DE102012203564A1 - Air conditioning for one vehicle - Google Patents

Abstract

An air conditioning system comprises a heat pump cycle (20) with an outdoor heat exchanger (25); a frost condition calculator (42) that calculates a degree of frost that has formed in the outdoor heat exchanger; an output section (37b) that outputs information about the frost formed in the outdoor heat exchanger; and a controller (40) that instructs a defrosting operation for melting the frost by controlling the heat pump cycle. The controller controls the output section to output the frost degree when the defrosting operation is not performed, and controls the output section to output defrosting information representing that the defrosting operation is performed when the defrosting operation is performed.

Description

The present invention relates to an air conditioner for a vehicle.

An air conditioning system for a vehicle includes an outdoor heat exchanger in which refrigerant exchanges heat with outside air. When a temperature of the outside air is low, the outdoor heat exchanger may have frost. In this case, heat can not be exchanged with the outside air, so that the heating capacity of the air conditioner is reduced.

In JP-A-53-119449 For example, a frost condition of an outdoor heat exchanger is determined using a difference between a temperature of outside air and an evaporation temperature of refrigerant in the outdoor heat exchanger. When it is determined that the frost is generated, a defrosting operation for defrosting the outdoor heat exchanger is performed, and it is described in, for example, FIG JP-U-55-5002 reported using a light that the de-rusting operation is performed.

However, an occupant of a vehicle is not notified when the defrosting operation is to be started. When the defrosting operation is started before the occupant is notified, the occupant may feel uncomfortable because the air conditioning capacity is reduced while the defrosting operation is being performed. Further, since the air conditioning can not be performed while the defrosting operation is performed, no fogging can be removed from a windshield of the vehicle during the defrosting operation.

It is an object of the present disclosure to provide an air conditioner for a vehicle that notifies information about a defrosting operation.

According to an example of the present disclosure, an air conditioner for a vehicle includes a heat pump cycle, a frost condition calculator, an output section, and a controller. The heat pump cycle includes an outdoor heat exchanger that condenses high pressure refrigerant by exchanging heat with outside air. The frost condition calculator calculates a degree of frost that has formed in the outdoor heat exchanger. The output section outputs information about the frost to an occupant of the vehicle. The controller performs a defrosting operation for melting the forest adhering to the outdoor heat exchanger by controlling a component of the heat pump cycle. The controller controls the output section to output the degree of frost calculated by the frost condition calculator as frost information when the defrosting operation is not performed. The controller controls the output section to output defrosting information representing that the defrosting operation is performed when the defrosting operation is performed.

Consequently, the occupant can know the frost information and the defrost information.

The foregoing and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:

1 Fig. 10 is a schematic view illustrating an air conditioner according to an embodiment;

2 Fig. 10 is a block diagram illustrating a control structure of the air conditioner;

3 Fig. 10 is a block diagram illustrating a defrosting operation of the air conditioner;

4 FIG. 12 is a graph illustrating a relationship between an outside air temperature and a refrigerant temperature in an outdoor heat exchanger of the air conditioning system; FIG.

5 Fig. 10 is a graph illustrating a relationship between the outside air temperature and a first threshold;

6 Fig. 12 is a graph illustrating a relationship between the outside air temperature and a second threshold;

7 Fig. 15 is a graph illustrating a relationship between the outside air temperature and a third threshold;

8th FIG. 15 is a graph illustrating a relationship between a temperature difference between the outside air temperature and the refrigerant temperature and a frost level; FIG.

9 FIG. 15 is a graph illustrating a relationship between a defrosting operation elapsed time and the refrigerant temperature; FIG.

10 is an image displayed in a normal operation of the air conditioner;

11 is an image displayed when frost is generated in the outdoor heat exchanger;

12 is an image displayed in the defrosting operation; and

13 is an image displayed in the defrosting operation to indicate a remaining period for the defrosting operation.

(Embodiment)

An air conditioner 10 according to one embodiment, has a heat pump cycle 20 and an air conditioning unit 30 and performs, for example, the air conditioning for a hybrid vehicle, electric vehicle or fuel cell vehicle. The air conditioner 10 is configured to perform at least one heating operation, cooling operation and defrosting operation. The defrosting operation is performed to melt frost adhering to a heat exchanger by releasing heat. The in 1 shown heat pump cycle 20 is an example on the air conditioning 10 is applied in the cycle 20 the refrigerant flow has a heating circuit for heating operation or has a cooling circuit for the cooling operation.

The heat pump cycle 20 Specifically, the cooling operation using an evaporator performs the cooling operation or the heating operation for a passenger compartment of the vehicle using the state change of the refrigerant flowing through the cycle 21 carried out, and the heating operation is using an indoor heat exchanger 22 carried out. The refrigerant may be carbon dioxide whose pressure becomes equal to or higher than a supercritical pressure.

