JP2953839B2 - Glass perspective control system for vehicles - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a glass perspective control system for a vehicle, and more particularly, to a glass perspective control system of a windshield or a rear glass which is detected beforehand by a sensor before the vehicle starts running, so as to make the glass transparent state. The present invention relates to a glass see-through control system for a vehicle, which energizes a glass temperature raising means all the way.

[0002]

2. Description of the Related Art Conventionally, a vehicle is provided with a hot air supply means such as a heater or a defroster in order to release a fogged or frozen state of a windshield or a rear glass. There is a temperature difference between the inside of the vehicle and the outside air,
This is to prevent the good running of the vehicle from being hindered thereby. Conventionally, various proposals have been made to automatically release the fogging or icing on the windshield or rear glass.

For example, Japanese Patent Application Laid-Open No. 2-304343 relates to a fogging detector for a vehicle, which comprises a sensor made of an electric field substance single crystal on the inner surface of a window glass and a resistance detecting means for detecting the resistance of the sensor. It is intended to determine whether or not the window glass is fogged based on the detection value of the resistance value detecting means, and then to try to energize the defroster mechanism.

On the other hand, Japanese Patent Publication No. 3-36180 relates to a fogging detecting device, which includes a light transmitting device, a light receiving device, a detection circuit for comparing an output signal of the light receiving device with a reference value and outputting a fogging detection signal. And a light transmitting device and a light receiving device are provided symmetrically on a windshield or a rear window, and the defroster mechanism is automatically activated by an output signal of a detection circuit.

[0005]

However, the above two prior arts are both rear-energized after the vehicle runs. Generally, when the windshield is frozen in winter or in the rainy season,
When condensation occurs on the windshield and rear glass,
The driver warms the engine or removes the icing condition using mechanical means or wipes off condensation without immediately starting the run. Therefore, there is a problem that the above-mentioned operation before traveling is complicated for the driver, and a considerable amount of time must be spent before traveling.

According to the present invention, it is determined whether or not at least a windshield, preferably a rear glass, is in a see-through state based on an output signal from a sensor, and the driver starts driving comfortably and immediately when the driver gets into the vehicle. It is an object of the present invention to provide a glass see-through control system for a vehicle that can perform the control.

[0007]

In order to achieve the above object, the present invention provides a sensor provided at least at or near a window of a vehicle and outputting a signal for determining the presence or absence of a see-through state of the window. Determining means for determining a see-through state of a window based on a detection signal of the sensor; glass heating means driven by an internal battery of the vehicle to heat the window; and a scheduled riding time before traveling of the vehicle. Preset means to set the, based on the scheduled boarding time determined by the preset means, when reaching a preset operation start time, when the determination means determines that the window is not transparent,
Control means for energizing the glass heating means ,
The glass heating means blows warm air into the window
Hot air blowing means and glass heat generating means for the window
And the control means, the hot air blowing means and
When energizing the glass heating means at the same time,
Characterized in that the amount of hot air blown out by the discharging means is suppressed.
You. The present invention also relates to at least a vehicle window or
Is provided in the vicinity of the window, and whether or not the window has a see-through state
A sensor for outputting a signal for determining
Of judging the see-through state of the window based on the detection signal of
Means, glass heating means for heating the window,
Preset to set the scheduled boarding time before running the vehicle
And the boarding schedule determined by the presetting means
When the preset operation start time has been reached based on the time
Window cannot be seen through the discriminating means.
Control means for urging the glass heating means.
And a step, wherein the glass heating means is provided in the window
Means for blowing warm air to the window, and the window
Glass heating means, and the hot air blowing means
Performs air conditioning inside the vehicle before traveling of the vehicle
One or more heat exchangers, switching valves,
Presser and expansion valve connected by pipe to cool and heat
A gas circulation system that circulates the gas of
Driven by an external power supply connected before the vehicle travels
And the control means is configured to control the coil which constitutes the gas circulation system.
Hot air is supplied to the windshield under the urging action of the impreza
And at the same time, the glass heating means through the external power supply.
In the case of biasing, this inhibits the output of the compressor
And features.

[0008]

[0009]

[0010]

According to the output signal from the sensor, the discriminating means judges whether at least the window is in the see-through state. Thus, if the vehicle is not in the see-through state, the control unit activates the glass heating unit for heating the window at the operation start time set based on the scheduled boarding time set by the preset unit. Is issued,
At the time of boarding, dew condensation on the window is removed or the frozen state is released.

Further, since the glass heating means is energized from the operation start time, the dew condensation state or the icing state of the window is released most efficiently, that is, at the time of getting on with minimum power consumption.

Further, the glass temperature raising means includes a hot air blowing means and a glass heat generating means. When both the hot air blowing means and the glass heat generating means having a large temperature rising amount and a large power consumption are used, the hot air blowing means is used. The window is efficiently made transparent by minimizing the blowing means to a necessary minimum and using most of the available electric energy for the glass heat generating means.

In addition, when the hot air blowing means is used together with the glass heating means, the output of the compressor is suppressed to a minimum to energize the glass heating means.
Electricity can be used efficiently.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, a preferred embodiment of a glass see-through control system according to the present invention in relation to an air conditioning system will be described in detail with reference to the accompanying drawings.

First, a general description of a vehicle air conditioning system as an air conditioning mechanism will be given.

In this embodiment, an electric vehicle is used as a vehicle. The electric vehicle has a battery mounted inside the vehicle, and the battery can be charged by a required amount from an external power supply (not shown).

The electric vehicle 10 includes an indoor heat exchanger 12,
An indoor heat exchanger 14 and an outdoor heat exchanger 16 are connected in series with this, and a gas circulation system is configured by a pipeline connecting these. A bypass valve 18 is provided between the indoor heat exchanger 12 and the indoor heat exchanger 14, and a pipe connected to the indoor heat exchanger 14 is connected to one of the downstream sides of the valve 18 and connected to the other. Expansion pipe 2
0 is interposed.

A four-way valve 22 is further provided downstream of the indoor heat exchanger 14, and the downstream side of the four-way valve 22 communicates with the outdoor heat exchanger 16. A pipe line is provided in parallel on the downstream side of the outdoor heat exchanger 16, and a bypass valve 24 is interposed in one of the pipe lines. The downstream side of the bypass valve 24 is connected to a bypass valve 26.
A parallel pipe line is connected to the downstream side, and an expansion valve 28 is interposed in one of the pipe lines. The indoor heat exchanger 12 is connected to a downstream side of a pipe including the expansion valve 28.

The two pipes of the four-way valve 22 are connected to the compressor 30, respectively. Under the switching action of the four-way valve 22, refrigerant such as chlorofluorocarbon is supplied to the outdoor heat exchanger 16 and the indoor heat exchanger 14.
Alternatively, it is configured to be supplied to the compressor 30. Further, the indoor heat exchanger 12, the outdoor heat exchanger 16
Are provided with fans 32, 34 which are energized by a rotary drive source (not shown), and dampers 36, 3 for communicating with outside air or effectively convecting room air.
8, 40, 41a, 41b, 42, 43, 44 and 4
6 are provided. In the drawings, reference numeral 48 indicates a battery, and reference numeral M indicates a prime mover, here, a motor.

The mechanical configuration of the electric vehicle 10 according to the present embodiment is basically as described above.
Next, the electrical configuration will be described with reference to FIGS.

As shown in FIG. 2, an inverter 50 for driving a compressor, an outdoor unit icing detection sensor 51 provided in the outdoor heat exchanger 16,
Solar radiation detection sensor 52, charge / discharge current detection sensor 53, humidity detection sensor 54, glass icing detection sensor 55, indoor temperature detection sensor 56, door opening / closing detection sensor 57, window opening / closing detection sensor 58, discharge depth detection sensor 59, outside air temperature A detection sensor 60 and a sheet pressure sensor 61 are provided, and their output sides are introduced to the CPU 62.

FIG. 3 is a system configuration diagram of a control system including the CPU 62.

The CPU 62 stores an RO in which the processing procedure is stored.
M63, a RAM 64 for temporarily storing output signals from the various sensors, an interface 66, and fans 32, 34, and a four-way valve 2 connected to the interface 66.
2. ON / OFF of bypass valves 18, 24, 26, etc.
Alternatively, a relay box 68 that performs a switching operation, an A / D converter 70 that converts an analog signal that is an output signal from various sensors into a digital signal and supplies the digital signal to the interface 66, and energizes a fan, a damper, a glass heater, and the like. To convert digital signals to analog signals
The converter 72 is further configured to introduce output signals of various switch groups provided on the operation panel 74 to the interface 66.

