KR101738015B1 - Heating System For Electric Vehicle Using Air Flow Control And Method Therefor - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an electrically driven vehicle using a heat pump,
The motor and the inverter are arranged in a space shielded by the inverter and the external heat exchanger, and the isolated space communicates with the air flap. Therefore, when the interior of the vehicle is kept warm and cooled, And a control method of the heating system using the air flow control of the electric vehicle, which can increase the heat efficiency supplied to the interior of the vehicle by heating the heat generating unit by preventing the air flowing into the motor from being supplied to the motor.

Description

Technical Field [0001] The present invention relates to a heating system using an air flow control of an electric vehicle,

The present invention relates to a heating system using an air flow control of an electric vehicle and a control method thereof, and more particularly, to an electric driving vehicle using a heat pump in which an exothermic motor and an inverter are separated from an external heat exchanger, The present invention relates to a heating system using an air flow control of an electric vehicle and a control method thereof, which can increase the heat efficiency supplied to an interior of a vehicle by heating a heat generating portion through an air flap at the time of warming and cooling.

2. Description of the Related Art [0002] In general, an air conditioner is provided in a vehicle for a driver to ride inside the vehicle. The air conditioner supplies cooling water for cooling the heat generated in the vehicle driving unit to the heater in the vehicle interior to increase the temperature inside the vehicle when the outside temperature is low or to transmit heat in the vehicle interior to the outside of the vehicle It is a means to perform the function of lowering the temperature inside the vehicle.

Such an air conditioning apparatus is also used in the case of an electric vehicle that utilizes the rotational force of an electric motor. FIG. 1 shows a heating system of an air conditioner using waste heat provided in such a conventional electric vehicle.

As shown in the figure, the air conditioner of an electric vehicle (including a hybrid vehicle) does not use a heater using cooling water as in the above-described general automobile, so that the configuration of the air conditioner of a vehicle using a conventional fossil fuel .

Referring to FIG. 1, a conventional air conditioner of an electric vehicle has a structure in which heat generated from an electric motor is transmitted to a room by a heat exchanger 101 provided in a motor room 100. In other words, in the air conditioner provided in the conventional electric vehicle, heat is generated in the motor 102 and the inverter 103 provided for driving the electric vehicle, and the waste heat thus generated is transmitted to the heat exchanger 101 And the heat exchanger 101 is configured to function to raise the temperature of the indoor side by transmitting the heat to the heat exchanger 201 located in the indoor part 200 of the vehicle.

However, the conventional air conditioner as described above is influenced by the outside air supplied into the shielded motor room 100. That is, the motor room 100 has an opening formed in a part of a side end thereof, and is influenced by a fan provided in the motor room 100 or running wind caused by running of the vehicle, and air is introduced through the opening, An air flap (104) is provided in the opening to adjust the amount of air introduced into the motor room (100). However, when outside air is introduced by the operation of the air flap 104 (including some operations), the introduced air comes into contact with the surface of the driving motor 102, as shown in FIG. 2, 102), so that waste heat of the motor 102 used for indoor heating is lost.

In the conventional air conditioner using waste heat, since the external heat exchanger 101 serves as an evaporator when the heat exchanger is used, the temperature of the air passing through the external heat exchanger 101 becomes lower than that of the outside air , The air having lowered temperature cools the waste heat sources of the inverter 103 and the drive motor 101, thereby reducing the efficiency of waste heat used for heat exchange.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an electrically driven vehicle using a heat pump,

The motor and the inverter are arranged in a space shielded by the inverter and the external heat exchanger, and the isolated space communicates with the air flap. Therefore, when the interior of the vehicle is kept warm and cooled, And a control method of the heating system using the air flow control of the electric vehicle, which is configured to increase the heat efficiency supplied to the interior of the vehicle by keeping the heat generating unit warm by preventing the air from being supplied to the motor. have.

According to an aspect of the present invention,

A heating system for an electric vehicle, comprising: a heat generating unit including a motor and an inverter that are operated and driven to drive an electric vehicle; An external heat exchanger including an external heat exchanger to receive heat generated by the heat generating unit and transfer the heat to the inside of the room, and to form an opening at one side and a bottom to circulate outside air; And an indoor unit disposed on the vehicle interior side and including an internal heat exchanger (31) to radiate heat received from the external heat exchanger, wherein the heat generating unit, the external heat exchanging unit, and the indoor unit are configured to be shielded from each other, An intermediate air flap which is formed at one side of the opening so as to communicate with the external heat exchanging portion and which is disposed at an opening between the heat generating portion and the external heat exchanging portion and opens and closes the opening portion by a sliding operation, And further comprising:

A lower air flap disposed at a lower opening of the external heat exchanger and opening and closing a lower opening by a sliding operation; And an external air flap disposed at an opening formed in one side surface of the external heat exchanger and opening and closing the side opening by a sliding operation, wherein the control unit further controls the lower air flap and the external air flap .