As in 1 shown has the heat pump cycle 20 an electric compressor 23 , the indoor heat exchanger 22 , an electric valve 26 , an outdoor heat exchanger 25 , an electric valve 24 , the evaporator 21 and an accumulator 27 which are annularly connected using a pipeline to form the circuit

The first electric valve 24 is in a first branch passage 24c arranged, extending from the outdoor heat exchanger 25 to the evaporator 21 extends, and a first bypass passage 24a extends to the valve 24 to get around. A first electromagnetic valve 24b is in the first bypass passage 24a disposed and in a parallel relationship with the first electrical valve 24 ,

The second electric valve 26 is in a second branch passage 26c arranged, extending from the indoor heat exchanger 22 to the outdoor heat exchanger 25 extends, and a second bypass passage 26a extends to the valve 26 to get around. A second electromagnetic valve 26b is in the second bypass passage 26a disposed and in a parallel relationship with the second electrical valve 26 ,

The first electric valve 24 is an expansion valve (decompressor), the refrigerant at the time of cooling operation before flowing into the evaporator 21 decompressed. For example, the valve 24 an electric control valve that can flexibly control the opening area of the refrigerant passage.

The first electromagnetic valve 24b opens or closes the first bypass passage 24a , The first detour passage 24a is closed in the cooling mode and is open in the heating mode.

The refrigerant passage extending from the refrigerant outlet of the outdoor heat exchanger 25 extends, branches into the first branch passage 24c connected to the refrigerant inlet of the evaporator 21 connected, and the first bypass passage 24a , bypassing the evaporator 21 with the refrigerant inlet of the accumulator 27 connected is.

The first branch passage 24c further extends from the refrigerant outlet of the evaporator 21 and is with the first bypass passage 24a adjacent to the refrigerant inlet of the accumulator 27 connected. The first electric valve 24 is in the first branch passage 24c on the inlet side of the evaporator 21 arranged. The first electromagnetic valve 24b is in the first bypass passage 24a arranged.

A refrigerant temperature sensor 25a is on the outlet side of the outdoor heat exchanger 25 arranged. The refrigerant temperature sensor 25a is a refrigerant temperature detecting means which detects the refrigerant temperature in the outlet part of the outdoor heat exchanger 25 detected.

The electric compressor 23 is powered by electricity supplied from a battery (not shown) in the vehicle, which is a storage battery, and compresses refrigerant and discharges the high-temperature and high-pressure refrigerant. A speed of the compressor 23 is controllable

An AC voltage is applied to the compressor 23 applied, and a frequency of the voltage is from an inverter 23a from 2 set. Thus, a rotational speed of an electric motor 23m of the compressor 23 controlled. DC power (DC) is transferred from the battery in the vehicle to the inverter 23a fed, and a controller 40 controls the inverter 23a ,

The electric compressor 23 may be a variable capacity compressor that can not gradually change the compression capacity of refrigerant. The accumulator 27 is a Container in which the refrigerant is separated into vapor and liquid before the refrigerant enters the electric compressor 23 flows.

An ejection pressure sensor 23b is at the refrigerant outlet of the compressor 23 arranged and detects the pressure of refrigerant coming from the compressor 23 is ejected, on the high pressure side. A signal coming from the discharge pressure sensor 23b is captured, is in the controller 40 entered. Moreover, the controller calculates 40 a high pressure side temperature from the detected pressure in the circuit.

That of the compressor 23 discharged refrigerant flows into the indoor heat exchanger 22 , In the heating mode, heat is transferred between the high pressure refrigerant and air passing through a warm air passage 31a flows, exchanged, leaving the heat exchanger 22 the air heats.

The second electric valve 26 is an expansion valve (decompressor), that of the indoor heat exchanger 22 cooled refrigerants decompressed at the time of heating operation. For example, the valve 26 an electronic control valve that flexibly controls the opening area of the refrigerant passage. The second electromagnetic valve 26b opens or closes the second bypass passage 26a , The second bypass passage 26a is closed in the heating mode and is open in the cooling mode.

The outdoor heat exchanger 25 is located outside the passenger compartment of the vehicle. Heat is between outdoor air, that of an outdoor fan 28 is forcibly ventilated, and replaced the refrigerant. In the heating operation, this flows from the second electric valve 26 decompressed refrigerant in the outdoor heat exchanger 25 and absorbs heat from the outside air. In the cooling operation, the high-pressure refrigerant releases heat to the outside air. The outdoor heat exchanger 25 condenses out of the inner heat exchanger 22 flowing refrigerant by exchanging heat with the outside air.

In the heating operation, the refrigerant does not flow to the evaporator 21 , In the cooling mode, the evaporator cools 21 the air that should be carried into the passenger compartment because of the evaporator 21 flowing refrigerant absorbs heat

In the heating mode, the first electromagnetic valve 24b opened, and the second electromagnetic valve 26b is closed. The first electric valve 24 is closed by a 0-pulse control, and the second electric valve 26 is controlled to have a required decompression amount. It flows in the heating mode of the heat pump cycle 20 Refrigerant, as in a dashed arrow in 1 shown in the order of the accumulator 27 , the compressor 23 , the indoor heat exchanger 22 , the second electrical valve 26 , the outdoor heat exchanger 25 , the first electromagnetic valve 24b and the accumulator 27 ,

In the cooling mode, the first electromagnetic valve 24b closed, and the second electromagnetic valve 26b is open The second electric valve 26 is closed by a 0-pulse control, and the first electric valve 24 is controlled to have a required decompression amount. Thereby flows in the cooling operation of the heat pump cycle 20 Refrigerant, as in a Strichpunktpfeillinienrichtung in 1 shown in the order of the accumulator 27 , the compressor 23 , the indoor heat exchanger 22 , the second electromagnetic valve 26b , the outdoor heat exchanger 25 , the first electric valve 24 , the evaporator 21 , and the accumulator 27 ,

The air conditioning unit 30 is described. The unit 30 Provides the conditioned air to the passenger compartment and has a housing 31 that is the outer shape of the unit 30 Are defined. For example, the unit is 30 arranged on the back of an instrument panel in front in the Fahrgrastrum. The housing 31 defines an air passage inside. A first end of the passage has an inlet 32a for the outside air and an inlet 32b for indoor air. A second end of the passage has at least one face opening (not shown), a foot opening (not shown) and a defroster opening (not shown) through which conditioned air flows into the passenger compartment. The housing 31 consists of several molded products made of resin such as polypropylene.