FIG. 4 shows the operation panel 74. The operation panel 74 is roughly divided into nine blocks, and a liquid crystal display panel 76a is provided at the top of the block. The liquid crystal display panel 76a can display, for example, temperature, humidity, and the like detected by the detection sensor in a digital or analog manner.

Reference numeral 76b indicates an operation switch for operating or not operating the air conditioner device. Auto (AU)
TO) is a switch for automatically adjusting the temperature or humidity in the room, and ON / OFF is a switch for turning on or off the air conditioner equipment. The pre-A / C switch is used by a driver or a passenger to perform pre-conditioning (hereinafter referred to as pre-conditioning) in which the temperature or humidity in the room is adjusted beforehand by using an external power supply or the like in advance. ON / O
FF switch.

Reference numeral 76c is a temperature setting switch. A digitally set or detected temperature is shown on the right side, a triangular up switch to increase the set temperature on the left side, and a down switch to lower the set temperature on the lower side. Is provided. Reference numeral 76d denotes a section for digitally displaying the boarding time, and a clock or an indicator for displaying the reserved time, or a switch for setting the clock, a day (D), a time (H), and a minute (M). It consists of switches for setting up or down respectively. By setting the day (D), the time (H), and the minute (M), the boarding time is changed or fixed.

On the lower left side of the operation panel 74, reference numeral 7
An inside / outside air changeover switch indicated by 6e is provided. The switch on the right is for introducing outside air into the car,
The switch on the left is for recirculating air only in the room. Each is composed of an ON / OFF switch. Reference numeral 76f is a switch for controlling the air volume of the blower fan. The left side has a relatively gentle air volume, the center has a medium air volume, and the right side has a strong air volume. I do.

Reference numeral 76g designates a switch for switching the outlet, and more specifically, for controlling the opening and closing of the damper corresponding to various dampers as already described with reference to FIG. is there.

For example, the AUTO switch on the left side is for automatically switching the outlet, the second switch from the left side is for sending wind in the direction of the chest of the driver, and the third switch from the left side is for blowing air toward the driver's chest. Switches open and close the damper to send wind to the driver's legs, the fourth switch from the left sends wind to the driver's chest and legs, and the right switch runs along the windshield wall. This is a switch for supplying wind.

Reference numerals 76h and 76i denote switches for setting a third dehumidifying and heating mode, which will be described later, during normal running, respectively. Reference numeral 76j designates a front and rear window, and a heater for heating the seat. 4 shows an ON / OFF switch to be activated.

The operation of the air conditioning system for a vehicle according to the present embodiment constructed as described above, particularly the operation of the CPU 62, will be described in detail below with reference to the attached flowchart.

FIG. 5 shows a control flowchart for driving the air conditioner in the running electric vehicle.

AUTO of operation switch 76b for air conditioner
When the switch (see FIG. 4) is operated (step S2) and the indoor temperature is set by the temperature setting switch 76c (step S4), the CPU 62 reads information of various sensors such as the indoor temperature (step S6), The air conditioning mode of cooling or heating is set from these sensor information (step S8).

Next, the CPU 62 reads the discharge current of the battery 48 from the charge / discharge current detection sensor 53 (step S10), calculates the remaining capacity of the battery 48 from this discharge current, and determines the maximum value of the available power in the remaining capacity. Calculation (step S12), and the total power required for operation including the power for driving the driving motor, the power for driving the electrical components other than the driving motor such as headlights, and the power for driving the air conditioner is calculated. (Step S14), it is determined whether or not the maximum value of the available power of the battery obtained in step S12 is larger than the operating power required for operation (step S16). For example, the four-way valve 22 and the bypass valve 18 shown in FIG.
24, 26 and the like are controlled (step S18).

In this case, the step S16 is performed in the battery 48.
To determine whether the remaining capacity is sufficient to supply the power required for traveling and to use the air conditioner.
If it is sufficient, after step S18, the output control of the compressor 30 of the air conditioner (step S20), the damper 3
Air-conditioning control such as opening / closing control of 6 to 46 (step S22), output control of blower fans 32 and 34 (step S24), control of glass heater (step S26), control of seat heater (step S28), and the like are performed.

In step S16, when available power ≧ operating power is not satisfied, the output of the compressor 30 of the air conditioner is limited until available power ≧ operating power (step S29).

Next, a method of controlling the air conditioner during normal traveling will be described with reference to the flowcharts of FIGS. 6 to 12 and FIG.

First, flags of respective modes used for air conditioning described later are initialized (step S30). Subsequently, it is determined whether or not an ignition (IGN) switch (not shown) of the electric vehicle is operated (step S32). If not, it is determined whether the driver has selected the pre-A / C switch using the operation switch 76b. It is determined whether the pre-A /
If C is selected, the control enters pre-A / C control. on the other hand,
If the pre-A / C switch has not been selected, the process returns to step S32.

On the other hand, if the IGN switch has been operated, it is determined whether or not the AUTO switch (see FIG. 4) of the operation switch 76b has been selected (step S36). If not, step S32 has been selected. Return to If the AUTO switch is selected, the automatic control of the air conditioner is performed, and subsequently, it is determined whether or not an operation key is input on the operation panel 74 (step S3).
8). If there is an operation key input, it is read in an operation input subroutine (step S40).

In the operation input subroutine, as shown in FIG. 8, the control state is changed by operating the keys on the operation panel 74. That is, the temperature setting switch 76c
It is determined whether or not is operated (step S40-
1) If the operation is performed, the set temperature is changed (step S)
40-2) Subsequently, it is determined whether or not the inside / outside air changeover switch 76e is operated (step S40-3). If the inside / outside air changeover switch 76e is operated, the inside / outside air flag for operating the damper to switch the inside / outside air is operated. Is set (step S40-
4). Further, it is determined whether or not the blower fan air volume switch 76f has been operated (step S40-5). If the air flow switch 76f has been operated, a flag for switching the air volume of the blower fan is set (step S40-6). It is determined whether or not the changeover switch 76g has been operated (step S40-7), and if it has been operated, a damper provided in the vehicle is operated to set a flag for switching the outlet (step S40-). 8).

Subsequently, the output from the sensor is read into the CPU 62. That is, the outdoor unit icing detection sensor 51 detects whether or not the outdoor heat exchanger 16 is frozen (step S42), the solar radiation amount detection sensor 52 detects the amount of solar radiation (step S44), and the charge / discharge current detection sensor 53. To detect the amount of discharge current from the battery 48 (step S
46), the humidity in the vehicle compartment is detected by the humidity detection sensor 54 (step S48), and whether or not the windshield and the rear glass are frozen is detected by the glass icing detection sensor 55 (step S50).
6, the indoor temperature is read (step S52), and the outside air temperature is detected from the outside air temperature detection sensor 60 (step S56).

Next, the refrigerant pressure is set to an appropriate pressure for the operation of the air conditioner, for example, 2 kg / cm ² ≦ refrigerant pressure ≦ 50 kg
/ Cm ² (step S58 and step S60). When the refrigerant pressure is not in the pressure range, it is determined that the refrigerant pressure is abnormal, and the control operation of the air conditioner is stopped. If the refrigerant pressure is within the pressure range, the outdoor heat exchanger 16 may freeze during heating, so it is determined whether or not the outdoor heat exchanger 16 is frozen (step S62). If so, the timer _td1 for decompression is operated (step S64).
And step S66).

Subsequently, it is determined whether or not the timer t _d1 is equal to or longer than 5 minutes (step S68). If the elapsed time of the timer t _d1 is within 5 minutes, the first effect having little effect on the indoor state is determined. Set the decompression mode flag (step S7)
0). If the timer t _d1 still freezes after 5 minutes, the mode is switched to the second thawing mode having a higher thawing capacity than the first thawing mode, and the flag of the second thawing mode is set (step S72). ).

When the thawing is performed as described above and the frozen state of the outdoor heat exchanger 16 is released, or when the frozen state is not detected originally, the timer _td1 is released (step S74).

Subsequently, as shown in FIG. 9, it is determined whether or not the front glass and / or the rear glass is frozen from the output of the glass freeze detection sensor 55 (step S).
76) When the icing is detected, the timer t _d2 for operating the glass heater is operated (steps S78 and S80), and it is determined whether or not the timer t _d2 has elapsed for 3 minutes (step S82). If it is within 3 minutes, a flag for minimizing the output of the compressor 30 of the air conditioner is set (step S84), the glass heater of the windshield and / or the rear glass is energized, and the flag of the glass heater operation mode is set. It is set (step S86).

