JP5292915B2 - Ventilation equipment - Google Patents

Description

  The present invention relates to a ventilator that ventilates a ventilated room such as a vehicle interior of a vehicle, and more particularly, to a ventilator that operates by power generated by a solar cell.

  Electric power can be obtained by a solar cell in the sun or the like with strong sunlight. In addition, if the vehicle is parked under hot weather, the temperature in the passenger compartment increases, which may cause discomfort when an occupant gets on the vehicle. From here, the proposal of the ventilator which ventilates a vehicle interior using the generated electric power of a solar cell has been made.

  As a ventilator that ventilates a ventilated room such as a passenger compartment using the generated power of the solar cell, when driving a plurality of fans with the generated power of the solar cell, the operating point in the voltage-current characteristics of the solar cell, A proposal has been made to drive the number of fans set so that the air volume at the predetermined static pressure value is maximized from the air volume-static pressure characteristics when the predetermined number of fans are driven at the operating point (for example, Patent Documents). 1).

  In addition, when ventilating and air-conditioning the vehicle interior using solar cells, the vehicle interior is divided into a plurality of areas, the air conditioning state for each divided area can be controlled, the solar radiation direction is detected, and the detected solar radiation direction The proposal which controls the air-conditioning state of each area | region based on this is made | formed (for example, refer patent document 2).

  By the way, in the solar cell, the generated power is reduced due to a decrease in the amount of solar radiation, and the ventilation device stops the ventilation fan when the generated power becomes a predetermined value or less.

On the other hand, in a ventilator using a solar cell, the current value is detected when a ventilation fan is operated using a current sensor or the like, and the generated power is determined to reduce the cost. be able to. In such a ventilator, when the generated power of the solar cell is lowered and the fan is stopped, for example, the fan is driven at a certain time interval to measure the current value, and the power generation of the solar cell The state (generated power) is judged. As a result, when it is determined that the generated power of the solar cell is equal to or greater than a predetermined value, the fan is continuously driven to ventilate the passenger compartment.
JP-A-5-238250 JP 2004-291680 A

  However, the generated power of the solar cell is affected by the inclination (time) of the sun and the weather, and the generated power is reduced when the sun is shaded even if temporarily. At this time, if it is temporarily shaded by the sun, the number of times the fan is driven is small, but at sunset, etc., the fan is intermittently driven repeatedly, resulting in a decrease in durability of the fan motor. May occur.

  In order to prevent this, if the drive interval of the ventilation fan is lengthened, the state where the ventilation fan is not driven continues even though the solar radiation is recovered and the generated power is increased.

  The present invention has been made in view of the above-described facts. When a power generation state of a solar cell is determined with a simple configuration and a ventilated room such as a vehicle interior is ventilated using the solar cell, a fan motor or the like is used. It aims at providing the ventilator which can suppress intermittent drive.

To accomplish the above object, a current detecting means for detecting a row U換 air fan ventilation operating the ventilation chamber by the electric power generated by the solar battery, the current value during operation of the ventilation fan, said storage means the current value corresponding to the generated power of the solar cell definitive the insolation criteria requiring ventilation of the ventilation chamber and stored as a reference value, and more said detected current value to the current detecting means If There is more than before Symbol reference value, performs a ventilation of the object to be ventilated chamber by operating the ventilation fan by generated power of the solar cell, the current value during operation of the ventilation fan is smaller than the reference value If the state has continued for a predetermined time or more, when the ventilation driving means for stopping the operation of the ventilation fan, said current value detected by said detecting means is less than the reference value, based on the current value, the The current value is Time setting means for setting the stop time of the ventilating fan so long as have, during the stop of the ventilation fan, in order to perform the detection of I Ri said current value to said current detecting means, said time setting means and intermittent drive means causes create dynamic the ventilation fan at set intervals of the stop time by including.

According to this invention, the generated power of the solar cell that changes depending on the amount of solar radiation is determined by the current value detected by the current detection means in a state where the ventilation fan is operated. The reference value, the amount of solar radiation when it is determined that the required ventilation of the ventilation chamber as a reference is set based on the generated power in the solar radiation amount.

Time setting means, based on the current value of when stopping the ventilating fan to the current value does not reach the reference value, sets a stop time for intermittently driving the ventilation fan. Intermittent driving means, the downtime of the ventilation fans, each time reaching the stop time, activate the ventilation fan in order to detect the current value, it is determined whether or not the current value has reached a reference value To be done .

