined value or more, the differential pressure signal “V” in the non-ventilated state is Invalidated (steps S6 and S9). For this reason, when the above-described air leakage is included in the differential pressure signal “V”, the difference between the differential pressure signal “V” and the initial output signal “Va” becomes a predetermined value or more, and the differential pressure signal “V”. "Is prevented from being used for correction, the air volume in the ventilation path 9a can be detected more accurately also from this point.
[0053]
Further, since the differential pressure signal “V” in the non-ventilated state of the differential pressure sensor 27 is compared with the differential pressure signal “V” in the ventilated state (step S24), the damper mechanism is based on the small difference between the two. 14 malfunctions can be detected. Moreover, the differential pressure signal “V” in the forced ventilation state is used to detect malfunction of the damper mechanism 14. For this reason, since the difference between the differential pressure signal “V” in the ventilation state and the differential pressure signal “V” in the non-ventilation state becomes large, it becomes easy to determine the malfunction and normal operation of the damper mechanism 14.
[0054]
In addition, since the malfunction of the damper mechanism 14 is notified based on the lighting of the LED 34, the user can take an abnormal measure such as replacing or repairing the damper mechanism 14.
[0055]
In the first embodiment, the differential pressure signal “V” in the non-ventilated state of the differential pressure sensor 27 is compared with the initial output signal “Va” of the ROM 29b. However, the present invention is not limited to this. The differential pressure signal “V” in the non-ventilated state may be compared with the differential pressure signal “V” in the previous non-ventilated state. In this case, when the difference between the differential pressure signals “V” is equal to or greater than a predetermined value once or a plurality of times, the zero point is rewritten based on the latest differential pressure signal “V” (“differential pressure signal V → V0 ") should not be performed.
[0056]
In the first embodiment, the initial output signal “Va” of the differential pressure sensor 27 is stored in the ROM 29b in advance. However, the present invention is not limited to this. For example, the initial output signal “Va” is stored in the EEPROM 29c in advance. It is good also as a structure to keep.
[0057]
Next, a second embodiment of the present invention will be described with reference to FIG. When the power is turned on, the control device 29 proceeds to step S31, rotates the damper 12 to the fully closed state, and closes the ventilation path 9a. Then, the process proceeds to step S32, and after detecting the differential pressure signal “V” of the differential pressure sensor 27, the process proceeds to step S33, “differential pressure signal V → V0” is executed and written to the EEPROM 29c, and the process proceeds to step S34. To do.
[0058]
When the control device 29 proceeds to step S34, the control device 29 rotates the damper 12 to the fully open position, and proceeds to step S35. Then, the air in the left chamber 2, the hall 3, and the right chamber 4 is discharged to the outside through the ventilation path 9a, the fan casing 21, and the exhaust duct 23 due to the pressure difference between the inside and outside, and the natural ventilation operation is started.
[0059]
When the control device 29 proceeds to step S35, it detects the differential pressure signal “V” of the differential pressure sensor 27, proceeds to step S36, executes “differential pressure signal V → V1”, and then proceeds to step S37. . Here, "V1 -V0.fwdarw.V2" is executed, the process proceeds to step S38, and "Vd-.DELTA.Vd.ltoreq.V2.ltoreq.Vd + .DELTA.Vd" is determined. “Vd” is a target value stored in advance in the ROM 28b, “ΔVd” is an allowable value of “Vd”, and when the control device 29 detects “Vd−ΔVd ≦ V2 ≦ Vd + ΔVd” in step S38, natural exhaust is performed. It is determined that the amount is an appropriate value, and the process proceeds to step 39.
[0060]
When determining “NO” in step S38, the control device 29 proceeds to step S40. If "Vd-.DELTA.Vd> V2" is detected, the process proceeds to step S41 to supply power to the fan motor 18. Then, the fan 19 is rotated to forcibly exhaust the air in the left chamber 2, the hall 3, and the right chamber 4, thereby increasing the exhaust air volume. If “Vd + ΔVd <V2” is detected in step S40, “NO” is determined, and the process proceeds to step S42. Here, the damper 12 is rotated by a predetermined amount (for example, 15 °) to reduce the opening amount of the ventilation path 9a. Then, after reducing the exhaust air volume, the process proceeds to step S39.
[0061]
When the control device 29 proceeds to step S39, it determines whether or not the time “T” has elapsed since the damper 12 was fully opened in step S34. If "NO" is determined here, the process returns to step S34, and steps S34 to S42 are repeated. Then, the air volume is adjusted according to the comparison result between the differential pressure signal “V” of the differential pressure sensor 27 and the target value “Vd”.
[0062]
When the control device 29 detects the elapse of time “T” in step S39, the control device 29 proceeds to step S43 and rotates the damper 12 to the fully closed state. Then, the process proceeds to step S44, the differential pressure signal “V” of the differential pressure sensor 27 is detected, and the process proceeds to step S45.