Further, the intermediate air flaps are arranged to be inclined toward the upper side toward the upper side.

At least one of the intermediate air flap, the lower air flap, and the outer air flap may include a support portion including a bar spaced apart at a predetermined distance, and a driver; And a guide part for fixing the driving part and sliding the driving part along the longitudinal direction of the driving part. The driving part is configured to open and close the spaced apart space of the supporting part by a sliding operation.

An intermediate air flap for opening and closing an opening portion formed between the heat generating portion and the external heat exchanging portion and an external air blowing portion for introducing external air into the external heat exchanging portion, A method of controlling a heating system using an air flow control of an electric vehicle including a flap and a lower air flap for exhausting air from the external heat exchanging unit, the method comprising: determining whether an external air flap is opened; Closing the intermediate air flap and closing the lower air flap only halfway when the external air flap is opened; Comparing the temperature of the external heat exchanger and the temperature of the motor when the external air flap is closed; Determining whether the temperature of the motor exceeds a critical temperature when the temperature of the motor is higher than the temperature of the external heat exchanger; Opening the intermediate air flap and opening the lower air flap if the temperature of the motor exceeds a critical temperature; Determining whether the temperature of the motor is lower than a critical temperature when the temperature of the motor is lower than the temperature of the external heat exchanger; And closing the intermediate air flap and closing the lower air flap if the temperature of the motor is lower than the critical temperature.

The method further includes opening the intermediate air flap and opening the lower air flap if the temperature of the motor is higher than the critical temperature.

According to the present invention,

The outside air supplied to the external heat exchanger is prevented from being applied to the heat generating portion by disposing the heat generating portion including the motor and the inverter that is driven by the driving operation in a space shielded from the external heat exchanger so that the waste heat of the heat generating portion is cooled Therefore, there is an effect that the waste heat generated in the heat generating portion can be efficiently supplied to the interior portion of the vehicle.

Further, by forming the opening portion which is opened and closed by the air flap between the heat generating portion and the external heat exchanger disposed in the space shielded separately from each other, the air communication between the heat generating portion and the external heat exchanger So that it can be achieved.

In addition, the intermediate air flaps disposed between the heat generating unit and the external heat exchanger are disposed at an angle of 90 degrees or less, that is, diagonal directions, so that the air introduced into the external heat exchanger flows downward Thereby allowing the air to escape through the lower air flaps disposed at the lower portion.

1 shows a heating system of an air conditioner using waste heat provided in a conventional electric vehicle.
2 is a side sectional view of a heating system of an air conditioner using waste heat provided in a conventional electric vehicle.
3 is a block diagram briefly illustrating a heating system using air flow control of an electric vehicle according to a preferred embodiment of the present invention.
4 and 5 show an outer air flap 50 according to a preferred embodiment of the present invention.
6 is a side view of an intermediate air flap in accordance with a preferred embodiment of the present invention.
FIG. 7 shows a variation of the intermediate air flip during heating and cooling of the heating system using the air flow control of the electric vehicle according to the preferred embodiment of the present invention.
FIG. 8 is a flowchart illustrating a control method of a heating system using air flow control of an electric vehicle according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

3 is a block diagram briefly illustrating a heating system using air flow control of an electric vehicle according to a preferred embodiment of the present invention.

Referring to the drawings, a heating system using an air flow control of an electric vehicle according to the present invention includes a heating unit 10 including a motor to generate heat according to driving of a vehicle, An external heat exchanging unit 20 for discharging the generated heat to the outside and an indoor unit 30 for receiving the heat supplied from the heat generating unit 10 by the user (s) using the vehicle.

The heat generating unit 10 is a means for generating heat by driving an electric vehicle, and is preferably disposed in a motor room (corresponding to an engine room of a conventional automobile) of an electric vehicle.

As shown in the figure, the components included in the heat generating unit 10 include an inverter 12, a motor 11, a valve, an electric water pump (EWP), a low voltage DC converter (LDC) And on-board chargers (OBCs). Each of these components is well-known components constituting an electric vehicle, and thus a detailed description thereof will be omitted.