If the glass heater has been frozen even after the glass heater operation time t _d2 has passed 3 minutes, it is determined that the frozen state is abnormal, and the compressor 30 of the air conditioner is returned to the normal state, and the compressor output The minimum mode flag is reset (step S88), the power supply to the glass heater is stopped, the glass heater operation mode flag is reset (step S90), and the timer _td2 is reset (step S92).

When thawing is performed in this manner, and the icing state of the front glass and / or the rear glass is released in step S76, the humidity detecting sensor 54
The control method is branched according to the value of the glass surface humidity detected in (step S94).

If the glass surface humidity is 95% or more in step S94, it is determined that the windshield and / or the rear glass is condensed.
It is determined whether or not the timer t _d2 set in the step is operating (step S96). If the timer is operating, it is determined whether or not the timer t _d2 has elapsed one minute (step S100). If it is within one minute, the output of the compressor 30 of the air conditioner is minimized, and the flag of the compressor output minimum mode is set (step S102).
Power is supplied to the glass heaters of the front glass and / or the rear glass, and a flag for the glass heater operation mode is set (step S104).

If the glass surface humidity is 95% or more even after the timer t _d2 has elapsed for one minute, the compressor output minimum mode flag is reset to return the air conditioner compressor 30 to the normal state (step S1). S106),
The power supply to the glass heater is stopped by resetting the flag of the glass heater operation mode (step S10).
7) The timer _td2 for operating the glass heater is reset (step S108). In this case, in the case of normal dew condensation, the dew condensation state can be released by energizing for one minute, but when the dew state cannot be released by energization for one minute, it is determined that it is a peculiar case, and large power is required. Power supply to the glass heater to be stopped is stopped.

In the case where the judgment result of the glass surface humidity in the step S94 is 70% or more and less than 95%,
The flag for minimizing the output of the compressor 30 is reset (step S109), and the flag for the operation mode of the glass heater is reset (step S110). Resets the timer t _d2 that is set in the step S80 (step S110). Next, the read current humidity value is compared with the previous humidity value (step S11).
2) If the previous humidity is less than the current humidity, a dehumidification mode flag is set (step S114). If the current humidity is smaller than the previous humidity, the set dehumidification mode flag is reset. (Step S118).

If the humidity read in step S94 is less than 70%, a flag for minimizing the output of the compressor 30 is set (step S11).
5) The glass operation mode flag is reset (step S116), and the timer _td2 is reset (step S117). Then, if the dehumidification mode flag is set, it is reset (step S118).

When the processing of each of steps S86 and S92 in the above-mentioned glass deicing release routine and steps S104, S108, S114 and step S118 in the defrosting routine is completed, the CPU 62 determines the set temperature from the read data. The temperature is corrected (step S120), and the set temperature is corrected by a calculation subroutine so as to provide a comfortable indoor state (step S122).

Subsequently, a mode is selected. First,
It is determined whether or not the DRY switch 76h is ON (step S124). If the DRY switch 76h is operated, the first dehumidification mode is selected (step S126). Step S
In 124, if no DRY switch 76h is turned ON, and calculates a target temperature T _S1 of the indoor temperature T _R is the corrected read in step S52 (step S128), the process branches method by calculation result.

If the result of the calculation is T _R -T _S1 > 2, in step S56, the outside air temperature detection sensor 60
Comparing the ambient air temperature T _AM and the room temperature T _R read from (step S130), the comparison result is T _AM> T _R -5
° C, the room temperature T _R is higher than the target temperature T _S1 + 2 ° C., and the outside air temperature T _AM is higher than the room temperature T _R −5 ° C. (T _R > T _S1 +2, T _AM > T _R). -5), it is determined that the mode is the cooling mode (step S132).

In step S130, when the outside air temperature T _AM is lower than the room temperature T _R -5 ° C. (T _R > T _S1).
+2, T _AM <T _R −5), and select the ventilation mode (step S136).

On the other hand, in step S128,
Fruit is T_R-T_s1If <−2, step S56
, The outside air temperature read from the outside air temperature detection sensor 60
Degree T _AMAnd room temperature T_R(Step S13)
4), T_AM> T_R+2, room temperature T_RIs corrected
Target temperature T_S12 ° C. or lower and the outside air temperature T
_AMIs the room temperature T_RBecause it is higher than + 2 ° C,
Target temperature T_S1Because it is possible to ventilate mode
Is determined (step S136).

In step S134, T_AM> T
_R+ 2 ° C., that is, the room temperature T_RIs the goal
Temperature T_S1−2 ° C. and the outside air temperature T_AMIs room temperature
Degree T _RIf the temperature is lower than + 2 ° C, the dehumidification flag is set.
It is determined whether or not it has been set (step S138).
If not, it is determined that the mode is the heating mode (step S14).
0), if set, determine second dehumidification mode
(Step S142).

Meanwhile, calculation result in step S128 is, the absolute value of the difference between the room temperature T _R and the target temperature T _S1 is 2 ℃
If it is smaller than (| T _R −T _s | ≦ 2), it is determined that the room is almost at the target temperature T _S1 , and it is determined whether or not the dehumidification flag is set in step S114 described above. It is determined (step S144), and if it is set, it is determined to be the first dehumidification mode (step S126). If it is not set, the operation mode of the air conditioner is stopped (step S146).

According to the steps described above, control modes such as cooling, heating, dehumidification, and ventilation are selected.

Subsequently, as shown in FIG. 12, the control of the electric power used during traveling is performed. It reads the electrical load current I _T used in the drive device and the compressor 30 than the electrical components, such as traction motor (step S148), the total output is the sum of the current consumption I _CO of the electrical load current I _T and the compressor 30 maximum discharge current I of the current I _a battery 48
_It is determined whether it exceeds _BMAX (step S149).

[0061] The total output current I _A is the maximum discharge current I _BMAX
If it is less than, it proceeds to the execution of the control mode shown in FIG. If the total output current I _A exceeds the maximum discharge current I _BMAX (see the broken line portion of the total output current I _A of FIG. 13),
For damaging the battery 48, the total output current I _A (I _T
+ I _CO ) must be reduced.

[0062] Therefore, the current consumption I _CO of the compressor 30 to the current amount obtained by subtracting the electrical load current I _T from the maximum discharge current I _BMAX to maintain accelerating performance (step S15
0, see the section between t _{1 and} t ₂ of the consumption current I _CO in FIG. 13). However, when the compressor 30 stops, the difference in refrigerant pressure before and after the compressor 30 decreases, and it takes time to restart the compressor 30. As a result, the capacity of the air conditioner decreases.

Therefore, it is determined whether or not the current consumption I _CO of the compressor 30 is _{equal to} or more than the minimum current consumption I _COMIN that can continue to drive the compressor 30 (step S1).
52). If the current consumption I _CO of the compressor 30 satisfies the above condition, the process proceeds to FIG. 14 to execute the control mode. If the current consumption I _CO of the compressor 30 does not satisfy the above condition, the compressor 30 stops, so that the current consumption I _{CO is set} to the minimum current consumption I _COMIN (step S154, the current consumption I _CO in FIG. 13). t
See ₂ to t ₃ interval).

[0064] In this case, as shown in FIG. 13, digested quiescent current I _CO and the electrical load current I _T total output current I is the sum of
_{Since A} exceeds the maximum discharge current I _BMAX of the battery 48, it is determined whether or not the excess time t is within an allowable time t _{d4 that} does not adversely affect the life of the battery 48 (step S156). If the time is less than the time _td4 , the process directly _proceeds to the control mode shown in FIG.

If the time t is equal to or longer than the permissible time t _d4 ,
Traveling motor as shown in t ₃ to t ₄ sections of the electrical load current I _T in FIG. 13, to limit the output of the drive motor, for example by issuing an output limit _signal: total output current I _A is the maximum discharge current I
Control is performed so as to be _BMAX or less (step S158).

The current consumption I of the compressor 30 is as follows.
After the adjustment for _CO , each control mode is executed.

The operation input subroutine (step S
As shown in 40), if the switches 76c, 76e, 76f, and 76g of the operation panel 74 are selected in advance,
Priority is given to each control mode. For example, even if the heating mode is selected by automatic control of the air conditioner, if the outside air introduction of the inside / outside air changeover switch 76e is selected, the damper is controlled to introduce outside air.

Next, a description will be given of a pre-air-conditioning control for air-conditioning the vehicle before traveling.

FIGS. 15 to 17 show flowcharts of the main part of the pre-air conditioner control.

The pre-air conditioner is usually performed during charging of the battery 48 at night or during parking, etc., and adjusts the temperature and humidity in the vehicle cabin by the time the driver gets on the vehicle next time, so that a comfortable in-vehicle environment can be obtained at the time of riding. It is something to be prepared.

