Patent Application
20130199225
This application claims priority under 35 U.S.C. §119 to Korean Application No. 10-2012-0012193 filed in Korea on Feb. 7, 2012, the entirety of which is incorporated herein by reference.
1. Field
An air conditioner for an electric vehicle is disclosed herein.
2. Background
Air conditioners for electric vehicles are known. However, they suffer from various disadvantages.
Embodiments will be described in detail with reference to the following drawings in which like reference numerals refer to like elements, and wherein:
An air conditioner for an electric vehicle according to embodiments will be described in detail with reference to the accompanying drawings. Specific embodiments will be explained in the drawings and the detailed description. However, it is to be understood that embodiments are not limited in application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings.
Reference may now be made in detail to specific embodiments, examples of which may be illustrated in the accompanying drawings. Wherever possible, like reference numbers have been used throughout to refer to the same or like parts. It is to be understood that the terminology defined in a dictionary used herein is meant to encompass the meaning thereof disclosed in related arts. Unless for the purpose of description and should not be regarded as limiting, the terminology is not meant to be ideal or exaggerated.
It will be understood that when an element is referred to with ‘first’ and ‘second’, the element is not limited by them. They may be used only for a purpose of distinguishing the element from the other elements.
With energy cost saving trends, there have been increasing demands for eco-friendly electric vehicles (EV). In the U.S.A. and Europe, Clean Air Acts mandate supply of electric vehicles. In Korea, there has been research and interest in green cars as low-carbon green growth.
A motor for driving an electric vehicle and a battery for operating various electric mechanisms are mounted in the electric vehicle. In addition, an air conditioner for cooling in the summer and heating in the winter may be mounted in such an electric vehicle.
The air conditioner has a cycle to transfer heat as refrigerant is circulated through compression, condensation, expansion, and evaporation processes in order. Such a cooling cycle enables the air conditioner to perform a cooling cycle to exhaust indoor heat outside in the summer and a heating cycle of a heat pump to provide heat in the winder via a reverse circulation order of the cooling cycle. In addition, the air conditioner for the electric vehicle may use the battery as a drive source of the motor, the motor having a mechanism for driving a compressor.
At temperatures below zero in a cold area, the heat exchange ability of the heat pump may not be sufficient and may deteriorate the performance and coefficient of heating performance (COP) of the air conditioner. If the battery is used too much to enhance the performance and COP of the air conditioner, the electric vehicle may have a disadvantage of noticeably deteriorating efficiency. Accordingly, an electric vehicle is required to have an air conditioner having enhanced performance and COP.
In addition, inner or outer humidity is applied to an indoor space of the electric vehicle because of characteristics of the electric vehicle, and frost generated on a front glass window may obstruct a driver's field of vision. A conventional air conditioner converts a heating operation into a cooling operation for dehumidification, such that heating for the indoor space may be performed for a predetermined time period disadvantageously. As a result, there has been a growing demand for an air conditioner for an electric vehicle that can perform continuous heating even in a dehumidification operation.
The air conditioner 100 according to this embodiment is an air conditioner operated using a battery as a driving source. The air conditioner 100 may include an air conditioning device that cools or heats an indoor space of the electric vehicle (C) and a controller 180 that controls the air conditioning device. In addition, the electric vehicle (C) may include a battery 10 and a motor 11, which may be used as a driving source. The motor 11 may drive a compressor 101.
The air conditioner 100 may further include a heat exchanger (not shown) having a working fluid (for example, water) that exchanges heat generated from the battery 10 and the motor 11, and a plurality of pipes that flows the working fluid therethrough. Latent heat exchanged by the battery 10 and the motor 11 may be used to heat a refrigerant circulating in the air conditioning device or to directly heat the indoor space.