Based on the current value detected by the current detection means , the time setting means sets the stop time to become longer as the current value becomes smaller. That is, the stop time is set longer as the amount of solar radiation is smaller.

  Thereby, when the amount of solar radiation falls and a ventilation fan is operated intermittently, since the frequency | count of operation of a ventilation fan can be suppressed, so that the amount of solar radiation is low, the lifetime reduction of a ventilation fan can be suppressed.

In the present invention, comprises a time storage means for storing a stop time set in correspondence to the current value more is detected in said current detecting means, said time setting unit, as the stop time, the current it is preferable to set a stop time stored in the time storage unit-out based on the value, which makes it easy to set the precise downtime.

The invention according to claim 3, in the storage means, based Ku first reference value generated power in the solar radiation amount of the reference, and rather based on the generated power in a given amount of solar radiation is less than the amount of solar radiation of the reference The second reference value is stored , and the first storage time and the second stop time longer than the first stop time are preset and stored in the time storage unit as the stop time , time setting means, the can before and SL current value Ru said first reference value less than a and the second reference value or more der, setting the first stop time as the stop time in the intermittent drive means and, the current value can and the Ru second reference below values der, sets the second stop time as a stop time in the intermittent drive means.

In the invention according to claim 4, the second reference value is set on the basis of the generated power ¼ of the generated power at the reference solar radiation amount .

  According to the present invention, the first stop time for the first reference value and the second stop time for the second reference value are set together with the first reference value and the second reference value.

  Generally, a temporary decrease in the amount of solar radiation blocked by clouds or the like is less likely to be 1/3 to 1/4 or less because the surroundings are bright. On the other hand, in the evening or the like, the surroundings also become dark, so the amount of solar radiation is greatly reduced.

Here, the reference value based on the generated power in the solar radiation amount of the reference to the first reference value, and a second reference value, for example, the generated power in the solar radiation amount of generated power reference of the solar cell 1 / A current value at 4 is set, and when the detected current value does not satisfy the second reference value, the stop time is set to a second stop time longer than the first stop time.

  As a result, when the possibility of increasing solar radiation is low, such as in the evening, it is possible to extend the stop time and ensure the frequency of operation of the ventilation fan compared to the case where it can be determined that the amount of solar radiation is temporarily reduced. Can be suppressed.

As described above, according to the present invention, when the amount of solar radiation is less than the amount of solar radiation that requires ventilation, since the stop time is set longer according to the decrease in the amount of solar radiation, when the amount of solar radiation is greatly reduced, The operation frequency of the ventilation fan can be surely suppressed.

Further, in the present invention, when the generated power of the solar cell is less than ¼ of the generated power at the reference solar radiation amount with respect to the generated power at the reference solar radiation amount required for ventilation , for example, Since the fan stop time is set to be long, an excellent effect is obtained in that the number of times the ventilation fan is operated can be surely suppressed when the amount of solar radiation is reduced in the evening.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic configuration of a ventilation device 10 according to the present embodiment. As shown in FIG. 2, the ventilation device 10 is provided in a vehicle 12 such as an automobile, and introduces air outside the vehicle (outside air) into a vehicle compartment 14 that is a ventilated room when the vehicle is parked. In the vehicle 12, the outside air is introduced into the passenger compartment 14, and the air in the passenger compartment 14 is exhausted to the outside of the vehicle through the vent duct 16 and the like, thereby ventilating the passenger compartment 14.

  Thereby, for example, when the vehicle 12 is parked under a hot sun, the temperature in the passenger compartment 14 is prevented from rising, and when the passenger gets into the vehicle 12, the temperature in the passenger compartment 14 increases. It is possible to prevent the discomfort caused by the trouble. In the following description, a vehicle compartment 14 formed in the vehicle 12 will be described as an example of a ventilated room. The ventilation device 10 may be configured by an air conditioner (air conditioner) provided in the vehicle 12.

  As shown in FIG. 1, the ventilator 10 includes a solar cell 18, a ventilation fan 20 driven by the power generated by the solar cell 18, and a controller 22 that controls the operation of the ventilation fan 20. ing.

  The ventilation fan 20 has a general configuration in which a fan (blade, impeller, etc.) 26 (see, for example, FIG. 2) is attached to a fan motor 24. Hereinafter, when the fan motor 24 and the fan 26 are not distinguished, they are collectively referred to as a ventilation fan 20. When an air conditioner is used as the ventilator 10, a blower fan may be applied as the ventilation fan 20 and an air conditioner ECU may be applied as the controller 22. Further, the basic configuration of the ventilator 10 is a known general configuration as long as the air in the passenger compartment 14 can be discharged outside the vehicle while introducing the outside air into the passenger compartment 14 by the ventilation fan 20. The detailed description is omitted here.