Then, the pre-A / C switch (see FIG. 4) of the air conditioner operation switch 76b is turned on (step S160), and the charger is connected (step S16).
2) The charging of the battery 48 from the external power supply via the charger is started, and the CPU 62 sets the boarding time of the next morning and the indoor set temperature at the boarding time set in advance in the factory or the like.
The data is read from the AM 64 and displayed on the liquid crystal display panel 76a of the operation panel 74.

These display contents can be changed by operating switches 76c of the operation panel 74 and switches provided in the section 76d.
The operation input subroutine (step S164) will be described.

The CPU 62 determines whether or not the outside air introduction switch of the inside / outside air changeover switch 76e has been operated (step S164-1), and if so, sets an outside air introduction flag (step S164-2). It is determined whether the initial value of the set scheduled riding time t _ab , for example, 7:00 am has been changed (step S164-3).
If the setting has been changed, the changed time is stored in the RAM 64 (step S164-4), and if not, the previously set 7:00 am is set as the scheduled boarding time t _ab (step S164-5). .

Next, the predetermined boarding scheduled time t _ab
, Set room temperature T _s , for example, T _s = 25
It is determined whether or not C has been changed (step S164-).
6) If changed, the changed set temperature is stored in RAM 6
4 (step S164-7), and if not changed, the previously set 25 ° C. is set as the set value of the room temperature T _S (step S164-8).

Further, a seat heater switch (FIGS. 4 and 7)
6i) is operated (step S164-).
9) and set a flag for the seat heater (step S1).
64-10), if the DRY switch (see 76h in FIG. 4) has been operated (step S164-11), the DRY switch
Is set (step S164-12).

[0076] Then, CPU 62 calculates a discharge amount I _d from the discharge depth of the battery 48 read from the depth-of-discharge detecting sensor 59 (step S166), and calculates the charging time H on the basis of the following equation (1).

H = (I _d / I _ch ) × K ₁ (1) In equation (1), I _ch is the rated charging current (A / H), and K ₁ is set according to the type of the battery 48. It is a charging efficiency coefficient.

The charging completion time is calculated from the charging time H obtained in the above equation (1) and the current time read from the clock in the section 76d of the operation panel 74 (step S168). It is determined whether or not charging is completed by time t _ab (step S170), and if completed, step S34 to be described later is performed.
The outputs of various sensors are read by the same sensor reading subroutine as in steps S5 to S350 (step S1).
71).

Further, the CPU 62 estimates the outside air temperature T _{AM at} the boarding time and the room temperature T _R when the air conditioner is not operated by the calculation described later (step S17).
2), the operation start time of the pre-air conditioner is set from these estimated temperatures (step S173). In this case, when it is determined in step S170 that charging is not completed by the boarding time, the battery 48 is charged,
The pre-conditioning system is suspended (step S17)
4).

The CPU 62 constantly determines whether or not the current time has reached the set operation start time of the air conditioner (step S175), and if the operation start time has been reached, the same as steps S160, S162 and S164. Step, the pre-air conditioner switch is turned on again.
N (step S176) or whether the charger is connected (step S177), and further reads an operation input subroutine (steps S164-1 to S16).
By performing 4-12), the setting change is read (step S178). Further, a sensor output reading subroutine (steps S345 to S35)
0), the outputs of various sensors are read (step S18).
0), and corrects the estimated by the value set in the room temperature at Step S174 based on the room temperature read from the room temperature sensor 56 (step S182), further detected conditioned from the room temperature T _R and the outside air temperature T _AM The mode is set (step S184).

Next, the charging current supplied to the battery 48 from the charger is read from the charging / discharging current detection sensor 53 (step S186), and the difference between the maximum charging capability of the charger and the current charging current is obtained from the charging current. The maximum value of a certain available power is calculated (step S188). And
The operating power required to operate the air conditioner is calculated (step S190), and it is determined whether the available power is greater than the operating power (step S192). Way valve 22 and bypass valve 1
8, 24, and 26 (step S194), output control of the compressor 30 of the air conditioner (step S196),
Opening and closing control of the dampers 36 to 46 (step S198),
Output control of blower fans 32 and 34 (step S20
0), air conditioner control such as control of a seat heater (step S201) is performed.

If the available power is not equal to or more than the operating power in step S192, the compressor 30
Is limited (step S201), and step S1
94 four-way valve 22 and bypass valves 18, 24, 2
6 is performed.

The CPU 62 determines whether or not one hour has elapsed from the scheduled time of boarding (step S202), and if one hour has elapsed, suspends the air conditioning system (step S2).
04). If the air conditioner has been operating for more than one hour from the scheduled boarding time, it is determined that the driver's scheduled boarding time has been changed, and the operation of the air conditioner is stopped to save electric energy to be consumed.

On the other hand, within one hour from the scheduled boarding time, the process goes to step S176, and the CPU 62 monitors whether the switch of the pre-air conditioner is ON (step S176) and whether the charger is connected (step S176). S17
7), or pre-air-conditioning switch is turned OFF, or if the charger is removed becomes the system pause step S204, further, the setting change and setting of the room temperature T _R of the riding time during charging was changed In this case (step S178), the control is changed based on the change information.

The pre-conditioner is controlled by the above steps. Therefore, details of each control will be described with reference to FIGS.

In the electric vehicle 10, an initial value relating to a pre-air conditioner is set in a manufacturing factory. That is, CPU
62 backup power source is connected to a control circuit including a (step S250), the reference value T _S of the room temperature, for example, 2
5 ° C. is set (step S252), and a reference value of the scheduled boarding time t _ab , for example, 7:00 am is set (step S254).

When the driver who drives the electric vehicle 10 with the initial values set as described above charges the battery 48, turns off the ignition switch (step S256) and turns on the pre-A / C switch (step S256). In step S258), the CPU 62 reads the set room temperature T _S and the estimated boarding time t _ab from the RAM 64 and displays them on the liquid crystal display panel 76a. In this case, the setting values of the room temperature T _S and the scheduled boarding time t _ab set in the manufacturing line or the like can be changed by the temperature setting switch 76c and the boarding time setting section 76d of the operation panel 74. Yes, it is updated in the RAM 64 for each change.

That is, the operation input subroutine of steps S164-1 to S164-12 is processed, and the scheduled boarding time t _ab and whether the set indoor temperature T _S of the electric vehicle 10 at the scheduled boarding time t _ab is changed. It is further determined whether or not the inside / outside air changeover switch 76e, the seat heater switch 76i, and the DRY switch 76h have been operated.

Next, it is determined whether or not the charging plug is attached (step S262). If the charging plug is not attached, the pre-air-conditioning system is stopped (step S26).
4) Returning to step S256, if it is attached, the depth of discharge DOD of the battery 48 is read (step S2).
66), and calculates the charging time required to charge completion from the depth-of-discharge DOD, further obtains the charge completion expected time t _f in accordance with the following equation (2) (step S268).

[0090] In this case, when the depth of discharge DOD is 80% if charged at 8 hours charging at rated current completed, the _{t f = t N + 10hr ×} DOD ... (2). In the equation (2), t _N indicates the current time.

Next, the scheduled boarding time t _ab read in step S254 is compared with the scheduled charging completion time t _f + α time (eg, α = 1 hour) (step S270).
Unless t _ob ≧ t _f +1 hour, the time for the pre-air conditioner is insufficient, and a message indicating that the pre-air conditioner is not available is displayed on the liquid crystal display panel 76a (step S27).
2) Stop the pre-air-conditioning system (step S2)
56).

If t _ob ≧ t _f +1 hour, it is determined that pre-air conditioning is possible, and it is determined whether 10 minutes have elapsed since the previous temperature was read (step S274). read the outside air temperature T _AM and the room temperature T _R (step S276), and determines whether the present time t _N has reached the charge completion expected time t _f (step S27
8), and repeats the process from step S256 to step S278 until it reaches its charging the scheduled completion time t _f.

If the current time t _N has reached the scheduled charging completion time t _f (t _N ≧ t _f ), the measurement is performed so far and the RAM
According to the change state of the outside air temperature T _AM stored in the memory 64, the estimated boarding time t based on the equation (3) using the three-point method.
The estimated outside air temperature T _AMOB at _ab is calculated (step S280).

[0094]

(Equation 3)

[0095] Next, the estimation by the same operation and calculation of the outside air temperature T _AMOB the calculation of the estimated room temperature T _ROB at boarding time t _ab (4) based on the equation (step S
282).