[0063]
When the control device 29 proceeds to step S45, it executes “differential pressure signal V → Vz” and writes it in the EEPRM 29c, and then proceeds to step S46 to determine “V2−Vz <Vf”. This “Vf” is a determination value stored in advance in the ROM 29b. When the control device 29 detects “V2−Vz ≧ Vf” in step S46, it determines that the damper 12 is normally opened and closed. The process returns to step S34. If “V2−Vz <Vf” is detected in step S46, the process proceeds to step S47.
[0064]
When the control device 29 proceeds to step S47, it determines “V2> Ve”. This “Ve” is a determination value stored in advance in the ROM 29b, and when the control device 29 detects “V2 ≦ Ve”, it returns to step S34. If “V2> Ve” is detected in step S47, the process proceeds to step S48 to turn on the LED 34 to notify that the damper 12 is not normally opened and closed, and the process returns to step S34.
[0065]
According to the above embodiment, the differential pressure signal “V” in the ventilation state of the differential pressure sensor 27 is compared with the determination value “Ve” (step S47). Therefore, when the air volume in the ventilation state is very small and the difference between the differential pressure signal “V” in the non-ventilation state and the differential pressure signal “V” in the ventilation state is small, the malfunction of the damper mechanism 14 is determined to be step S46. Is prevented from being erroneously detected.
[0066]
When the air volume in the ventilation path 9a is large, the fan mechanism 20 is stopped and the damper mechanism 14 is opened to naturally exhaust indoor air. For this reason, since it is not necessary to always operate the fan mechanism 20, the power consumption is reduced. A reference numeral 36 in FIG. 1 indicates an air volume control mechanism including the damper mechanism 1 and the fan mechanism 20.
[0067]
Next, a third embodiment of the present invention will be described with reference to FIG. A protruding plate-like stopper 9d is integrally formed on the inner peripheral surface of the ventilation path 9a, and the damper 12 is held in a fully closed state based on contact with the stopper 9d. For this reason, it is possible to prevent an air leak from occurring between the ventilation path 9a and the damper 12 that would hinder the update of the zero point of the differential pressure sensor 27 without paying attention to the machining accuracy of the ventilation path 9a and the damper 12. Is done.
[0068]
Next, a fourth embodiment of the present invention will be described with reference to FIG. A partition plate 9e is disposed in the ventilation path 9a. The partition plate 9e defines another ventilation path 9f in the ventilation path 9a. The damper 12 is housed in the ventilation path 9f so as to be rotatable about the shaft 12a. Is connected to the rotating shaft of the damper motor 13.
[0069]
The control device 29 executes the operation control program of FIG. 1 based on the differential pressure signal “V” of the differential pressure sensor 27. This differential pressure signal “V” indicates the difference between the internal pressure of the ventilation passage 9f and the internal pressure of the intake chamber 11, and the air in the left chamber 2, the hall 3, and the right chamber 4 is forced to the outside through the ventilation passage 9a. To be discharged.
[0070]
Next, a fifth embodiment of the present invention will be described with reference to FIG. A thermistor wind speed sensor 35 corresponding to an air volume sensor is fixed to the peripheral wall of the ventilation path 9a. This air speed sensor 35 uses the thermistor characteristic that the amount of heat radiation on the surface changes according to the air volume in the ventilation path 9a, and outputs an air volume signal “V” at a voltage level corresponding to the air volume in the ventilation path 9a. To do.
[0071]
According to the above embodiment, the control device 29 executes the operation control program of FIG. 1 or the operation control program of FIG. 2 using the air volume signal “V” of the air speed sensor 35, and the left chamber 2, hall 3, right chamber The air in 4 is forcibly exhausted from the air passage 9a or naturally exhausted.
[0072]
In the first to fifth embodiments, the LED 34 is turned on in accordance with the abnormality detection of the damper mechanism 14, but the present invention is not limited to this. For example, an abnormality message is displayed on the display device or a buzzer is turned on. You may make it ring.
Moreover, in the said 1st-5th Example, although this invention was applied to the ventilator which discharges inside air to the outdoors, it is not limited to this, For example, indoor air is ventilated to another room The present invention may be applied to a blower or an intake device that sucks outside air into the room.
[0073]
【The invention's effect】
  As is clear from the above description, the ventilation device of the present invention has the following effects.
  Claim1According to the means described,Arithmetic circuitIn ventilationDifferential pressure signalIn a non-ventilated stateDifferential pressure signalBecause it was corrected based onDifferential pressure signal of arithmetic circuitEven if drift occurs due to the influence of ambient temperature and aging, the air volume can be detected accurately.
  According to the first aspect of the present invention, since the fan mechanism and the damper mechanism are driven and controlled based on the detection result of the air volume, when the air volume is large, the fan mechanism is stopped and the damper mechanism is opened, Can be exhausted naturally. For this reason, since it is not necessary to always operate a fan mechanism, power consumption is reduced.
[0074]
  Claim1According to the means described,Arithmetic circuitIn ventilationDifferential pressure signalIn a non-ventilated state whenDifferential pressure signalUpdated. This included air leakageDifferential pressure signalIs prevented from being used for correction, so that the air volume can be detected more accurately.