  As shown in FIG. 2, the solar cell 18 is installed at a site irradiated with sunlight, such as the upper surface of the roof panel 28 of the vehicle 12. The installation location of the solar cell 18 is not limited to this, and the solar cell 18 is installed in an arbitrary area such as the upper surface of the trunk lid 30 or the surface of the wind glass 32 that is irradiated with sunlight and does not disturb the view of the passenger. Anything is acceptable.

  The solar cell 18 receives sunlight, converts the light energy of the received sunlight into DC power, and outputs it. Note that the solar cell 18 is configured to output a voltage corresponding to the drive voltage of the fan motor 24, and a known general configuration can be applied to the configuration of the solar cell 18.

  As shown in FIG. 1, the solar cell 18 is connected to the controller 22, and the generated power of the solar cell 18 is input to the controller 22. In the solar cell 18, for example, one of a pair of electrodes (for example, the positive electrode side) is connected to the controller 22, and the other electrode (for example, the negative electrode side) is grounded (grounded) to the vehicle body of the vehicle 10 together with the controller 22. Has been.

  The controller 22 is provided with a microcomputer (hereinafter referred to as a microcomputer 34) having a general configuration in which a CPU, a ROM, a RAM, and the like are connected by a bus (all not shown). In addition, the controller 22 includes a power supply circuit 36 that generates DC power of a predetermined voltage (for example, 5 v) used for driving the microcomputer 34 from the power supplied from the solar battery 18. The microcomputer 34 is operated by electric power supplied from the power supply circuit 36.

Thereby, the power generation by the solar battery 18 is started, and the power generated by the solar battery 18 is supplied to the microcomputer 34 via the power supply circuit 36, whereby the microcomputer 34 starts to operate . Further, when the power generation of the solar cell 18 is stopped, the microcomputer 34 stops the operation. That is, the ventilation device 1 0 includes a solar cell 18 becomes operable by start power generation, also stops the particular good Ri work movement of the solar cell 18 stops power generation.

  In the present embodiment, the microcomputer 34 is described as being operated by the generated power of the solar battery 18 as an example. However, the present invention is not limited to this, and the microcomputer 34 is operated by the power of a battery (not shown) provided in the vehicle 12. Any configuration can be applied.

  The controller 22 is provided with a current detection circuit 38 serving as current detection means. The controller 22 is provided with a switch circuit 40. The switch circuit 40 includes, for example, a switching element 42 using a semiconductor switching element such as an FET and a protection diode 44.

The ventilation fan 20 is connected to the switch circuit 40, and the generated power of the solar battery 18 is supplied to the ventilation fan 20 through the current detection circuit 38 and the switch circuit 40.

  A drive control unit 46 is formed in the microcomputer 34, and the switching element 42 is turned on by the drive control unit 46, so that the generated power of the solar cell 18 is supplied to the ventilation fan 20. In addition, the ventilation fan 20 is powered off when the switching element 42 is turned off by the drive control unit 46. At this time, the protection diode 44 prevents the backflow of the current from the ventilation fan 20. In this embodiment, a so-called semiconductor relay such as a semiconductor switching element is used. However, the present invention is not limited to this, and switching means having an arbitrary configuration such as an electromagnetic relay can be applied.

  On the other hand, the ventilation fan 20 is provided with a drive circuit 48 for the fan motor 24, and the generated power of the solar battery 18 is supplied to the fan motor 24 via the drive circuit 48.

  A drive control unit 46 of the microcomputer 34 is connected to the drive circuit 48, and the voltage output from the drive circuit 48 to the fan motor 24 is controlled by the drive control unit 46. Thereby, in the ventilator 10, the on / off and rotation speed of the fan motor 24, that is, the on / off of the ventilation fan 20 and the amount of air blown into the passenger compartment 14 are controlled.

  Note that the rotational speed control of the fan motor 24 (air flow control of the ventilation fan 20) depends on the characteristics of the fan motor 24, such as controlling the duty ratio of the DC voltage output from the drive circuit 48 to the fan motor 24. Any control method may be applied as long as it is configured to be driven at the number of revolutions corresponding to the generated power of the solar cell 18, which increases the amount of solar radiation and increases the temperature in the passenger compartment 14. It becomes possible to increase the amount of ventilation in an easy environment.