The heat generated in the motor 11 and the inverter 12 is generated by the motor 11 and the inverter 12 during driving of the vehicle, The heat exchange unit 20 is connected to the external heat exchanging unit 20 through an exchange of air to heat the external heat exchanging unit 20 to prevent heat loss from being generated. An opening and an air flap 40 are provided to allow the exchange of the air to be selectively performed and selectively communicated with or shielded from the external heat exchanging unit 20 to be described later by driving the air flap.

In other words, the amount of indoor heat exchange increases in accordance with the heat exchange amount of the external heat exchanger 21 when the heat pump cycle is normally performed in the heating using the heat pump of the electric vehicle. In this case, the external heat exchanger 21 performs indoor heat exchange The temperature of the external heat exchanger 21 becomes lower than the temperature of the outside air since it serves as an evaporator. Therefore, outside air introduced from the outside is cooled while passing through the external heat exchanger (21), and heat is generated when such air is introduced into the heat generating portion (10). Therefore, the motor 11 or the inverter 12 of the heat generating unit 10 can be prevented from being cooled by shielding the heat generating unit 10 by the intermediate air flap 40.

The motor 11 and the inverter 12 constituting the heat generating unit 10 generate heat in order to transfer heat to the external heat exchanger 21 of the external heat exchanging unit 20, The air conditioner of the present invention is connected to the air conditioner through a gas pipe which can be connected to the air conditioner. Accordingly, heat (waste heat) generated in the heat generating unit 10 is transferred to the external heat exchanging unit 20, which will be described later, through the gas pipe.

The external heat exchanging unit 20 functions to discharge the heat generated in the heat generating unit 10 to the outside or to transmit the heat generated by the heat generating unit 10 to the inside room 30 to be described later. The external heat exchanging unit 20 includes an external heat exchanger 21.

The external heat exchanger 21 receives the heat generated by the heat generating unit 10 and transfers the heat to an internal heat exchanger to be described later. Accordingly, the external heat exchanger is connected to the internal heat exchanger through the gas pipe or the like so as to transfer heat to the internal heat exchanger.

The external heat exchanging unit 20 is formed at one side of the heat generating unit 10 and the external heat exchanging unit 20 is provided at one side thereof with external air introduced into the external heat exchanging unit 20 An opening is formed. An outer air flap 50 is formed in the opening so that the amount of the introduced air is controlled according to whether the outer air flap 50 is opened or not.

Since the external heat exchanging unit 20 is configured such that external air does not flow into the heat generating unit 10 when the intermediate air flap 40 is closed even when outside air flows through the opening, It is possible to solve the problem that the heat generated in the motor 11 by the outside air is reduced in the air conditioner of Fig.

The external heat exchanger 20 further includes an opening formed at a lower end of the external heat exchanger 20 so as to discharge the air introduced by the external air flap 50 and a lower air flap 60 disposed at the lower end opening.

The lower air flap 60 is provided to discharge the air introduced into the external heat exchanger 20 to the lower end, and is preferably formed over the entire lower end of the external heat exchanger 20. Therefore, the air introduced by the opening of the outer air flap 50 passes through the external heat exchanger 21 and is discharged downward by opening the lower air flap 60 disposed at the lower end.

In a preferred embodiment of the present invention, the middle air flap 40 and the lower air flap 50 are configured to operate in conjunction with each other. This is to control the amount of air to be discharged depending on the amount of air flowing through the external air flaps 50.

Meanwhile, the external heat exchanger 21 can cool the heat generating unit 10 by receiving and discharging the heat generated in the heat generating unit 10. Accordingly, it is possible to prevent the motor 11 and the inverter 12 of the heat generating unit 10 from being heated beyond the set range.

The indoor unit (30) includes an internal heat exchanger (31) capable of dissipating heat. The internal heat exchanger (31) is connected to the external heat exchanger (21) and receives heat transferred from the external heat exchanger to dissipate the heat into the air.

Preferably, the indoor unit 30 is disposed in a space on which a user is boarding the vehicle, so that the heat emitted from the indoor unit 30 raises the temperature of the space occupied by the user.

On the other hand, the control of the intermediate air flap 40, the outer air flap 50 and the lower air flap 60 is preferably performed through an electronic control unit (ECU) And may be controlled through other known control means included in the electric vehicle (hereinafter, collectively referred to as a 'control unit'). These matters are well known in the control of the various means provided in electric vehicles, and therefore, detailed description thereof will be omitted.

4 and 5 show a lower air flap 60 according to a preferred embodiment of the present invention.

As shown in the figure, the lower air flap 60 is composed of two layers, that is, a supporting portion 62 and a driving portion 61, which are formed by arranging a plurality of bars spaced apart at regular intervals.