The conditioned air is blown through the face opening toward an upper body of the occupant in the passenger compartment. The conditioned air is blown through the foot opening toward a foot of the occupant in the passenger compartment. The conditioned air is blown through the defroster opening toward an inside of a windshield of the vehicle. Each port is connected to the passenger compartment through a duct (not shown) and is opened / closed based on the air outlet mode by a switchover flap (not shown).

The interior air intake 32b and the outside air intake 32a be shut up 32 opened or closed based on the air intake mode, and the opening degree of the inlet 32b . 32a can from the fold 32 be controlled flexibly An angle of the flap 32 is powered by an actuator, like about a servomotor 32m , controlled, and the outside air and / or the inside air is through the inlet 32b . 32a in the case 31 sucked. Consequently, the air intake mode is set from an inside air circulation mode, an outside air introduction mode, and a middle mode having both the inside air circulation and the outside air introduction.

The housing 31 has a control box 32c and a fan 33 , The flap 32 is in the box 32c arranged. An inlet part of the blower 33 is with the exhaust air inlet 32a and the inside air intake 32b connected. In the heating operation, when the outside air intake mode is selected, the outside air intake becomes 32a Introduced outside air with low humidity and is blown to the inside of the windshield after it has been prepared in the passage, so that the anti-fog effect can be achieved. When the inside air circulation mode is selected, the inside air intake becomes 32b Indoor air is introduced at high temperature and is blown to the foot of the occupant after being processed in the passage, so that the heating load can be reduced.

The fan 33 has a centrifugal multi-wing fan 33a (for example sirocco fan) and a motor 33m who is the fan 33a drives The circumference of the centrifugal fan 33a is from a volute casing 33a surround. The air outlet of the blower 33 is connected to an air passage which is defined to be in the centrifugal direction of the fan 33a extends.

The air passage crosses the evaporator 21 on the upstream side in the air flow direction Further, the air passage has a cooling air passage 31b and the warm air passage 31a downstream of the evaporator 21 in the air flow direction In addition, the air passage has a mixing space 31c in which air coming out of the cooling air passage 31b flows, and air coming out of the warm air passage 31a flows, be mixed The evaporator 21 is downstream of the blower 33 in the case 31 arranged and the indoor heat exchanger 22 and the air mix door 34 are downstream of the evaporator 21 in the case 31 arranged.

The evaporator 21 is arranged such that it covers the entire passage immediately after the blower 33 crosses. Almost the whole of the blower 33 Blown air passes through the evaporator 21 , The evaporator 21 corresponds to a cooling heat exchanger that cools air before passing through the cooling air passage in the cooling operation and the defrosting operation 31b flows because refrigerant inside the evaporator 21 flows, absorbs heat from the air An evaporator temperature sensor 21a is at the outlet part of the evaporator 21 arranged and detects the temperature of air coming from the evaporator 21 is cooled. That of the temperature sensor 21a detected signal is in the controller 40 entered.

The indoor heat exchanger 22 is in the warm air passage 31a arranged, and the warm air passage 31a is from the air mix door 34 opened and closed. The air mix door 34 is an air flow control, which is the amount of air (hot air) that the indoor heat exchanger 22 should go through, relative to the air coming from the air inlet 32a . 32b is sucked controls. The air, the evaporator 21 passes through the air mix door 34 in a predetermined ratio flexible in air, which is the indoor heat exchanger 22 should go through, and air, the indoor heat exchanger 22 to handle, separately

A servomotor 34m the flap 34 closes a part or the whole passage 31a . 31b by changing a position of the flap 34 , An opening degree of the warm air passage 31a is from the air mix door 34 controlled in a range between 0% and 100%. The air enters the indoor heat exchanger based on the degree of opening 22 one. Moreover, an opening degree of the cooling air passage becomes 31b from the air mix door 34 controlled and changes inversely proportional to the opening degree of the hot air passage 31a , The opening degree of the cooling air passage 31b is controlled in a range between 0% and 100%.

The indoor heat exchanger 22 In the heating mode, it heats air through the hot air passage 31a flows because refrigerant that is inside the heat exchanger 22 flows, gives off heat in air. An outside air temperature sensor 35 detects a temperature of the outside air, and an inside air temperature sensor 36 detects a temperature of the interior air of the passenger compartment.

A control panel (CP) 37 is with a control panel 37a and a display part 37b fitted. The control panel 37a is constructed, for example, by a touch-sensitive switch connected to the display part 37b is integrated, or consists of a mechanical switch. Various instruction signals are sent through the keypad 37a into the controller 40 entered. The air outlet mode can be controlled by the control panel 37a can be changed, and the mode can be changed using the keypad 37a be changed between the heating mode, the cooling mode and the defrosting.