[0096]

(Equation 4)

It is determined whether or not the estimated outside air temperature T _{AMOB at the} scheduled boarding time t _ab obtained in step S280 is T _AMOB ≦ 20 ° C. (step S284). Then, the target temperature T _S1 is calculated according to the equation (5) (step S286). If the temperature is equal to or lower than 20 ° C., the heating mode is determined, and the target temperature T _S1 is calculated according to the equation (6) (step S288).

T _s1 = 25−A × (20 + T _AMOB ) (5) T _s1 = 25 + B × (20−T _AMOB ) (6) Equations (5) and (6) are initially set at the factory. (5) shows a case where the room temperature T _S is 25 ° C.
A in the equation is a coefficient during cooling, B in Equation (6) is a coefficient during heating, and the cooling coefficient A and the heating coefficient B have a relationship of A <B.

Further, even if the temperature is the same in summer and winter, the bodily sensation is different. Therefore, when the air conditioner for cooling is performed in summer, the temperature is adjusted to be lower than the set temperature of 25 ° C. (Equation (5)). When the air conditioner for heating is performed in winter, the temperature is adjusted to be high (Equation (6)).

The initial setting obtained in this way is
Target temperature T at room temperature 25 ° C _S1To step S26
Is corrected with the value changed in step 1 (step S29)
0). This arithmetic expression is shown in Expression (7).

T _S2 = T _S1 + T _AD (7) In this case, T _AD = the value input in the manual−25 ° C.

Next, the CPU 62 calculates the room temperature T _R and the corrected target temperature T _S2 (step S29).
4) The processing method branches depending on the operation result.

[0103] The calculation result in the case was T _R -T _s2 <-2, were compared with the outside air temperature T _AM read from outside air temperature detection sensor 60 and the indoor temperature T _R +2 (step S29
6) If T _AM ≧ T _R +2, the room temperature T _R is lower than the corrected target temperature T _S2 by 2 ° C. or more, and the outside air temperature T
_AM is determined that can be the target temperature T _S2 by ventilation is higher than the target temperature T _S2 which is corrected, and the ventilation mode (step S298), to set the ventilation time h (step S300), the prediction boarding Time t _ab and ventilation time h
Determining an operating start time of the blower fan 32 and 34 from _{Tokyo and (t s = t ab -h 1} ) ( step S302).

In step S296, T _AM ≧ T
When it is not _R +2, i.e., when none of the room temperature T _R and the outside air temperature T _AM is lower than the target temperature T _S2,
The heating mode is set (step S304).

In the heating mode, the available power P that can be used for heating is determined by the following equation (step S3).
06).

P = (I _MX −I _c ) × V (8) In equation (8), I _MX is the maximum current that can be supplied by the charger, V is the battery voltage, and I _c is the charging current.

[0107] Then, CPU 62 reads out the heating capacity F in the available electric power P from the data map in advance and the stored available power P a heating capacity F in ROM 63 (step S308), the target temperature the room temperature T _R T
The heating operation time h ₂ required to adjust the _S2 (9) determined by the equation (step S310).

[0108]

(Equation 9)

In equation (9), Q is the amount of heat required to change the room temperature by 1 ° C., which is a value previously obtained from an experimental value. Q1 is the amount of heat leaked from the room to the outside.

The warm-up obtained by the calculation of the above equation (9)
Chamber operation time h_TwoAnd the boarding time t _abThe operation of heating from and
Start time t to start_s2(T_s= T_ab-H_Two)
(Step S312).

[0111] On the other hand, the result of calculation in step S294, if the absolute value of the difference between the room temperature T _R and the target temperature T _S2 was smaller than _{2 (| T R -T s2 |} ≦ 2), the room Is determined to be substantially at the target temperature T _S2 , and the operation mode of the air conditioner is suspended (step S314).

[0112] Further, the result of calculation made in step S294, if the room temperature T _R is 2 ℃ or more higher than the target temperature T _S1 is _{(T R -T s2> 2)} , the outside air temperature T _AM and the room temperature T _R - 5 (step S316), and T _AM <
If a T _R -5 becomes a ventilation mode in step S298, the room temperature T _R to match the target temperature T _S2 by ventilation.

Further, the result of the comparison in step S316 is obtained.
Fruit, T_AM<T_RIf −5, the indoor temperature T_Rand
Outside air temperature T_AMIs the target temperature T_S2Higher than (T_R>
T_s2<T_AM), Cooling mode (step S318),
The available electric power P that can be used for cooling is used for heating.
This is an equation for calculating usable power P that can be used.
Determined by the above equation (8) (step S320), RO
Available power P and cooling capacity stored in advance in M63
F from the data map with F
The cell capacity F is read (step S322), and the room temperature T is read.
_RTo the target temperature T _S2Cooling operation time required to adjust to
h_ThreeIs obtained by the equation (10) (step S32).
4).

[0114]

(Equation 10)

In the equation (10), Q2 is the amount of radiant heat due to solar radiation, and is a factor for reducing the cooling effect. In this case, a value determined by the vehicle type from the actually measured value, for example, 800 kcal is set.

An operation start time t _s2 for starting the cooling operation is obtained from the cooling operation time h ₃ obtained by the calculation of the above equation (10) and the scheduled boarding time t _ab (t _s2 = t _ab −
h ₃₎ (step S326).

As described above, the operation start time t_s2Is set to
Step S302 of the completed ventilation mode and the heating mode
Step S312 and the cooling mode step S326
And the current time t_NIs the operation start time t_S2Step until
The processing routine from S256 is repeated (step
S328), current time t_NIs the operation start time t_s2Reached
At this time, the charging current I_CRead
(Step S330), the charging current I_CUse
The available power P is obtained by the above equation (8) (step S8).
332), can be used for pre-air conditioner
Active power P is the minimum required to drive the pre-air conditioner.
Power required P_MNIs smaller than (P <P _MN) (Step
S334), the available power P is the minimum required power P_MNthan
Pause the operation of the pre-conditioning system until it becomes large
(Step S335).

When the available power P is larger than the minimum required power P _MN , the input determination subroutine (step S33)
After processing 6), it is determined whether or not the refrigerant pressure read from a refrigerant pressure sensor (not shown) is 50 kg / cm ² or more (step S338). If the refrigerant pressure is 50 kg / cm ² or more, the pressure of the refrigerant is abnormal. Shut down the air conditioning system to be. Further, unless 50 kg / cm ² or more refrigerant pressure is equal to or a 2 kg / cm ² or less (step S340), the pressure drop of the refrigerant as long 2 kg / cm ² or less, the coolant pressure 50 kg / as in the case of cm ² or more to stop the air-conditioning system, 2kg /
If it is not less than cm ² , it is determined that the refrigerant pressure is at a normal value.

The detailed operation of the input determination subroutine in step S336 will be described with reference to FIG.

The CPU 62 determines whether or not the charging plug is attached (step S336-1). If the charging plug is attached, the CPU 62 determines whether or not the ignition switch is turned off (step S336-2). For example, it is determined whether or not the pre-A / C switch is ON (step S336-3), and if the pre-A / C switch is ON, it is determined whether or not the previously set room temperature T _S has been changed (step S336). S336-4). If it has not been changed, it is determined whether or not the scheduled boarding time t _ab has been changed (step S336-5). If there has been no change, the process exits this subroutine.

If the charging plug is not attached in step S336-1 and if the switch of the pre-conditioner is not turned on in step S336-3, the pre-conditioning system is stopped (step S336-6),
If the setting of the room temperature T _S has been changed in step S336-4, the set value of the room temperature T _S is changed to step S290.
Is corrected according to the same equation (7) (step S33).
6-7) If the set value of the scheduled boarding time t _ab has been changed in step S336-5, the set value is changed (step S336-8) and the process exits this subroutine.

In the input determination subroutine (step S336) described above, the determination is repeatedly performed by the interrupt method at regular time intervals even after the air conditioner starts operating. The setting information is immediately executed when a change or a stop of the pre-air conditioner control is input.

Next, the output of the outdoor unit icing detection sensor 51 provided in the heat exchanger is read (step S34).
2) If the heat exchanger installed outdoors is frozen (step S343), the second thawing mode is selected (step S344), and the operation of the second thawing mode described later is performed. If the temperature is not frozen, the outside air temperature T
_AM is read (step S345), the room temperature is read from the room temperature detection sensor 56 (step S346),
The indoor humidity is read from the humidity detection sensor 54 (step S347).

[0124] Further, reads the amount of solar radiation S _T from solar radiation amount detecting sensor 52 (step S348), it reads the icing information windshield heater and / or rear window heater of a glass icing detection sensor 55 (step S34
9).

Then, defrosting control of the front and / or rear glass is performed by the glass heater control subroutine. Details of this control will be described with reference to FIG.