The supporting part 62 is fixed and the driving part 61 disposed on the upper part of the supporting part 62 slides in the longitudinal direction of the lower air flap 60 and is driven.

The lower air flap 60 is configured to discharge air through a spaced distance between a plurality of bars of the support portion 62. At this time, the driving portion 61 is slid to block the gap of the support portion, So as to prevent the flow of the fluid.

4 is a plan view (a) and a side sectional view (b) of an opened state of the lower air flap 60. Fig. 5 is a plan view (a) b).

Preferably, the driving unit 61 is fixed by a guide unit 63 for fixing the driving unit 61, and is slid by the flow of the guide unit 63.

4 and 5 have been described only for the lower air flap 60, the outer air flap 50 and the intermediate air flap 40 of the present invention are also the same as the structure of the lower air flap 60 described above .

Figure 6 is a side view of an intermediate air flap 40 in accordance with a preferred embodiment of the present invention.

As shown in the figure, the intermediate air flaps 40 are arranged obliquely toward the external heat exchanger 20 toward the upper side. In other words, the intermediate air flaps 40 are disposed at an angle of 90 degrees or less.

Therefore, if the intermediate air flap 40 is in a closed state when external air flows through the opening formed in the external heat exchanging unit 20, the flow direction of the introduced external air is changed from the horizontal direction to the vertical direction So that outside air passing through the external heat exchanging unit 20 can escape through the lower air flap 60. [

FIG. 7 shows a variation of the intermediate air flip during heating and cooling of the heating system using the air flow control of the electric vehicle according to the preferred embodiment of the present invention.

As shown in FIG. 7A, when the interior of the vehicle to which the heating system using the air flow control of the electric vehicle according to the present invention is applied needs to be heated, it is necessary to supply the heat generated from the heat generating unit 10, By shielding the heat generating portion 10 for supplying, it is possible to prevent unnecessary leakage.

Therefore, the intermediate air flap 40 is closed so as to prevent the opening formed in the heat generating portion 10, thereby protecting the temperature of the heat generating portion 10.

7B, when cooling of the interior of the vehicle to which the heating system using the air flow control of the electric vehicle according to the present invention is applied is required, or when the temperature of the heating unit 10 rises more than necessary, It is necessary to cool the heat generating portion 10 and it is necessary to open the heat generating portion 10 which is shielded for this.

Therefore, by opening the closed intermediate air flap (40), the air introduced through the external heat exchange unit (20) is controlled to flow into the heat generating unit (10).

FIG. 8 is a flowchart illustrating a control method of a heating system using air flow control of an electric vehicle according to a preferred embodiment of the present invention.

Preferably, the heating system using the air flow control of the electric vehicle of the present invention can be controlled through an electronic control unit (ECU) provided in the vehicle and controlling the electronic equipments in the vehicle. In addition, Can be controlled through known control means (hereinafter, referred to as a " control unit "). These matters are well known in the control of the various means provided in electric vehicles, and therefore, detailed description thereof will be omitted.

First, when vehicle heating control is started by the driver, the controller determines whether the external air flap 50 is open (S001).

If it is determined in step S001 that the outer air flap 50 is opened, the controller closes the middle air flap 40 and controls the lower air flap 60 to close halfway (step S002). Therefore, the middle air flap 40 is closed to prevent the outside air from flowing into the heat generating portion 10, and the outside air flap 60 allows the outside air to escape.

If it is determined in step S001 that the external air flap 50 is closed, the controller compares the temperature of the motor 11 of the external heat exchanger 21 with the temperature of the heating unit 10 in step S003.

If it is determined in step S003 that the temperature of the motor 11 is higher than the temperature of the external heat exchanger 21, the controller determines whether the temperature of the motor 11 is higher than a preset temperature (S004). The set temperature may be a temperature at which the heating can be smoothly performed by the motor 11, and may be, for example, 60 degrees in the present invention.

If it is determined in step S004 that the temperature of the motor 11 is higher than the set temperature, the controller can smoothly perform heating by the motor 11 and does not need to shield the heating unit 10 The intermediate air flap 40 is opened and the lower air flap 60 is also opened so that external air flows into the heat generating portion 10 so that heat exchange with the external heat exchanging portion 20 can be performed through the air (S005).

If it is determined in step S004 that the temperature of the motor 11 is not higher than the predetermined temperature, the control unit may close the intermediate air flap 40 by heating the heating unit 10, 10), and the lower air flap 60 is opened to control the air introduced into the external heat exchange unit 20 to be discharged (S008).