  The current detection circuit 38 provided in the controller 22 can detect the current value supplied to the ventilation fan 20 when the ventilation fan 20 is driven by the generated power of the solar battery 18. For example, the current detection circuit 38 may be configured to output a voltage corresponding to a current value, but will be described as a current value I below.

  Incidentally, the microcomputer 34 is provided with a memory 50 serving as a storage unit and a time storage unit, and a comparison determination unit 52 serving as a determination unit. The memory 50 stores a reference value of a preset current value. When the comparison determination unit 52 reads the current value I detected by the current detection circuit 38, the reference stored in the memory 50 is stored. Compare with the value.

  The solar cell 18 increases the generated power when the solar radiation becomes strong (the amount of solar radiation increases). Moreover, in the parked vehicle 12, the temperature in the passenger compartment 14 rises due to strong solar radiation. Further, the life (durability) of the fan motor 24 is reduced due to the longer driving time.

From here, in the ventilation apparatus 10, the lower limit value of the solar radiation amount when operating the ventilation fan 20 is set in consideration of the solar radiation amount and the durability of the ventilation fan 20 (fan motor 24). In the memory 50 of the controller 22, ventilation is performed in a state where the generated power of the solar cell 18 when the amount of solar radiation is the lower limit (for example, 500 w / m ² , hereinafter referred to as generated power A) is obtained. The current value I detected by the current detection circuit 38 when the fan 20 is operating is stored as a reference value Is that is a first reference value.

  The comparison determination unit 52 reads the current value I detected by the current detection circuit 38 at a preset timing, and compares it with the reference value Is stored in the memory 50, whereby the power generation state of the solar cell 18 is It is confirmed whether the power generation state in which the ventilation fan 20 is operated, that is, whether the amount of solar radiation exceeds the amount of solar radiation set to operate the ventilation fan 20 or not.

  When the amount of solar radiation set to operate the ventilation fan 20 has been reached, that is, when the current value I has reached the reference value Is (I ≧ Is), the drive control unit 46 switches the switching element 42. While being turned on, the output of the drive circuit 48 is controlled so that the ventilation fan 20 operates at the number of rotations corresponding to the generated power.

  Further, the drive control unit 46 determines that the current value I is lower than the reference value Is (I <Is) by the comparison determination unit 52, and stops the operation of the ventilation fan 20 when this determination state continues. To do.

  A timer 54 and a time setting unit 56 are formed in the microcomputer 34. When the generated power of the solar battery 18 decreases and the current value I becomes lower than the reference value Is, the drive control unit 46 starts time measurement by the timer 54 and sets a predetermined time (hereinafter, time Δt). If the current value I does not exceed the reference value Is, the ventilation fan 20 is stopped (ventilation stop). That is, when operating the ventilation fan 20, the microcomputer 34 indicates that the current value I is lower than the reference value Is for a time Δt or longer (the power generation state of the solar cell 18 continues to decrease). Then, the operation of the ventilation fan 20 is stopped.

  Further, when the ventilation fan 20 is stopped, the drive control unit 46 of the microcomputer 34 starts measurement of the stop time by the timer 54, and when a preset time (hereinafter referred to as interval time ΔTs) has elapsed, the ventilation fan 20 20 is activated so that the current value I can be detected, and the comparison / determination unit 52 determines the power generation state of the solar cell 18.

  At this time, if the comparison determination unit 52 determines that the current value I exceeds the reference value Is, the drive control unit 46 determines that the solar cell 12 is in a power generation state greater than or equal to the predetermined value, and sets the ventilation fan 20 Operate. Thereby, the ventilation in the passenger compartment 14 is resumed. When it is determined that the current value I has not reached the reference value Is, the drive control unit 46 stops the ventilation fan 20 until the interval time ΔTs has elapsed.

  That is, when the ventilation fan 20 is stopped, the microcomputer 34 operates the ventilation fan 20 at a preset interval time ΔTs to determine the power generation state of the solar cell 18.

  On the other hand, a decrease in the power generation state of the solar cell 18 is caused by the sun rising in the evening in addition to when the sun is blocked by clouds or the like. Here, when the sunlight is blocked by a cloud or the like, the amount of solar radiation is partially reduced, and the surroundings are relatively bright. Therefore, the amount of solar radiation is not greatly reduced. On the other hand, in the evening when the sun leans, the surroundings gradually darken, so the amount of solar radiation is greatly reduced compared to when the sun is temporarily blocked.