That is, it is determined whether or not it is 5 minutes before the scheduled boarding time t _ab (step S350). If it is 5 minutes before, the output of the glass icing detection sensor 55 is read (step S3).
51), it is determined whether or not it is frozen (step S35)
2) If it is frozen, the output of the compressor 30 of the air conditioner is minimized (step S353), and the front and / or
Alternatively, power is supplied to the rear glass heater (step S35).
4).

If three minutes have passed since the energization (step S
355), on the basis of the information of the amount of solar radiation S _T read in step S348, following the correction of the solar radiation (11)
This is performed based on the equation (step S356).

T _S = T _S -K ₂ × S _T (11) In equation (11), K ₂ is a solar radiation correction constant.

If the front glass heater and / or the rear glass heater are not frozen in step S352, the output of the humidity detection sensor 54 is read (step S357), and control branches depending on the value of the glass surface humidity (step S358). ).

If the glass surface humidity is 70% or more and less than 95%, it is determined whether or not this humidity value is smaller than the previous humidity value read in step S347 (step S359). RA as mode
It is stored in M64 (step S360), and the insolation is corrected in step S356.

When the humidity read in step S358 is less than 70%, and when the previous humidity is not smaller than the current humidity in step S359, correction of solar radiation is performed in the same manner as in step S356 (step S3).
61).

Further, if the glass surface humidity is 95% or more in step S358, the glass heating mode for evaporating the condensed water droplets is set (step S36).
1) The output of the compressor 30 of the air conditioner is minimized (step S362), and the glass heater is energized (step S363). After a lapse of one minute from the energization (step S364), the insolation is corrected in step S356.

Then, the control mode determination routine of the air conditioner from step S294 to step S326 is processed again (step S366), and it is determined whether the mode is ventilation, first heating, cooling, first dehumidification or pause. ,
Reading the charging current I _C from the charging and discharging current detecting sensor 53 (step S368), determined by said available power P that can be used in air-conditioning (8) (step S370), the output of the compressor 30 from this value Is corrected (step S372).

Then, the operation in any of the modes of ventilation, first heating, cooling, first dehumidification or pause determined in the above steps is executed, and the glass heater and the seat heater are driven as required. These controls are continued until the scheduled ride time t _ab exceeds one hour, and after one hour, the process returns to step S330.

Hereinafter, embodiments of the control in each mode will be described.

The operation when the air conditioner is selectively driven in one of the cooling, ventilation, heating, dehumidifying and thawing modes is shown in FIG. 27 and thereafter.

First, the cooling mode will be described.

As can be easily understood with reference to FIGS. 27 and 28, in this cooling mode,
The first port 22a and the second port 22b are in communication with each other, and the third port 22c and the fourth port 22
d is in communication. In the bypass valve 18, the first port 18a and the second port 18b are in communication with each other, and therefore, the expansion valve 20 connected to the third port does not function here.

In the bypass valve 24, the first port 24a and the third port 24c are in communication with each other, and the first port 24a and the second port 24b are shut off. Further, in the bypass valve 26, the first port 26a and the third port 26c communicate with each other, and the communication between the first port 26a and the second port 26b is shut off.

Referring to the damper, as easily understood from FIG. 28, the damper 38 is opened and the damper 40 is opened.
Is also open. The damper 42 is closed and the dampers 44 and 46 are open. The blowout damper 41a is closed and the blowout damper 41b is opened. Further, the blowout damper 43 at the leg is in a closed state.

In the above state, the indoor heat exchanger 14 operates to control the air temperature discharged from the room, and the indoor heat exchanger 12
Performs auxiliary and dehumidification functions of 4. Therefore, the indoor heat exchangers 14 and 12 perform heat exchange from warm air to cool air. In other words, the air in the room reaches the fan 32 through the damper 38, the forced air is forced by the fan 32, reaches the indoor heat exchanger 12, and further reaches the indoor heat exchanger 14.

Then, the low-temperature, low-pressure gas that has passed through the expansion valve 28 undergoes heat exchange with the indoor heat exchangers 12 and 14, and
Therefore, cool air is supplied to the driver from the blowout damper 41b. The low-pressure, high-temperature gas that has passed through the indoor heat exchanger 14 passes through the first port 22 a of the four-way valve 22 through the second port 2.
2b, and the pressure is raised to a high temperature by the compressor 30, and the third port 22c and the fourth port 2 of the four-way valve 22
It reaches the outdoor heat exchanger 16 through 2d. Here, since the damper 44 is opened, outside air is introduced into the room,
The high-pressure, low-temperature gas is heat-exchanged through the outdoor heat exchanger 16 with the outside air forcibly introduced under the urging action of the fan 34, and the high-pressure, low-temperature gas is exchanged with the third valve of the bypass valve 24.
From the port 24c, it reaches the bypass valve 26 via the first port 24a.

In the cooling mode, since the first port 26a and the third port 26c of the bypass valve 26 are in communication with each other, the high-pressure, low-temperature gas is supplied to the expansion valve 28.
, Where the pressure and the temperature of the indoor heat exchanger 1 are reduced.
2 to the indoor heat exchanger 14, and this cycle is repeated. In this case, the cooling mode does not change between the normal air conditioner control and the pre-air conditioner control. That is, there is one cooling mode.

Next, the ventilation mode will be described with reference to FIGS.
9 will be described.

In the ventilation mode, the air in the room of the electric vehicle 10 is ventilated by introducing the outside air.
The indoor heat exchangers 12, 14 and the outdoor heat exchanger 16 are off. However, the fan 32 is in a state of being energized to forcibly introduce outside air into the room of the electric vehicle 10. Here, the damper 36 is opened and the damper 38 is opened.
Is closed, the blowout damper 41b is opened, and the damper 40 is also in the opened state. Further, the damper 42 is opened, and the damper 46 is also in the opened state. Here, if necessary, the damper 44 is opened, and the outside air is forcibly introduced also from the rear of the electric vehicle 10.
Can be driven to further force the air in the room of the electric vehicle 10 to the outside. It will be easily understood from FIG. 29 that the remaining dampers are in the closed state.

The opening of the damper 44 is also used when the cooling of the prime mover is insufficient due to only the indoor ventilation or when cooling air is introduced from the outside. This ventilation mode is used when the air conditioner is in the normal air conditioner control state or in the pre-acon control state.

Next, the heating mode will be described with reference to FIGS. 27, 30 and 31.

In the heating mode, heating is performed basically without introducing outside air into the room of the electric vehicle 10. Here, the first port 22a and the third port 22c of the four-way valve 22 are in communication with each other, and the second port 22b
And the fourth port 22d communicate with each other. Further, in the bypass valve 24, the first port 24a and the third port 2
4c is connected to the first port 2 in the bypass valve 26.
6a and the third port 26c are in communication. further,
In the bypass valve 18, the first port 18a and the second port 18b communicate.

The damper will be described. In FIG. 30, the damper 38 is opened, and the blowout dampers 41a, 41b are closed. The blowout damper 43 is opened,
The damper 40 is in an open state. The damper 42 is closed, and the dampers 44 and 46 are open. Fan 3
2, 34 are energized respectively, and the indoor heat exchangers 12, 1
Numerals 4 act to exchange heat between cool air and warm air, respectively, and the outdoor heat exchanger 16 has a function of introducing cool air to make warm air.

The operation will be described with reference to FIGS. 27 and 30.

The first port 24a and the third port 24c of the bypass valve 24 are in communication with each other. Therefore, low-temperature, low-pressure gas is introduced into the outdoor heat exchanger 16. Here, the outside air introduced from the opened damper 44 undergoes heat exchange, and high-temperature, low-pressure gas is introduced into the compressor 30. That is, the high-temperature, low-pressure gas flows from the fourth port 22d of the four-way valve 22 to the second port 22b, passes through the compressor 30, reaches the third port 22c to the first port 22a, and then passes through the indoor heat exchanger. Reach 14 Here, the high-pressure, high-temperature gas from the compressor 30 undergoes heat exchange, becomes high-pressure, low-temperature, further reaches the first port 18a from the second port 18b of the bypass valve 18, passes through the indoor heat exchanger 12, and further cools. A high pressure state is reached and the expansion valve 28 is reached. Here, the low-temperature, low-pressure gas is supplied from the third port 26c of the bypass valve 26 to the first port 26c.
It reaches the outdoor heat exchanger 16 again through the port 26a.
Therefore, the driver is supplied with warm air as shown by the arrow.