The control panel 37a can be a starter, and the defrosting operation will start if one Instruction in the control panel 37a is entered to start the defrosting operation. Moreover, the control panel 37a be a stopping device, and the defrosting operation is stopped when an instruction in the control panel 37a is entered to stop the defrosting operation.

The display part 37b is an output section that outputs information about frost, such as a frost formation level, to an occupant in the passenger compartment of the vehicle. In particular, the display part leaves 37b inform the inmates visually. The display part 37b may be made of a liquid crystal display, for example. The display part 37b shows different types of information by the controller 40 be provided on a screen. For example, the display part shows 37b the current air outlet mode and / or the current mode of operation on the display part shows 37 Information as to whether the defrosting operation is performed or not, or information about the time it takes to complete the defrosting operation (remaining time period for the defrosting operation).

The control 40 from 2 is a controller that controls the air conditioning operation and the defrosting operation to the frost of the outdoor heat exchanger 25 to melt The controller 40 controls every component that controls the heat pump cycle 20 , the outdoor fan 28 , the flap 32 , the air mix door 34 and the like, based on the operating state.

The control 40 includes a microcomputer (not shown), an input circuit (not shown), an output circuit (not shown), a defrost time calculator 41 , a freeze condition calculator 42 , a defrosting operation determiner 43 , a drive state detection device 44 and a display controller 45

The signal is from the keypad 37a of the control panel 37 , which is located in the front of the passenger compartment, entered into the input circuit. Another signal is from the outside air temperature sensor 35 , the refrigerant temperature sensor 25a , the discharge pressure sensor 23b , the evaporator temperature sensor 21a and the inside air temperature sensor 36 entered.

The microcomputer has a memory such as a ROM (Read Only Memory) or RAM (Memory in which reading and writing are allowed) and a CPU (Central Processing Unit), etc. The microcomputer has various programs for calculating the proper operating state of all parts To be Controlled The microcomputer performs calculations using the various signals input to the input circuit and the various programs, and outputs a calculation result to the output circuit

The output circuit sends an output signal to the inverter 23a , the first electric valve 24 , the first electromagnetic valve 24b , the second electric valve 26 , the second electromagnetic valve 26b , the engine 28m of the external fan 28 , the engine 32m the flap 32 , the engine 33m of the blower 33 and the engine 34m the air mix door 34 and the display part 37b of the control panel 37 based on the calculation result.

The frost condition calculator 42 calculates a degree of frost formation (level) using the outside air temperature and the refrigerant temperature of the outdoor heat exchanger 25 and sends the frost formation level to the microcomputer. The degree of frost formation represents an amount of that in the outdoor heat exchanger 25 formed frost.

The defrosting plant determiner 43 determines whether or not the defrosting operation is required based on the frost formation level, and the determination result is sent to the microcomputer.

The defrost time calculator 41 calculates a time it takes to complete the defrosting operation using the frost level during the defrosting operation. The calculated time period is sent to the microcomputer.

The display control 45 controls on the display part 37b displayed image. The display control 45 generates a predetermined image based on the information provided by the microcomputer. Further, the display controller controls 45 the timing and position to display the image.

The drive state detection device 44 detects the driving state of the vehicle by detecting, for example, the speed of the vehicle and the switching state of an ignition switch (not shown). In addition, the drive state detecting device 44 be included in the variety of sensors that provide the information to the controller 40 Deploy The from the capture device 44 captured information is transmitted to the microcomputer. The switching state of the ignition switch represents the on / off of the ignition switch of the vehicle.

Operation (cooling, heating and defrosting) of the air conditioner 10 is described When an air conditioner (A / C) switch of the control panel 37a of the control panel 37 is on, activates the control 40 the compressor 23 , If the controller 40 Based on a temperature set by the occupant of the vehicle and the signals received from the plurality of sensors, it determines that the cooling operation is required, the second electromagnetic valve becomes 26b opened, and the first electromagnetic valve 24b and the second electric valve 26 are closed Furthermore, the controller controls 40 the opening degree of the first electric valve 24 so that it has a decompression amount that a required cooling ability is achieved. In addition, the controller controls 40 the air outlet switching door in such a manner that the air outlet mode for the cooling operation is set to the face mode.

In the cooling operation, the refrigerant flows in the semicolon arrow direction of FIG 1 , While that of the compressor 23 ejected gas with the high temperature and high pressure in the indoor heat exchanger 22 flows, passes through the indoor heat exchanger 22 no air, so that the amount of heat given off by the refrigerant in the indoor heat exchanger 22 is small.

The refrigerant flows through the second bypass passage 26a in the outdoor heat exchanger 25 , If the refrigerant is the outdoor heat exchanger 25 passes through, cools from the outdoor fan 28 air carried by the refrigerant by absorbing heat, so that the refrigerant reaches the haze state. The refrigerant in the vapor state flows through the passage 24c and is from the first valve 24 decompressed. The decompressed refrigerant flows into the evaporator 21 and is made by absorbing heat from air passing through the air passage of the housing 31 flows, evaporates. The refrigerant is in the accumulator 27 divided into gas and liquid and gets into the compressor 23 sucked. The one from the evaporator 21 cooled air is blown out through the face outlet toward the upper body of the occupant to cool the passenger compartment.