If it is determined in step S003 that the temperature of the external heat exchanger 21 is higher than the temperature of the motor 11, the controller determines whether the temperature of the motor 11 is lower than a preset temperature (S006 ).

If it is determined in step S006 that the temperature of the motor 11 is lower than the set temperature, the control unit controls the temperature of the motor 11 of the heat generating unit 10, The intermediate air flap 40 is opened so as to allow heat exchange through the air and the lower air flap 60 is closed in order to prevent the heated air in the external heat exchanger 21 from escaping to the outside ).

If it is determined in step S006 that the temperature of the motor 11 is higher than the predetermined temperature, the control unit determines that the heating can be smoothly performed by the motor 11, The intermediate air flap 40 is closed and the lower air flap 60 is opened in order to prevent unnecessary heating by the heated air in the external heat exchanger 20, (S008).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. I do not want to. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10: heating part 11: motor
12: inverter 20: external heat exchanger
21: external heat exchanger 30: indoor part
31: internal heat exchanger 40: intermediate air flap
50: outer air flap 60: lower air flap
61: driving part 62:
63: guide portion
100: Conventional motor room 101: Conventional motor room heat exchanger
102: Conventional motor 103: Conventional inverter
104: conventional air flap 200: conventional indoor part
201: Conventional indoor heat exchanger

Claims (6)

In an electric vehicle heating system,
A heating unit (10) including a motor (11) and an inverter (12) that are operated and driven to drive an electric vehicle;
An external heat exchanger 20 including an external heat exchanger 21 for receiving the heat generated by the heat generating unit 10 and transferring the heat to the indoor unit 30 and forming an opening at one side and a lower part to circulate outside air; );
And an indoor unit (30) disposed on the vehicle interior side and including an internal heat exchanger (31) and radiating heat received from the external heat exchanger (21)
The heat generating unit 10, the external heat exchanging unit 20, and the indoor unit 30 are configured to be shielded from each other,
An opening is formed at one side of the heat generating part 10 so as to communicate with the external heat exchanging part 20,
Further comprising an intermediate air flap (40) disposed at an opening between the heat generating portion (10) and the external heat exchanging portion (20) for opening and closing the opening portion by a sliding operation and a control portion for controlling the intermediate air flap Wherein the air flow control is performed using the air flow control of the electric vehicle.
The method according to claim 1,
A lower air flap (60) disposed at a lower opening of the external heat exchanger (21) and opening and closing a lower opening by a sliding operation; And
Further comprising an external air flap (50) disposed in an opening formed in one side surface of the external heat exchanger (21) and opening and closing a side opening by a sliding operation,
Wherein the control unit further controls the lower air flap (60) and the outer air flap (50).
The method according to claim 1,
Wherein the intermediate air flap (40) is arranged to be inclined toward the outer heat exchanging part (20) toward the upper part.
3. The method of claim 2,
At least one of the middle air flap 40, the lower air flap 60 and the outer air flap 50,
A support portion 62 and a driving portion 61 including a bar spaced apart at regular intervals;
And a guide part (63) which fixes the driving part (61) and slides along the longitudinal direction of the driving part,
Wherein the driving unit (61) is configured to open and close a spaced space of the support part (62) by a sliding operation.
(10) including a motor (11) and an external heat exchanger (20) including an external heat exchanger (21), wherein an opening formed between the heat generator (10) and the external heat exchanger An external air flap 50 for introducing external air into the external heat exchanging part 20 and a lower air flap 60 for discharging air from the external heat exchanging part 20 A method of controlling a heating system using an air flow control of an electric vehicle,
Determining whether the outer air flap (50) is open; And
Closing the middle air flap (40) and closing the lower air flap (60) only when the outer air flap (50) is opened;
Comparing the temperature of the external heat exchanger (21) and the temperature of the motor (11) when the external air flap (50) is closed;
Determining whether the temperature of the motor (11) exceeds a critical temperature when the temperature of the motor (11) is higher than the temperature of the external heat exchanger (21);
Opening the intermediate air flap (40) and opening the lower air flap (60) when the temperature of the motor (11) exceeds a critical temperature;
Determining whether the temperature of the motor (11) is lower than a critical temperature when the temperature of the motor (11) is lower than the temperature of the external heat exchanger (21); And
And opening the intermediate air flap (40) and closing the lower air flap (60) when the temperature of the motor (11) is lower than the critical temperature. Way.
6. The method of claim 5,
Further comprising the step of opening the intermediate air flap (40) and opening the lower air flap (60) when the temperature of the motor (11) is higher than the critical temperature Control method.

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