FIG. 31 shows a case where introduction of outside air by the inside / outside air changeover switch 76e is selected in the heating mode. In this case, the damper 36 is opened to introduce the outside air into the room of the electric vehicle 10, and the damper 42 is also in the opened state. The damper 38 is in a half-open state. The remaining points are the same as in the heating mode. The outside air introduction in this heating mode is excellent in the function of introducing outside air into the room,
As shown in FIG. 1, if the damper 38 is half-opened, the ventilation of air from the outside air into the room is further performed, which is preferable.

Next, the dehumidification mode will be described. The dehumidification mode is for lowering the humidity in the room of the electric vehicle 10 and performs dehumidification only in the interior of the electric vehicle 10, and also performs dehumidification by introducing a part of air from the outside into the interior of the electric vehicle 10. This is the mode to perform.

The first dehumidification mode will be described with reference to FIGS. 27 and 32. At this time, the indoor heat exchanger 20
Performs heat exchange from cold air to warm air, and the indoor heat exchanger 12 performs heat exchange from warm air to cold air. In the bypass valve 18 interposed therebetween, the first port 18a and the third port 18c are in communication with each other.
6, the first port 26a and the third port 26c are in communication with each other, and the bypass valve 24 is connected to the first port 24a.
And the second port 24b are in communication. In the four-way valve 22, the first port 22a and the third port 22c are in communication, and the second port 22b and the fourth port 22d are in communication. The fan 32 is in the driving state and the fan 3
4 is also in a driving state.

As for the damper, the damper 36 is closed and the damper 38 is opened.
The blowing damper 41a is opened, and the blowing damper 41b is opened.
Is closed. Then, the blowout damper 43 is closed, while the damper 40 is open. Further, the damper 42 is closed, and the dampers 44 and 46 are open.

[0156] The above-mentioned arrangement state makes the dehumidifying capacity medium and the heating capacity low. Damper 4
By opening 4, 46, the exhaust heat of the prime mover is ventilated through the outside air.

In the above configuration, first, at high temperature,
High-pressure gas is led out of the compressor 30 and the four-way valve 2
2 also communicates from the third port 22c to the first port 22a, which is introduced into the indoor heat exchanger 14. At this time,
In the indoor heat exchanger 14, heat exchange with the cool air sent from the indoor heat exchanger 12 is achieved, and the indoor air is supplied from the blow-out damper 41a into the room as warm air.

On the other hand, the heat-exchanged low-temperature, high-pressure gas is
It reaches the expansion valve 20 and is replaced with low-temperature, low-pressure gas.
This is introduced into the indoor heat exchanger 12. Indoor heat exchanger 1
2 is supplied with high-temperature air in the room under the driving action of the fan 32, so that heat is exchanged with the low-pressure and low-temperature gas, and the gas reaches the expansion valve 28, and the high-pressure and low-pressure gas is supplied to the bypass valve 26 as a high-temperature and low-pressure gas. From the 3 port 26c, it reaches the bypass valve 24 via the first port 26a.

In the bypass valve 24, the first port 24
a and the second port 24b are in communication with each other, while the third port
Since the port 24c is closed, the port 24c reaches the four-way valve 22, and reaches the compressor 30 from the fourth port 22d of the four-way valve 22 via the second port 22b. Here, the temperature is raised to a high temperature and the pressure reaches the indoor heat exchanger 14 again.

As will be understood from the above description, this first
In the dehumidification mode, the indoor heat exchanger 14 supplies cool air to the room as warm air, while the indoor heat exchanger 12 supplies warm air to the indoor heat exchanger 14 as cool air. Therefore, it is possible to perform dehumidification and to warm the room at a temperature that is not so high. The prime mover for driving the compressor 30 is cooled by the outside air under the opening operation of the damper 44, and the warm air generated thereby is cooled by the fan 34.
Is released from the damper 46 to the outside under the urging action.

Next, the second dehumidification mode will be described.
In the second dehumidification mode, the dehumidification capacity is higher than in the first dehumidification mode, and the heating capacity is increased from low to medium.
For this reason, as easily understood from FIG. 33, the bypass valve 24 is switched, the first port 24a and the third port 24c are communicated, and the second port 24b is closed. Therefore, the high-temperature, low-pressure gas supplied from the expansion valve 28 reaches the outdoor heat exchanger 16. In this case, the difference from FIG. 32 is that the damper 36 is opened, while the damper 38
Has a smaller opening than that shown in FIG.
Then, the damper 42 is opened.

As a result, the outside air is introduced through the damper 36 rather than the recirculation of the indoor air, and the indoor air is supplied to the outdoor heat exchanger 16 under the opening action of the damper 42. In other words, the outdoor heat exchanger 16 plays a role of absorbing the dehumidified warm air of the medium to low temperature sent from the room and guiding it to the outside via the damper 46.

Further, when the outside air introduction of the inside / outside air changeover switch 76e is selected by manual operation, outside air is introduced and dehumidification is performed. In this case, the difference from the second dehumidification mode is that, as shown in FIG. 34, the damper 36 is completely opened, and the damper 42, the damper 44, and the damper 4
6 has been opened. As a result, the introduction of outside air can be further increased, the dehumidification capacity can be increased, and the heating capacity can be suppressed low.

Finally, the decompression mode will be described. The decompression mode is divided into a first decompression mode and a second decompression mode. In the first thawing mode, the gas is configured to pass through all the indoor heat exchangers 12 and 14 without passing through the expansion valve 28, and thus, while sending warm air into the room, for example,
Ice or the like attached to the outdoor heat exchanger 16 can be removed. In the second thawing mode, the thawing ability is further enhanced,
On the other hand, warm air is not supplied to the room.

The first decompression mode will be described first with reference to FIGS. 27 and 35. In this case, the indoor heat exchangers 12 and 14 play a role of exchanging heat from cold air to warm air. In addition, the outdoor heat exchanger 16 fulfills the role of changing cold air into warm air. Describing the damper, the damper 36 is closed, and the blowing dampers 41a,
1b is also in a closed state. The blowout damper 43 is opened,
The dampers 38 and 40 are completely opened. The damper 42 is closed, and the dampers 44 and 46 are also closed. The four-way valve 22 has a first port 22a and a third port 2
2c is connected to the second port 22b and the fourth port 22d.
Is in communication. In the bypass valve 24, the first port 24a communicates with the third port 24c. In the bypass valve 18, the first port 18a communicates with the second port 18b. In the bypass valve 26, the first
The port 26a and the second port 26b are in communication.
The fan 32 is driven, and the fan 34 is also driven.

In the above configuration, in the first decompression mode, first, the high temperature derived from the compressor 30
High pressure gas is introduced into the indoor heat exchanger 14. At this time, the indoor heat exchanger 14 functions to further increase the temperature of the warm air exchanged from the indoor heat exchanger 12, and the air thus warmed is supplied to the feet of the driver.

On the other hand, the high-temperature, high-pressure gas further passes through the indoor heat exchanger 12 and reaches the bypass valve 26 without passing through the expansion valve 28. Second port 26b and first port 26
Depending on the state of communication with the gas a, the high-temperature and high-pressure gas further reaches the bypass valve 24, and from the first port 24a to the outdoor heat exchanger 16 via the third port 24c, where heat is exchanged. In the indoor heat exchanger 12, as described above, the gas is in a low-temperature and high-pressure state in order to further warm the indoor air and send it to the indoor heat exchanger 14. Therefore, the gas is exchanged by the outdoor heat exchanger 16. To warm the air.
Therefore, ice attached to the surface of the outdoor heat exchanger 16 and the like is thawed by this warm air.

The second decompression mode will be described with reference to FIGS. 27 and 36. In this case, the difference from the first thawing mode is that the damper 40 is completely closed and the flow shown in FIG. 27 is completely opposite. And the indoor heat exchanger 14 plays a role of turning warm air into cool air, and the indoor heat exchanger 12 plays a role of turning cold air into warm air. Also, the bypass valve 18
Communicates the first port 18a and the third port 18c to operate the expansion valve 20. The four-way valve 22 is the first port 22a
And the second port 22b are in communication with each other, and the third port 2
2c and the fourth port 22d are in communication.

Therefore, the compressor 30 is operated at a high temperature,
The high-pressure gas flows from the third port 22c of the four-way valve 22 to the fourth port 22d.
To reach. Here, the gas is cooled by cold air and reaches the bypass valve 24 as a high-pressure, low-temperature gas. From the bypass valve 24 to the bypass valve 2
6 and reaches the indoor heat exchanger 12. The gas heat exchange in the outdoor heat exchanger 16 changes the surrounding air from cold air to warm air, so that ice or the like attached to the surface of the outdoor heat exchanger 16 can be thawed.