[0075]
  Claim1According to the means described, Arithmetic circuitIn ventilationDifferential pressure signalIn a non-ventilated state whenDifferential pressure signalWas not updated. Therefore, in the latest non-ventilated state that does not include air leakageDifferential pressure signalBased on ventilationDifferential pressure signalTherefore, the air volume can be detected more accurately.
  Claim1According to the means described,The differential pressure signal in the non-ventilated state based on the difference between the differential pressure signal in the non-ventilated state of the arithmetic circuit and the initial differential pressure signal plus the allowable valueWas disabled. This included air leakageDifferential pressure signalIs prevented from being used for correction, so that the air volume is detected more accurately.
[0076]
  Claim2According to the means described,Arithmetic circuitDifferential pressure in non-ventilated statesignalAnd in ventilationDifferential pressure signalAnd comparedDamper mechanismCan be detected.In addition, since the differential pressure signal at the time of forced ventilation is used, the difference between the differential pressure signal in the ventilation state and the differential pressure signal in the non-ventilation state becomes large, and it becomes easy to determine the malfunction of the damper mechanism.
[Brief description of the drawings]
FIG. 1 is a diagram showing a first embodiment of the present invention (flow chart showing control contents of a control device);
FIG. 2 is a cross-sectional view showing the overall configuration
FIG. 3 is an enlarged cross-sectional view showing a ventilation passage portion.
FIG. 4 is a block diagram schematically showing an electrical configuration.
FIG. 5 is a diagram showing an output signal from a differential pressure sensor
FIG. 6 is a diagram showing the installation state of the ventilation device
FIG. 7 is a diagram showing a second embodiment of the present invention (flow chart showing control contents of the control device);
FIG. 8 is a diagram showing a third embodiment of the present invention (a cross-sectional view showing an enlarged ventilation passage portion);
FIG. 9 is a view showing a fourth embodiment of the present invention (a cross-sectional view showing an enlarged ventilation passage portion);
FIG. 10 is a view showing a fifth embodiment of the present invention (a cross-sectional view showing an enlarged ventilation passage portion);
[Explanation of symbols]
6 is a main body frame, 6a is a main intake port (intake port), 6b is an exhaust port, 6c is an auxiliary intake port (intake port), 9a is a ventilation path, 14 is a damper mechanism (ventilation control mechanism), and 20 is a fan mechanism ( (Air volume control mechanism), 27 is a differential pressure sensor (air volume detection means), 29 is a control device (correction means), 29b is ROM (storage means), 29c is EEPROM (storage means), 34 is LED (notification means), 35 Is a thermistor wind speed sensor (air volume detecting means), and 36 is an air volume control mechanism.

Claims (2)

A body frame installed on the ceiling of the house ;
An air passage provided inside the main body frame and interconnecting an intake chamber inside the main body frame and a fan storage chamber located above the intake chamber;
A fan mechanism that is provided in the fan storage chamber and exhausts the air inside the house from the fan storage chamber through the intake chamber and the ventilation path in order;
A damper mechanism provided inside the ventilation path so as to be rotatable between a horizontal fully closed state and a vertical fully opened state, and a damper motor for rotating the damper between the fully closed state and the fully opened state; ,
A first pressure sensor that detects an internal pressure of the intake chamber, a second pressure sensor that detects an internal pressure of the ventilation path, a detection result of the first pressure sensor, and a detection result of the second pressure sensor. An arithmetic circuit that outputs a differential pressure signal at a voltage level corresponding to the differential pressure, and a storage means in which an initial differential pressure signal and an allowable value of the initial differential pressure signal are recorded, each of the fan mechanism and the damper mechanism Equipped with a control device for controlling the drive,
When the differential pressure signal output from the arithmetic circuit in a state where the damper is fully opened and the fan mechanism is turned on is less than or equal to a predetermined value,
Detecting a differential pressure signal output from the arithmetic circuit in a state where the fan mechanism is turned off and the damper is fully closed;
The detected differential pressure signal is compared with the added value of the initial differential pressure signal and the allowable value stored in the storage means, and the detected differential pressure signal is less than the added value of the initial differential pressure signal and the allowed value. In some cases, the detected differential pressure signal is stored, and the number of rotations of the fan mechanism is controlled according to the comparison result between the differential pressure signal output from the arithmetic circuit and the stored differential pressure signal, and the detected differential pressure is detected. When the signal is larger than the sum of the initial differential pressure signal and the allowable value, the rotational speed of the fan mechanism is controlled according to the comparison result between the differential pressure signal output from the arithmetic circuit and the initial differential pressure signal. Ventilating device. The controller is
When the test mode is set, the damper is fully closed while the fan mechanism is on,
A differential pressure signal output from the arithmetic circuit when the damper is fully closed when the fan mechanism is on and a differential pressure signal output from the arithmetic circuit when the damper is fully opened when the fan mechanism is on The ventilator according to claim 1, wherein the presence or absence of abnormality is detected based on a comparison between the difference between the difference and a determination value stored in advance.

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