  Generally, the amount of solar radiation when the sun is blocked by clouds or the like is relatively bright in the surroundings, so that the generated power does not become 1/3 to 1/4 or less of the generated power A. From here, in the ventilator 10 applied to this embodiment, when the generated power is a solar radiation amount that is ¼ or less of the generated power A, the decrease in the solar radiation amount is not temporary, Judged to be caused by tilting.

In ventilator 10, a current value I detected by operating the ventilation fan 20 when the generated power is a quarter of the generated power A, is set as the reference value I _L to the second reference value Stored in the memory 50. That is, the memory 50, and the reference value Is, a lower reference value I _L than the reference value Is is stored as a reference value of the current I.

The microcomputer 34, the current value I and the reference value Is detected by the current circuit 38, the I _L, reduction of the generated power, becomes higher potential is either temporary generated power, it can be higher in such evening Judgment is made whether the nature is low.

Further, in the ventilator 10, the interval time ΔTs is applied when the generated power is likely to be high (highly likely) and the interval time ΔT ₁ is applied when the power generation amount is low. An interval time ΔT ₂ is set.

The interval time [Delta] T _1, [Delta] T _2, for example, interval [Delta] T ₁ is set as 3min, such interval [Delta] T ₂ is set as 10min interval time [Delta] T ₂ is longer than the interval time [Delta] T ₁ (ΔT ₂ > ΔT ₁ ). The interval times ΔT ₁ and ΔT ₂ are stored in the memory 50 as the interval time ΔTs. The interval times ΔT ₁ and ΔT ₂ are set in consideration of the power generation capability of the solar cell 18, the rating and ventilation capability of the ventilation fan 20, the ease of temperature rise of the passenger compartment 14 due to solar radiation, and the like. The time can be.

The time setting unit 56 provided in the microcomputer 34 sets the interval time ΔTs to the interval time ΔT ₁ or the inter time ΔT ₂ based on the determination result of the comparison determination unit 52. In this case, the time setting unit 56 does not reach the current value I is the reference value _{I L} (I _{<I L)} and sets the interval time .DELTA.Ts the interval time _{ΔT 2 (ΔTs = ΔT 2)} , the current value I is that a higher reference value _{I L (I L ≦ I <} is), sets the interval time .DELTA.Ts the interval time _{ΔT 1 (ΔTs = ΔT 1)} .

  Thereby, in the ventilator 10, when the ventilation fan 20 is stopped because the generated power of the solar cell 18 is reduced, the operating frequency of the ventilation fan 20 for determining the power generation state of the solar cell 18 is reduced. It is trying to be suppressed.

  The ventilation device 10 configured as described above can be operated when an ignition switch (not shown) is turned off in order to park the vehicle 10. The ventilation device 10 is provided with a ventilation switch (not shown), and can be operated when the ventilation switch is turned on while the ignition switch is turned off.

  In the ventilation device 10, power generation of the solar cell 18 is started in a state where ventilation operation is possible, and the generated power of the solar cell 18 is supplied to the microcomputer 34 via the power supply circuit 36, whereby the microcomputer 34. The operation of the microcomputer 34 is stopped when the power generation of the solar battery 18 is stopped.

  Here, when the generated power of the solar battery 18 exceeds the preset generated power A, the microcomputer 34 causes the current value I detected by the current detection circuit 38 to exceed the reference value Is and the ventilation fan 20 operates. Is done. Thereby, the inside of the passenger compartment 14 is ventilated.

  Thus, in the ventilation apparatus 10, since the generated electric power of the solar cell 18 exceeds the preset generated electric power A and it is determined that the inside of the passenger compartment 14 needs to be ventilated, the ventilation fan 20 is operated. The temperature rise in the passenger compartment 14 due to solar radiation can be reliably prevented without operating the ventilation fan 20 to shorten the life of the fan motor 24. Accordingly, since the vehicle is parked under hot weather in summer, the temperature in the passenger compartment 14 is prevented from rising, and discomfort can be prevented from occurring when a passenger gets on the vehicle.

  In the ventilator 10, the power generation state of the solar cell 18 is determined from the current value I detected by the current detection circuit 24. As a result, it is not necessary to provide a solar radiation sensor, and the number of sensors for detecting the power generation state of the solar cell 12 is reduced, thereby simplifying the device and reducing the cost.

  Here, in the ventilation device 10, in order to detect the current value I by the current detection circuit 38 in a state where the ventilation fan 20 is stopped, it is necessary to operate the ventilation fan 38. At this time, if the ventilation fan 20 is operated frequently, the durability of the fan motor 24 will be reduced, such as a reduction in the service life. From here, in the ventilator 10, the operation frequency of the ventilation fan 20 when the generated electric power of the solar cell 18 falls is efficiently suppressed.