[0170] The gas that has passed through the bypass valve 26 reaches the indoor heat exchanger 12. In the indoor heat exchanger 12, since the cool air is forcibly sent to the indoor heat exchanger 12 under the driving action of the fan 32, the high-pressure, low-temperature gas is further lowered in the indoor heat exchanger 12, while This indoor heat exchanger 1
The warmed air after passing through 2 reaches the indoor heat exchanger 14. Here, the high-pressure, low-temperature gas obtained from the indoor heat exchanger 12 reaches the indoor heat exchanger 14 via the expansion valve 20, and performs heat exchange between warm air and cold air. Then, the high-temperature, low-pressure gas is sent to the compressor 30 again through the four-way valve 22.

The above is a detailed description of each mode of cooling, ventilation, heating, dehumidification and thawing.

According to the present embodiment, as described above, when it is determined that the windshield cannot be seen through at the operation start time set based on the preset boarding scheduled time, the control means is controlled. As a result, the glass heating means is urged to remove the icing or dew condensation. Therefore, the driver can immediately drive the vehicle while riding. Also, since the glass heating means is energized immediately before the boarding time,
After the glass is made transparent, no extra power is consumed to maintain the state. Further, when the hot air is blown to the windshield by the compressor 30 and the fan 32 as the glass heating means, and the heating glass is urged, the output of the compressor 30 or the blowout amount of the hot air is suppressed to the minimum operation. Therefore, most of the available power is supplied to the heat-generating glass to efficiently release the dew condensation or icing state of the windshield.

[0173]

According to the present invention, as described above, when the operation start time set on the basis of the scheduled vehicle entry time set by the preset means is reached, the icing or dew state of the window is detected by the sensor. If detected by the control means, the glass heating means is energized by the control means,
This frozen state or dew state is removed. In this way, when the driver tries to start traveling, it is possible to reliably obtain the see-through state of the window, and to start traveling in a safe and calm atmosphere.

Further, since the operation start time of the glass heating means is set based on the scheduled boarding time, a good see-through state is achieved at the scheduled boarding time. Therefore, no further power is used to maintain the state after the window can be made transparent, and power consumption can be suppressed.

Further, according to the present invention, the glass heating means comprises a hot air blowing means and a glass heat generating means, and the glass heating means having a large temperature rising amount and a large power consumption is blown out by the hot air blowing means. When used together with the means, the amount of hot air blown out or the output of the compressor is suppressed, and most of the available electric energy can be used for the glass heating means, and the window can be made transparent in a short time and efficiently. I do.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of an electric vehicle that implements a glass see-through control system for a vehicle according to the present invention.

FIG. 2 is a schematic explanatory diagram of control means including the arrangement of various sensors of the embodiment shown in FIG.

FIG. 3 is a detailed explanatory diagram of a control system of the embodiment shown in FIG. 1;

FIG. 4 is an explanatory diagram of an operation panel of the embodiment shown in FIG.

FIG. 5 is a flowchart showing the entire operation of the normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 6 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 7 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 8 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 9 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 10 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 11 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 12 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

13 is a diagram illustrating output current control of a battery in the normal air conditioner mode shown in FIG.

FIG. 14 is a flowchart showing a control operation in a normal air conditioner mode of the embodiment shown in FIG. 1;

FIG. 15 is a flowchart showing an overall operation in a pre-air-conditioning mode of the embodiment shown in FIG. 1;

FIG. 16 is a flowchart showing an overall operation in a pre-air-conditioning mode of the embodiment shown in FIG. 1;

FIG. 17 is a flowchart showing an overall operation in a pre-air-conditioning mode of the embodiment shown in FIG. 1;

FIG. 18 is a flowchart showing a control operation of an operation input subroutine in the pre-air conditioner mode shown in FIGS. 15 to 17;

FIG. 19 is a flowchart showing a control operation in a pre-air-conditioning mode of the embodiment shown in FIG. 1;

FIG. 20 is a flowchart showing a control operation in a pre-air conditioner mode of the embodiment shown in FIG. 1;

FIG. 21 is a flowchart showing a control operation in a pre-air conditioner mode of the embodiment shown in FIG. 1;

FIG. 22 is a flowchart showing a control operation in a pre-air conditioner mode of the embodiment shown in FIG. 1;

FIG. 23 is a flowchart showing a control operation in a pre-air-conditioning mode of the embodiment shown in FIG. 1;

FIG. 24 is a flowchart showing a control operation of an input determination subroutine in the pre-air-conditioning mode shown in FIGS. 19 to 23;

FIG. 25 is a flowchart showing a control operation of a glass heater control subroutine in the pre-air conditioner mode shown in FIGS. 19 to 23;

FIG. 26 is a flowchart showing a control operation in a pre-air conditioner mode of the embodiment shown in FIG. 1;

FIG. 27 is a list for explaining the operation of each air conditioner mode in the embodiment shown in FIG. 1;

FIG. 28 is a diagram showing an operation in a cooling mode of the embodiment shown in FIG. 1;

FIG. 29 is a diagram showing the operation in the ventilation mode of the embodiment shown in FIG. 1;

FIG. 30 is a diagram showing an operation in the heating mode of the embodiment shown in FIG. 1;

FIG. 31 is a diagram showing the operation in the heating mode of the embodiment shown in FIG. 1;

FIG. 32 is a diagram showing an operation in a first dehumidification mode of the embodiment shown in FIG. 1;

FIG. 33 is a diagram showing an operation in a second dehumidification mode of the embodiment shown in FIG. 1;

FIG. 34 is a diagram showing an operation in a third dehumidification mode of the embodiment shown in FIG. 1;

FIG. 35 is a diagram showing an operation in a first decompression mode of the embodiment shown in FIG. 1;

FIG. 36 is a diagram showing an operation in a second decompression mode of the embodiment shown in FIG. 1;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 ... Electric vehicle 12,14 ... Indoor heat exchanger 16 ... Outdoor heat exchanger 18,24,26 ... Bypass valve 20,28 ... Expansion valve 22 ... 4-way valve 30 ... Compressor 32,34 ... Fans 36,38,40 , 41a, 41b, 42, 43, 4
4, 46 ... Damper 50 ... Inverter 51 ... Outdoor unit icing detection sensor 52 ... Solar radiation detection sensor 53 ... Charge / discharge current detection sensor 54 ... Temperature detection sensor 55 ... Glass icing detection sensor 56 ... Indoor temperature detection sensor 57 ... Door opening / closing detection Sensor 58: Window open / close detection sensor 59: Discharge depth detection sensor 60: Outside air temperature detection sensor 61: Sheet pressure sensor 62: CPU 64: RAM 74: Operation panel

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁶ , DB name) B60S 1/00-1/68

Claims (2)

(57) [Claims] 1. A sensor which is provided at least in or near a window of a vehicle and outputs a signal for determining the presence or absence of a see-through state of the window, and a judging means for judging a see-through state of the window based on a detection signal of the sensor. A glass heating means driven by an internal battery of the vehicle to heat the window; a presetting means for setting a scheduled riding time before traveling of the vehicle; and a scheduled riding time determined by the preset means. relative to, upon reaching a preset operation start time, if the window by the discriminating means has determined that it is impossible perspective, Bei example and a control means for biasing the glass heating device, wherein glass heating device is provided with a warm air blowoff means blowing hot air on the window, and a glass heat generating means of said window, said Control means, when said biasing the warm air blowout means the glass heat generating means at the same time, the glass fluoroscopic control system for a vehicle, characterized in that to suppress the hot air balloon of the hot air blowout section. 2. At least at or near a vehicle window.
It is provided beside and determines the presence or absence of the see-through state of the window.
And a detection signal from the sensor to determine the see-through state of the window.
Determining means, a glass heating means for heating the window, and a presetting means for setting a scheduled riding time before traveling of the vehicle.
With reference to the scheduled ride time determined by the preset means and the preset means.
When the preset operation start time is reached,
The window was determined to be invisible by another means
If, and a control means for biasing the glass heating device, said glass heating device is provided with a warm air blowoff means blowing hot air on the window, and a glass heat generating means of said window, said The hot-air blowing means connects one or more heat exchangers, a switching valve, a compressor, and an expansion valve, which are provided inside the vehicle for air-conditioning the interior of the vehicle before traveling of the vehicle, through a pipeline. including the gas circulation system for circulating the gas for heating and cooling and
Seen, the gas circulation system is external voltage is connected to the front running of the vehicle
Is driven by the source, said control means, the hot air is supplied to the windshield under the biasing action of the compressor <br/> suppressor constituting the gas circulation system,
At the same time when said via an external power supply for biasing said glass heat generating means, the glass fluoroscopic control system for a vehicle, characterized in that to suppress the output of the compressor.