The air conditioning device may include the compressor 101, which compresses the refrigerant, first and second indoor heat exchangers 110 and 120 that suck the refrigerant exhausted from the compressor 101, an expansion valve 140 that expands the refrigerant having passed one of the indoor heat exchangers 110 and 120, an outdoor heat exchanger 130 that sucks the refrigerant having passed the expansion valve 140, and a valve device 160 that adjusts a flow rate of the refrigerant sucked into the first and second indoor heat exchangers 110 and 120.
The term indoor or interior space refers to the passenger cab of the electric vehicle. The term indoor heat exchanger refers to a heat exchanger that heat exchanges with indoor air or air within the indoor or interior space of the electric vehicle. The term outdoor heat exchanger refers to a heat exchanger that heat exchanges with outdoor air or air outside of the interior space of the electric vehicle.
The controller 180 may check a battery residue and an outdoor temperature, and it may control the valve device 160 to supply the refrigerant to at least one of the first indoor heat exchanger 101 or the second indoor heat exchanger 120 to meet a required heating performance and desired coefficient of heating performance of the air conditioning device. More particularly, the controller 180 may check a battery residue and an outdoor temperature. If there is sufficient battery residue to drive the vehicle, and based on the sensed outdoor temperature, the controller 180 may control the valve 160 to supply the refrigerant to at least one of the first and indoor heat exchanger 101 or the second indoor heat exchangers 110 and 120 to meet a required heating performance and desired coefficient of heating performance of the air-conditioning unit device.
The first and second indoor heat exchangers 110 and 120 discussed herein refer to heat exchangers that exchange heat with an indoor space of the electric vehicle (C) and the outdoor heat exchanger 130 refers to a heat exchanger arranged in a front portion of the electric vehicle that exchanges heat with outdoor air.
More specifically, the first and second indoor heat exchangers 110 and 120 may be in communication with the indoor space of the electric vehicle (C), and they may be arranged in an indoor duct 12 having an inlet 13 through which indoor air may be sucked and an outlet 14 through which heat-exchanged air may be exhausted to the indoor space. According to this embodiment, the first indoor heat exchanger 110 may be arranged adjacent to the outlet 14 of the indoor duct 12 and the second indoor heat exchanger 120 may be arranged adjacent to the inlet 13 of the indoor duct 12.
Also, the outlet 14 of the indoor duct 12 may include a first outlet hole (not shown), through which air may be exhausted toward the indoor space, and a second outlet hole (not shown), through which air may be exhausted toward a front window, which may be formed of glass. A damper may be provide at each of the outlet holes to adjust a flow rate of the air exhausted toward the indoor space and the front window. The heat-exchanged air may be exhausted only to the indoor space or only to the front window or to both of the indoor space and the front window based on an open degree of each damper. Air dehumidified in a dehumidifying operation mode, which will be described later, may be supplied to the front window.
The air conditioning device may further include a four-way valve 150. The four-way valve 150 may enable the air conditioning device to selectively perform a heating operation mode and a cooling operation mode.
In the heating operation mode, the refrigerant exhausted from the compressor 101 may be supplied to at least one of the first indoor heat exchanger 110 or the second indoor heat exchanger 120. The refrigerant may be condensed while first passing the at least one of the first indoor heat exchanger 110 or the second indoor heat exchanger 120, and it may heat the indoor air. Thereafter, the refrigerant may pass the expansion valve 140 and the outdoor heat exchanger 130 sequentially, to be evaporated while passing the outdoor heat exchanger 130.
In the cooling operation mode, the refrigerant exhausted from the compressor 101 may be sucked into the outdoor heat exchanger 130 and condensed while passing the outdoor heat exchanger 130. Thereafter, the refrigerant may pass the expansion vale 140 and at least one of the first indoor heat exchanger 110 or the second indoor heat exchanger 120 sequentially, to cool the indoor air with being evaporated while passing the at least one of the first indoor heat exchanger 110 or the second indoor heat exchanger 120.