The refrigerant flow will be described in the case where the heating operation is performed. When the air conditioner (A / C) switch of the control panel 37a of the control panel 37 is switched on, activates the control 40 the compressor 23 If the controller 40 Based on a temperature set by the occupant of the vehicle and the signals received from the plurality of sensors, determining that the heating operation is required, the first electromagnetic valve becomes 24b opened, and the second electromagnetic valve 26b and the first electric valve 24 will be closed. Furthermore, the controller controls 40 the opening degree of the second electric valve 26 so it has a decompression amount also controls the controller 40 the air outlet switching door in such a manner that the air outlet mode is set to the foot mode or the defroster mode based on the preset temperature for the heating operation.

In the heating operation, the refrigerant flows in the dashed arrow direction of FIG 1 , While that of the compressor 23 ejected gas with the high temperature and high pressure in the indoor heat exchanger 22 flows through air passing through the warm air 31a passes through heat from the refrigerant added to cool the refrigerant. The refrigerant flows into the passage 26c and is from the second electric valve 26 decompressed. The decompressed refrigerant flows into the outdoor heat exchanger 25 , If the refrigerant is the outdoor heat exchanger 25 passes through, the refrigerant absorbs heat from air, that of the external fan 28 is conveyed, so that the refrigerant is evaporated. The vaporized gaseous refrigerant flows through the passage 24a and the first electromagnetic valve 24b , The refrigerant is in the accumulator 27 separated into gas and liquid and gets into the compressor 23 sucked.

In the heating mode, low temperature air (for example, outside air in winter) passes through the housing 31 is sucked, the evaporator 21 , and the air mix door 34 causes the air through the hot air passage 31a flows. This is from the indoor heat exchanger 22 heated to be heated. In a case where the defroster mode is selected in the heating mode, the heated air passes through the indoor heat exchanger 22 and is blown out through the defroster opening toward the inside of the windshield Further, in a case where the foot mode is selected in the heating mode, the heated air passes through the indoor heat exchanger 22 and is blown out through the foot opening toward the occupant's foot.

In a case where a two-height mode is selected in the heating operation, the air mix door shares 34 in the case 31 low temperature sucked air in a proper ratio between the cooling air passage 31b and the warm air passage 31a on low temperature air passing through the hot air passage 31a flows, is from the indoor heat exchanger 22 heated and is in the mixing room 31c mixed with low temperature air passing through the cooling air passage 31b flows. The temperature-controlled heated air is blown out through the foot opening toward the foot of the occupant.

Low-temperature air passing through the cooling air passage 31b does not heat and is in the mixing room 31c mixed with the air in the warm air passage 31a is heated. The Thus, the conditioned air is blown out to the upper body and the foot of the occupant, respectively, and the warm air blown to the foot and the cold air blown to the upper body have a proper temperature difference , such as 10-15 ° C. Consequently, the air-conditioned air heats the occupant's foot or cool the upper body (around the head) of the occupant

The defrosting operation will be described. The defrosting operation has a first mode and a second mode, and an operation mode of the first mode and the second mode is selected by the occupant.

The first mode will be described. In the first operating mode, the heat pump cycle 20 operated to have the same refrigerant flow as the heating operation. Furthermore, the controller stops 40 the outdoor fan 28 and sets the outside air introduction mode The speed of the fan 33 is decreased to reduce the air flow rate and the opening of the air mix door 34 is controlled to achieve a given heating capacity

In this case, the refrigerant is in the heat pump cycle 20 in the indoor heat exchanger 22 Heat by exchanging heat with air through the hot air passage 31a flows to provide the warmed air. In contrast, the outdoor fan 28 is stopped, the heat exchange between the refrigerant and the outside air in the outdoor heat exchanger 25 not done so much. The surface of the outdoor heat exchanger 25 is heated by the heat of the refrigerant to the frost, which at the outdoor heat exchanger 25 liable to melt. At this time, the power of the compressor 23 for the heat dissipation in the indoor heat exchanger 22 and for the heat release in the outdoor heat exchanger 25 used. Therefore, in the first operation mode of the defrosting operation, the frost of the outdoor heat exchanger 25 be removed while the heating operation is performed at the same time.

The second mode will be described. In the second mode, the heat pump cycle 20 operated so that it has the same refrigerant flow as in the cooling operation. Furthermore, the controller stops 40 the outdoor fan 28 and sets the inside air circulation mode or the middle mode that has both the inside air circulation mode and the outside air introduction mode. The speed of the fan 33 is increased to increase the air flow rate, and the opening of the air mix door 33 is reduced to the hot air passage 31a to throttle.

This gives the refrigerant in the heat pump cycle 20 in the indoor heat exchanger 22 no heat because the heat exchange between the refrigerant and the air is not so much carried out. Furthermore, because the outdoor fan 28 is stopped in the outdoor heat exchanger 25 the heat exchange between the refrigerant and the outside air is not so much performed. The surface of the outdoor heat exchanger 25 is heated by the heat of the refrigerant to that at the outdoor heat exchanger 25 to melt adhering frost.

Further, in the evaporator 21 Heat between the refrigerant coming from the first electric valve 24 is decompressed, and that of the blower 33 exchanged indoor air, so that the refrigerant absorbs heat from the indoor air. At this time, the heat pump cycle works 20 as a normal supercritical cycle. Therefore, in the defrosting operation, the inside air is heated by the exhaust heat of the vehicle, and the amount of the heated air flowing into the housing 31 is sucked, is increased, so that the evaporator 21 the heat recovery can efficiently perform by absorbing heat from the indoor air.