  Below, the action | operation of the ventilation fan 20 using the generated electric power of the solar cell 18 in the controller 22 provided in the ventilation apparatus 10 is demonstrated.

  FIG. 3 shows an outline of drive control of the ventilation fan 20 executed by the microcomputer 34. In the ventilation device 10, when the power generation of the solar cell 18 is started, the microcomputer 34 is activated prior to the driving of the ventilation fan 20, and the operation of the microcomputer 34 is stopped by stopping the power generation of the solar cell 18. The flowchart of FIG. 3 is executed at predetermined time intervals when the microcomputer 34 is activated, and ends when the microcomputer 20 is stopped.

  In this flowchart, the power generation state (generated power) of the solar cell 18 is determined in the first step 100. At this time, when it is determined that the generated power of the solar cell 18 exceeds the preset generated power A, in step 102, the switching element 42 is turned on and the operation of the drive circuit 48 is controlled. Thus, the operation of the ventilation fan 20 is started (drive of the fan motor 24 is started). Thereby, ventilation in the passenger compartment 14 is started. The generated power determination process will be described later.

  In the microcomputer 34, when the operation of the ventilation fan 20 is started (during ventilation due to the operation of the ventilation fan 20), the current value I detected by the current detection circuit 38 is read in step 104. It is confirmed whether or not the current value I exceeds the reference value Is. Thus, when the solar cell 18 is in a power generation state exceeding the generated power A and the current value I exceeds the reference value Is (I ≧ Is), an affirmative determination is made in step 106 and the operation of the ventilation fan 20 continues. Is done.

  On the other hand, when the sun's sunlight is blocked by clouds or the sun sets in the evening, the power generated by the solar cell 18 decreases. As a result, when the current value I is lower than the reference value Is (I <Is), a negative determination is made in step 106 and the process proceeds to step 108, the timer 54 is reset / started, and the current value I decreases. Measurement of time T is started.

  Thereafter, in step 110, the current value I detected by the current detection circuit 38 is measured, and it is confirmed whether or not the current value I exceeds the reference value Is (step 112). In step 114, it is confirmed whether or not the time T measured by the timer 54 has reached a preset time Δt.

  Here, for example, before the time T measured by the timer 54 reaches the time Δt, the amount of solar radiation increases, the generated power of the solar cell 18 increases, and the current value I exceeds the reference value Is (I ≧ Is), an affirmative determination is made in step 112. Thereby, the operation of the ventilation fan 20, that is, the ventilation in the passenger compartment 14 is continued.

  In contrast, if the amount of solar radiation does not increase and does not exceed the generated power A and the current value I does not reach the reference value Is even after the time Δt has elapsed, an affirmative determination is made in step 114 and the process proceeds to step 116. Transition. In this step 116, the switching element 42 is turned off and the power supply to the ventilation fan 20 (fan motor 24) is stopped. Thereby, the operation of the ventilation fan 20 is stopped, and the ventilation of the passenger compartment 14 is stopped.

  Thereafter, the microcomputer 34 proceeds to step 100 to determine the power generation state of the solar cell 12, that is, the amount of solar radiation.

  FIG. 4 shows an outline of the generated power determination process executed by moving to step 100.

  In this flowchart, the ventilation fan 20 is driven for a predetermined time in the first step 120, and the current value I is detected by the current detection circuit 38 in step 122 at this time. In addition, the drive time of the ventilation fan 20 should just be the time which can detect the electric current value I. FIG.

  Thereafter, in step 124, it is confirmed whether or not the current value I exceeds the reference value Is. Here, if the generated power of the solar cell 18 exceeds the generated power A and the current value I exceeds the reference value Is, an affirmative determination is made in step 124. That is, it is determined that the solar cell 18 is in a power generation state exceeding the generated power A, and this flowchart is ended.

  Accordingly, the process proceeds to step 102 in FIG. 2 to activate the ventilation fan 20 so that the passenger compartment 14 is ventilated.

On the other hand, in the flowchart of FIG. 4, if the amount of solar radiation does not increase and the current value I has not reached the reference value Is (I <Is), a negative determination is made in step 124 and the process proceeds to step 126. In step 126, it is determined whether or not the current value I reaches the reference value I _L.