The air conditioning device may include a first fan 171 mounted adjacent to the outdoor heat exchanger 130 and a second fan 172 mounted adjacent to the first and second indoor heat exchangers 110 and 120. The fans 171 and 172 may be controlled by the controller 180.
The air conditioning device may further include a temperature sensor 173 and a humidity sensor 174. The controller 180 may control the operation of the air conditioning device based on a detected temperature (the outdoor temperature and/or the indoor temperature) and a detected humidity in the indoor space.
That is, when the outdoor temperature is a preset value or less, the controller 180 may control the valve device 160 to enable the refrigerant to pass the first indoor heat exchanger 110 and the second indoor heat exchanger 120 such that the air conditioning device may be operated in a first or cold district heating operation mode to enhance the coefficient of performance.
In contrast, when the outdoor temperature is greater than the preset valve, the controller 180 may control the valve device 160 to enable the refrigerant to be sucked only into the first indoor heat exchanger 110 or the second indoor heat exchanger 120, such that the air conditioning device may be operated in a second or normal heating operation mode, to reduce the consumption of the battery 10.
According to one embodiment, the second indoor heat exchanger 120 may be located adjacent to the inlet 13 of the indoor duct 12, and the first indoor heat exchanger 110 may be located adjacent the outlet 14 of the indoor duct 12. The controller 180 may control the refrigerant to flow to the first indoor heat exchanger 110 in the normal heating operation mode. In contrast, the controller 180 may control the refrigerant to flow into the second indoor heat exchanger 120 in the normal heating operation mode, based on the structure of the first and second indoor heat exchangers 110 and 120, which may be layered or unfolded in the indoor duct 12.
In other words, the controller 180 may adjust the refrigerant drawn into each of the first and second indoor heat exchangers 110 and 120 based on the determined outdoor temperature or the battery residue to enhance a COP or heating performance of the air conditioning device. Also, the controller 180 may control the air conditioning device to be operated in the cold district heating operation mode or the normal heating operation mode or to be stopped.
The controller 180 may control the valve device 160 based on the battery residue to enhance the coefficient of performance of the air conditioning device or the valve device 160 to enhance the heating performance of the air conditioning device.
The preset temperature may be, for example, approximately 0° C. More specifically, in an environment having a temperature above 0° C., the controller 180 may operate the air conditioning device in the normal heating operation mode. In an environment having a temperature 0° C. or less, the controller 180 may operate the air conditioning device in the cold district heating operation mode. Further, the preset temperature may be approximately −10° C., and the air conditioning device having the structure discussed above may be operated with a COP of 1 or more, even in an outdoor temperature below approximately −10° C.
The valve device 160 according to this embodiment may include a first solenoid valve 161 that adjusts a flow rate of the refrigerant drawn into the second indoor heat exchanger 120 from the compressor 101, a second solenoid valve 162 that adjusts a flow rate of the refrigerant exhausted from the first indoor heat exchanger 110, and an electronic expansion valve 163 that adjusts a flow rate of the refrigerant transferred to the second indoor heat exchanger 120 from the first indoor heat exchanger 110.
With reference to
With reference to
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A valve device 160 according to this embodiment may include a solenoid valve 164 that adjust a flow rate of the refrigerant drawn into the first indoor heat exchanger 110 from the compressor 101 and an electronic expansion valve 165 that adjusts a flow rate of the refrigerant drawn into the second indoor heat exchanger 120. The controller 180 may control the solenoid valve 164 and the electronic expansion valve 165 to be open in the cold district heating operation mode. The controller 180 may control the solenoid valve 164 or the electronic expansion valve 165 to be closed in the normal heating operation mode.
According to this embodiment, the controller 180 may control the refrigerant to flow only into the first indoor heat exchanger 110 in the normal heating operation mode as discussed above. In this instance, the controller 180 may open the solenoid valve 164 and close the electronic expansion valve 165.