Operation of the air conditioner 10 is referring to 3 described. The flowchart of 3 Represents one of the controller 40 performed processing and is executed when the ignition switch of the vehicle is turned on.

When the processing is started, at S1, the frost formation level is calculated by the frost condition calculator 42 based on a difference between the outside air temperature and the refrigerant temperature in the outdoor heat exchanger 25 calculated.

At S2, it is determined whether the frost is generated or not based on the frost formation level calculated at S1. If it is determined at S2 that the frost is not generated, the processing returns to S1. If it is determined at S2 that the frost is generated, at S3 of the display part 37b a frost information representing the frost level is displayed. For example, when the frost is generated at the maximum level, information indicating that the frost having the maximum level is generated is displayed as information that defrosting is required

At S4, it is determined whether or not the defrosting operation is allowed. If the de-rusting operation is not allowed, the processing returns to S3. If the defrosting operation is permitted, processing proceeds to S5. If for example from the determiner 43 is determined that the frost level has reached the maximum level, the defrosting operation is in an automatic Defrosting mode automatically allowed. In this case, the defrosting operation is permitted. If the occupant also has an instruction in the keypad 37a to start the defrosting operation, the defrosting operation is permitted. In addition, when frost is generated while air-conditioning for the passenger compartment is performed, the defrosting operation is permitted.

At S5, the controller controls 40 the air conditioner 10 to start the defrosting operation. At S6, the display part becomes 37b controlled to display information representing that the defrosting is performed. The information also includes information about the level of frost. Therefore, the occupant can know that the defrosting operation is being performed and know a change caused by the defrosting operation.

At S7 the time calculator calculates 41 a remaining time period for the defrosting operation (Tend), that is, a period of time necessary to complete the defrosting operation. At S8, the controller controls 40 the display part 37b to display the calculated remaining time for the defrosting operation.

At S9 the determiner determines 43 Whether a condition for ending the de-rusting operation is satisfied or not. If the condition is not satisfied, the processing returns to S6, and the defrosting operation continues. If the condition is satisfied, the processing advances to S10. For example, when the frost level is lowered to a predetermined level, the condition is considered satisfied. If the occupant alternatively the keypad 37a operated to stop the defrosting operation, the condition is considered fulfilled. When the driving condition detecting device 44 alternatively detects that the vehicle starts to drive, the condition is considered fulfilled. The determination may be made by further referring to other conditions such as outside air temperature. At S10, every component of the heat pump cycle becomes 10 instructed to stop the defrosting operation, and the processing is terminated.

Consequently, at S3, before the defrosting operation is started, the frost formation level is displayed. During the defrosting operation, the operating state of the defrosting operation is displayed at S6, and the remaining period of the defrosting operation is displayed at S8. Consequently, an occupant based on the on the display part 37b displayed information to start / stop the defrosting operation.

The calculation of the frost level at S1 will be made with reference to 4 - 8th specifically described. 4 FIG. 15 is a diagram showing an example relationship between the outside air temperature and the temperature of refrigerant at the outlet part of the outdoor heat exchanger. FIG 25 represents. A horizontal axis of 4 represents the outside air temperature, and a vertical axis of 4 represents the refrigerant temperature. Dashed line of 4 represents a change in the evaporation temperature of the outdoor heat exchanger 25 and is changed by the outside air temperature condition. A vertical line G of 4 represents a critical limit for the defrosting operation. When the outside air temperature becomes equal to or higher than a threshold value such as 12 ° C, the defrosting operation becomes regardless of the refrigerant temperature of the outdoor heat exchanger 25 prevented.

When the refrigerant temperature becomes lower than a temperature represented by the broken line of the level 1, it is determined that the frost is generated. The progress state of the frost is determined as a level by defining the broken line of the level 2 and the broken line of the level 3. The amount of frost increases in the order of the level 1, the level 2 and the level 3. When the outside air temperature is the same as the refrigerant temperature decreases, the temperature difference between the outside air temperature and the refrigerant temperature becomes large, so that the amount of frost increases. The frost level is measured using the in 4 calculated model.

A specific method of calculating the frost level will be described with reference to FIG 5 - 8th described. The frost level will be as in 4 shown changed by the temperature difference between the outside air temperature and the refrigerant temperature. Three thresholds are set to define the frost level relative to the outside air temperature, and correspond to the dashed lines in FIG 4 , For example, if the outside air is -10 ° C, the first threshold will be in 5 set as 3 ° C, the second threshold is in 6 set as 5 ° C, and the third threshold is in 7 set as 8 ° C.

The frost level is calculated using the thresholds and the temperature difference, as in 8th shown, determined.

If the temperature difference is less than the first threshold, the frost level is defined as 0. If the temperature difference is equal to or greater than the first threshold and less than the second threshold, the frost level is defined as level one. If the temperature difference is equal to or greater than the second threshold and less than the third threshold, the frost level is defined as level 2 if the temperature difference is equal to or is greater than the third threshold, the frost level is defined as level 3.