Here, ambient relatively bright, not reduced solar radiation is large the solar cell 18 receives the current value I is, but does not reach the reference value Is, is greater than the reference value I _L (Is> I ≧ and _{I L),} an affirmative determination is made in step 126, the interval time .DELTA.Ts, is set to a relatively short interval time [Delta] T _1.

  Thereafter, in step 130, the timer 54 is reset / started and the ventilation fan 20 is stopped, that is, the time until the next power generation state of the solar cell 18 is determined (until the current value I is detected). Start measuring).

In the next step 132, the time T measured by the timer 54 is read, and it is confirmed whether or not the time T has reached the interval time ΔTs (here, the interval time ΔT ₁ ).

Here, when the time T measured by the timer 54 reaches the interval time ΔT ₁ (ΔTs) (T ≧ ΔTs (ΔT ₁ )), an affirmative determination is made at step 132 and the routine proceeds to step 120. Thereby, after the lapse of time ΔTs, the power generation state of the solar cell 18 is determined.

That is, the current value I corresponding to the amount of solar radiation into the solar cell 18 showing the power generation state of the solar cell 18, but does not reach the reference value Is, when it exceeds the reference value I _L is the interval time interval [Delta] T ₁ Then, the ventilation fan 20 is activated.

  Therefore, when the amount of solar radiation decreases because the sun is temporarily hidden in the clouds, etc., if the sunlight recovers and the amount of solar radiation increases, ventilation in the passenger compartment 14 is started (restarted) quickly. Further, it is possible to prevent the temperature in the passenger compartment 14 from rising due to a delay in the start of ventilation.

In contrast, the amount of solar radiation decreases significantly to the solar cell 18, electric power generated by the solar cell 18 becomes a 1/4 or less of the generated power A, the current value I is smaller than the reference value I _L (I < I _L ), a negative determination is made at step 126, and the routine proceeds to step 134.

In this step 134, the interval time ΔTs is set to an interval time ΔT ₂ that is longer than the interval time ΔT ₁ . That is, the surrounding is relatively dark, since the solar radiation the solar cell 18 is subjected is such to greatly reduced, the current value I is, if not reach the reference value I _L (I <I _L), interval time ΔTs Is set to the interval time ΔT ₂ .

Thereafter, in step 130, when the timer 54 is reset / started and the time during which the ventilation fan 20 is stopped reaches the interval time ΔT ₂ (T ≧ ΔTs (ΔT ₂ )), an affirmative determination is made in step 132. Then, the process proceeds to step 120, where the ventilation fan 20 is operated to determine the power generation state of the solar cell 18.

Here, the reference value _IL is based on the generated power ¼ of the generated power A with respect to the generated power A of the solar cell 18 when the amount of solar radiation in the passenger compartment 14 requires ventilation. Is set. That is, the reference value I _L has a current value I when the generated power A is the amount of solar radiation substantially 1/4 of the solar radiation amount obtained.

  In general, the decrease in the amount of solar radiation caused by the sun being blocked by clouds or the like is not greatly reduced because the surroundings are bright. On the other hand, the decrease in the amount of solar radiation such as in the evening is greatly reduced by darkening the surroundings of the vehicle 12. That is, when the amount of solar radiation is temporarily reduced, the power generated by the solar cell 18 rarely decreases to 1/3 to 1/4 of the generated power A. It can be assumed that it takes time. Moreover, the fall of the solar radiation amount in the evening etc. will make the electric power generation of the solar cell 18 1/3 to 1/4 or less of the electric power generation A.

From here, the ventilator 10, the current value I when a quarter of the power generation power of the generator power A is set as a reference value I _L, when the current value I does not reach the reference value I _L is the interval time setting the interval time ΔT ₂ ΔTs. Thereby, the interval at which the ventilation fan 20 is operated becomes longer, and the number of operations of the ventilation fan 20 can be reduced as compared with the case where the ventilation fan 20 is operated at the interval time ΔT ₁ .

  The ventilation device 10 applied to the present embodiment determines the generated power of the solar cell 18 by detecting the current value I when the ventilation fan 20 is operating. For this reason, in the ventilator 10, even if the solar radiation amount decreases, the ventilation fan 20 is operated intermittently until the power generation of the solar cell 18 is stopped.

At this time, when the amount of solar radiation is small, by operating the ventilation fan 20 intermittently at the interval time ΔT ₂ , the number of operations is surely reduced as compared with the intermittent operation at the interval time ΔT _1. be able to. Thereby, it can suppress that the lifetime of the ventilation fan 20 becomes short.

Further, a state where the amount of solar radiation is extremely low and the generated power is less than ¼ of the generated power A also occurs at dawn, but at dawn, the outside air temperature and the temperature in the passenger compartment 14 are also low. Therefore, at this time as well, since the interval time ΔTs is set to the interval time ΔT ₂ , it is possible to suppress an increase in the operating frequency of the ventilation fan 20. Can be suppressed.

  Therefore, when the amount of solar radiation decreases because the sun is temporarily hidden in the clouds, etc., if the sunlight recovers and the amount of solar radiation increases, ventilation in the passenger compartment 14 is started (restarted) quickly. Further, it is possible to prevent the temperature in the passenger compartment 14 from rising due to a delay in the start of ventilation.

In the present embodiment described above, the interval time ΔTs is set to two stages of interval times ΔT ₁ and ΔT ₂ , but not limited to this, the interval time is set to three or more stages, and the interval time decreases as the amount of solar radiation decreases. ΔTs may be lengthened.

  Further, the interval time ΔTs is not limited to this, and a map set so that the interval time ΔTs becomes longer as the solar radiation amount or the current value I based on the solar radiation amount decreases is stored in the memory 50 and stored in this map. Based on this, the interval time ΔTs may be set steplessly.

  Further, the interval time ΔTs is stored so that the previous current value I is stored and updated so that the time becomes longer when the current value I decreases, and is updated so that the time becomes shorter when the current value I increases. Also good.

  Alternatively, the ventilation fan 20 may be intermittently operated a predetermined number of times at the same interval time ΔTs, and if the current value I does not reach the reference value Is, the interval time ΔTs may be updated to be longer.

  In addition, in this Embodiment demonstrated above, although the ventilation apparatus 10 provided in a vehicle was demonstrated to the example, this invention does not restrict to this but ventilates the to-be-ventilated room using the generated electric power of a solar cell. It can be applied to ventilators with any configuration.

It is a schematic block diagram of the ventilator concerning this Embodiment. It is the schematic of the vehicle by which a ventilator is used. It is a flowchart which shows an example of control of a ventilation fan. It is a flowchart which shows an example of determination of generated electric power.

Explanation of symbols

10 Ventilator 12 Vehicle 14 Car compartment (ventilated room)
18 Solar cell 20 Ventilation fan 22 Controller 24 Fan motor (ventilation fan)
34 Microcomputer 38 Current detection circuit (current detection means)
46 Drive control unit (ventilation drive means, intermittent drive means)
50 memory (storage means, time storage means)
52 Comparison determination unit (determination means)
54 Timer (Measuring means)
56 Time setting part (Time setting means)

Claims (4)

And line U換 gas-fan ventilation of the ventilation chamber operated by the electric power generated by the solar cells,
Current detection means for detecting a current value when the ventilation fan is operating;
Storage means for storing said current value corresponding to the generated power of the solar cell definitive the insolation criteria requiring ventilation of the target ventilation chamber as a reference value,
If the current value more is detected in the current detecting means is equal to or greater than before Symbol reference value, it performs a ventilation of the object to be ventilated chamber by operating the ventilation fan by generated power of the solar cell, the ventilation fan if the current value during operation state of less than the reference value continues for a predetermined time or more, a ventilation drive means for stopping the operation of the ventilation fan,
Time setting means for setting the stop time of the ventilation fan to be longer as the current value is lower based on the current value when the current value detected by the detection means is less than the reference value ; ,
During the stop of the ventilation fan, in order to perform the detection of I Ri said current value to said current detecting means, the intermittent drive means causes create dynamic the ventilation fan at set intervals of the stop time by the time setting means ,
Including ventilator. Includes time storage means for storing outage time set corresponding to the current value more is detected in said current detecting means,
It said time setting unit, as the stop time, the ventilation device according to claim 1 for setting the stop time stored in based-out the time storage unit to the current value. In the storage means, based Ku first reference value generated power in the solar radiation amount of the reference, and based Ku second reference value generated power in a given amount of solar radiation is less than the amount of solar radiation of the reference is stored In addition, as the stop time , the first storage time and a second stop time longer than the first stop time are preset and stored in the time storage unit,
Said time setting unit, the can before and SL current value Ru said first reference value less than a and the second reference value or more der, the first stop time as the stop time in the intermittent drive means set, the current value can and the Ru second reference below value der ventilation apparatus of claim 2 which sets the second stop time as a stop time in the intermittent drive means. The second reference value, the ventilation device according to claim 3 which is set on the basis of 1/4 of the generated power of the generator power in solar radiation of the reference.

Images