For example, in a case where the outside air temperature is -10 ° C, the temperature difference is equal to or more than 3 ° C and less than 5 ° C, the frost level is defined as level one. If the temperature difference is equal to or greater than 5 ° C and less than 8 ° C, the frost level is defined as level 2. If the temperature difference is equal to or greater than 8 ° C, the frost level is defined as level 3.

Consequently, the state calculator determines 42 the frost level based on the outside air temperature and the temperature difference between the outside air temperature and the refrigerant temperature. The frost level is not limited to having three levels. The frost level can be two levels or four or more levels.

The calculation of the remaining period of the defrosting operation at S7 will be explained with reference to FIG 9 described. 9 FIG. 14 is a diagram illustrating an example relationship between a time lapse of the defrosting operation and the refrigerant temperature. A horizontal axis of 9 represents the elapsed time for the defrosting operation, and the defrosting operation is defined to start at time 0.

The refrigerant temperature has a predetermined value Pe for completing the defrosting operation (eg, 5 ° C.) as the condition for ending the defrosting operation. When the refrigerant temperature exceeds the predetermined temperature Pe due to the defrosting operation, the de-rusting operation is ended

As in 9 shown, calculates the time calculator 41 a period of time required from the current time T _n to the end time of the defrosting operation T _f . The calculated time period (T _f -T _n ) corresponds to the remaining period of the defrosting operation (Tend).

Specifically, when the time ΔT has passed since T _n-2 to T _n-1 or since T _n-1 to T _n , the refrigerant temperature is changed (in FIG 9 elevated). A gradient is calculated by dividing the change in the refrigerant temperature by the time ΔT, and an average of the gradients is calculated using n samples (n = 4, ΔT = 0.25 s). The remaining time period of the defrosting operation Tend is calculated based on the current time T _n , the average of the gradients and the predetermined temperature Pe.

Examples of that of the display part 37b displayed image will be referring to 10 - 13 described 10 represents an image that is displayed at a normal operating time. As in 10 is shown during the heating operation or the cooling operation, information regarding the preset temperature, the air quantity and the air outlet mode are displayed.

11 displays an image that is displayed when frost is generated As in 11 is shown, the preset temperature is displayed at a frost generation time, for example, in a flashing state at a frequency of 0.5 Hz. The picture of 11 is an example of the picture displayed at S3. The speed of blinking or the color of the display part 37b can be changed according to the frost level. Further, according to the frost level, another image may be displayed in the other display area. The frost level can be indicated by the number of other images

12 represents an image displayed when the defrosting mode is performed. As in 12 is shown, the image is made invisible except for the preset temperature, and the preset temperature is displayed during the defrosting operation, for example, in the blinking state at a frequency of 1 Hz. The flashing speed in the defrosting mode is faster than in the forestry production time. The picture of 12 is an example of the picture displayed at S6. Further, information indicating that the de-rusting operation is performed may be displayed in the visible area. In addition, an original flag indicating that the defrosting operation is performed may be displayed.

13 represents an image indicating the remaining time period of the defrosting operation. In 13 At times, three images are partially overlapped with time to display an image in an imaginary manner. As in 13 is shown, the remaining time period of the defrosting operation is displayed in the display area of the preset temperature, and the other image is made invisible. The picture of 13 is an example of the image displayed at S8 Further, information indicating that the countdown of the remaining time period is performed may be displayed in the invisible area. In addition, an end time of the defrosting operation can be calculated by adding the remaining time period to the current time, and the calculated end time of the defrosting operation can be displayed.

When the de-rusting operation is not performed according to the embodiment, the controller controls 40 the display part 37b as in S3 of 3 shown to output the frost information indicating the degree or level of frost formation represent. Therefore, the occupant can recognize the frost degree from the information. The occupant can predict the start time of the defrosting operation to some extent by recognition. Consequently, the occupant is prevented from feeling that the defrosting operation is suddenly started even if the defrosting state is automatically started in response to the frost condition.

While the defrosting operation is being performed, the controller controls the display 37b to output the defrost information, which, as in S6 of 3 show that the defrosting operation is performed. Therefore, the occupant can recognize that the defrosting operation is being performed. Consequently, the occupant may know that a reduction in the air conditioning capacity is caused by the defrosting operation. The information about the defrosting operation can improve the comfort of the occupant.

While the defrosting operation is performed, the controller controls 40 the display part 37b to obtain the information that the defrosting operation is performed and the remaining time period of the defrosting operation, as in S8 of FIG 3 shown to spend. Therefore, the occupant can recognize the time necessary to complete the defrosting operation. Thus, even if the air-conditioning capacity is reduced by the de-rusting operation, the occupant can know that the air-conditioning capacity is restored after the lapse of time.

If the determiner 43 in a case where the defrosting operation is not performed, determines that the defrosting operation is necessary controls the controller 40 the display part 37b to, as in S3 of 3 shown to output information showing that the defrosting operation is necessary. Therefore, the occupant can recognize that the defrosting operation is necessary. Consequently, the occupant may know that a reduction in the air conditioning capacity is caused by the frost.

When the information instructing the start of the defrosting operation enters the keypad 37a , which corresponds to a starter input, controls the controller 40 every component to, as in S4 of 3 shown to perform the defrosting operation. Therefore, the occupant can start the defrosting operation with an appropriate timing determined by the occupant based on the frost degree. Even if the degree of frost is low, the occupant may instruct the defrosting operation to prevent the amount of frost from becoming large

When the information instructing the stoppage of the defrosting operation is entered into the keypad 37a , which corresponds to a stopping means, are input, controls the controller 40 every component to, as in S9 of 3 shown to stop the defrosting operation. Therefore, the occupant can stop the defrosting operation with an appropriate timing determined by the occupant. Although the defrosting operation is not completed, the defrosting operation can be stopped by the occupant when the frost degree becomes low. In this case, the air conditioning for the passenger compartment may be performed with the air conditioning capability restored to some extent.

While the defrosting operation is performed in the state where the vehicle is stopped, the controller controls 40 each component when the driving condition detecting means 44 recorded the start of the drive of the vehicle that, as in S9 of 3 shown, the defrosting operation is stopped. Therefore, when the vehicle begins to drive, the defrosting operation is automatically stopped. As a result, the air conditioning ability can be restricted from being lowered by the defrosting operation when the vehicle starts running.

The frost detection device 42 detects the frost degree using the temperature difference between the outside air temperature and the refrigerant temperature. Therefore, the detection device 42 accurately detect the degree of frost without being affected by a disturbance.

As the driver of the vehicle, the operating condition of the air conditioning 10 the driver can know that the reduction of the air conditioning capacity is caused by the frost, not by a failure. Further, the driver can visually recognize the frost condition. The defrosting operation may be started by the driver (user), and the driver may see the period of time necessary to finish the defrosting operation. For example, the defrosting operation may be performed at a favorable timing using a short time during which the vehicle stops until a traffic light changes from red to green. Since the amount of time necessary to complete the defrost operation is seen, the occupant may be made to wait until the time has elapsed. As a result, the defrosting can be suitably achieved for the outdoor heat exchanger.

The preferred embodiment is described above. However, the present disclosure is not limited to the above embodiment.

The frost information, which represents the frost levels, has three frost levels. Alternatively, frost formation can be the amount of frost. Furthermore, the frost information may have four or more levels for the frost.

The frost calculator is not limited to using the outside air temperature and the refrigerant temperature. Alternatively, a humidity sensor may be disposed on the outdoor heat exchanger. In this case, the frost condition can be more accurately detected using the information provided by the humidity sensor.

That on the display part 37b displayed image is only an example and is not limited to the above example. Further, the output section is not on the display part 37b and the other device may be used as the output section. The actual operating state such as cooling, heating, dehumidifying or defrosting may be displayed on the display part 37b as the operating status are displayed. The remaining time period of the defrosting operation may be indicated by the original (exclusive) liquid crystal portion or the other method. The information may be output from the output section except the image by light, speech or vibration.

Such changes and modifications are to be understood as being within the scope of the present disclosure as defined by the appended claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 53-119449A [0003]
• JP 55-5002 U [0003]

Claims (7)

A vehicle air conditioner comprising: a heat pump cycle ( 20 ) with an outdoor heat exchanger ( 25 ) condensing high-pressure refrigerant by exchanging heat with outside air; a frost condition calculator ( 42 ) that calculates a degree of frost that has formed in the outdoor heat exchanger; an output section ( 37b ) outputting information about the frost formed in the outdoor heat exchanger; and a controller ( 40 ) which has a defrosting operation for melting the frost adhering to the outdoor heat exchanger by controlling a component ( 23 . 26 instructs the output section to output the frost degree calculated by the frost state calculator as frost information when the defrosting operation is not performed, and the controller controls the output section to output defrosting information representing that the defrosting operation is performed when the defrosting operation is performed. An air conditioner according to claim 1, wherein the controller calculates a remaining time period for the defrosting operation required to end the defrosting operation based on the frost degree while the defrosting operation is performed, and the controller controls the output section to output the defrosting information and the remaining time period of the defrosting operation while the defrosting operation is performed. An air conditioner according to claim 1 or 2, further comprising: a determiner ( 43 ) determining whether the frost degree requires the defrosting operation, the controller controlling the output section to output requirement information representing that the defrosting operation is necessary when the determiner determines that the defrosting operation is necessary while the defrosting operation is not being performed , An air conditioner according to any one of claims 1-3, further comprising: a starter ( 37a ) inputting a start information representing that the defrosting operation should be started to the controller, wherein the controller controls the component of the heat pump cycle to start the defrosting operation when the starter inputs the start information to the controller. An air conditioner according to any of claims 1-4, further comprising: a stopping device ( 37a ), which inputs a stop information representing that the defrosting operation should be stopped to the controller, wherein the controller controls the component of the heat pump cycle to stop the defrosting operation when the stopping device inputs the stop information to the controller The air conditioner according to any one of claims 1 to 5, further comprising: drive state detecting means (10). 44 ), which detects a driving state of the vehicle, wherein the controller controls the component of the heat pump cycle to stop the defrosting operation when the detecting means detects that the vehicle starts to run, while in a state where the vehicle is stopped, the defrosting operation is carried out. Air conditioning system according to any one of claims 1-6, further comprising: a first temperature detection means ( 35 ) which detects a temperature of the outside air; and a second temperature detection device ( 25a ), which detects a temperature of the refrigerant at a refrigerant outlet part of the outdoor heat exchanger, wherein the frost condition calculator calculates the frost degree using a difference between the detected temperature of the outside air and the detected temperature of the refrigerant.

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