So far, the valve device 160 according to the embodiments discussed above is described as controlling the refrigerant to flow into at least one of the first indoor heat exchanger 110 or the second indoor heat exchanger 120. However, embodiments are not limited thereto and the first and second indoor heat exchangers 110 and 120 may be connected with the compressor 101 in serial or in parallel. The valve device 160 may include a proper number of solenoid valves or electronic expansion valves within the spirit and scope of the principles of this disclosure. It is obvious that positions of the solenoid valves and/or electronic expansion valves may vary.
As described above, the air conditioner for an electric vehicle according to embodiments disclosed herein may stably perform a heating operation at a low outdoor temperature in a cold district. Further, the air conditioner for an electric vehicle according to embodiments disclosed herein may enhance heating performance or coefficient of heating performance in a cold district. Furthermore, the air conditioner for an electric vehicle according to embodiments disclosed herein may enhance heating performance or coefficient of heating performance based on an outdoor temperature, considering battery efficiency.
To simultaneously perform the cold district heating operation mode and a dehumidifying operation mode according to embodiments, the air conditioner 100 may include the air conditioning device having the compressor 101 that compresses refrigerant, the first indoor heat exchanger 110 located adjacent to the inlet 13 of indoor air, the second indoor heat exchanger 120 located adjacent to the outlet 14 of indoor air, and the valve device 160 that adjusts the flow rate of refrigerant drawn into the first and second indoor heat exchangers 110 and 120. The air conditioner 100 may check at least two or more of a battery residue, an outdoor temperature, and an indoor humidity. The air conditioner 100 may include the controller 180 that controls the valve device 160, to enable condensation or evaporation of refrigerant performed in the first and second indoor heat exchangers 110 and 120.
The controller 180 may determine the battery residue and the indoor humidity, and it may control the refrigerant evaporated in the second indoor heat exchanger. The controller 180 may control the valve device 160 such that refrigerant is evaporated in the second indoor heat exchanger, and it may operate the air conditioning device in a dehumidifying operation mode. More particularly, the controller 180 may check the battery residue and the indoor humidity. If there is sufficient battery residue to drive the vehicle, and the indoor humidity is a predetermined humidity or greater, the controller 180 may control the valve device 160 such that refrigerant is evaporated in the second indoor heat exchanger, and it may operate the air conditioning device in a dehumidifying operation mode.
Also, the controller 180 may determine the battery residue and the outdoor temperature. The controller 180 may control the valve device 160 such that the refrigerant is evaporated in the first and second indoor heat exchangers 110 and 120, such that it may operate the air conditioning device in a cold district heating operation mode. That is, if the battery residue remains sufficient to drive the vehicle and the outdoor temperature is a preset value or less, the controller 180 may control the valve device 160 such that the refrigerant is evaporated in the first and second indoor heat exchangers 110 and 120, such that it may operate the air conditioning device in a cold district heating operation mode.
More particularly, when the indoor humidity is the predetermined humidity or greater, the controller 180 may control the air conditioning device to be operated in the cold district heating operation mode for a predetermined time period after controlling the air conditioning device to be operated in the dehumidifying operation mode. That is, when the outdoor temperature is a predetermined temperature or less, the controller 180 may control the air conditioning device to be operated in the cold district heating operation mode. When the indoor humidity of the electric vehicle (C) is a predetermined humidity or greater, the controller 180 may control the air conditioning device to be operated in the dehumidifying operation mode. In this instance, the first indoor heat exchanger 110 may be used as a condenser and the second indoor heat exchanger 120 as an evaporator, such that the indoor space may be continuously heated even in the dehumidifying operation mode. After the indoor humidity is reduced, the electric vehicle (C) may be again operated in the cold district heating mode, if appropriate.
More specifically, the indoor air drawn into the indoor duct 12 may be dehumidified while passing the second indoor heat exchanger 120 and the dehumidified air may be supplied to the indoor space after being heated via the first indoor heat exchanger 110.
With reference to
Accordingly, the refrigerant may be drawn into the first and second indoor heat exchangers 110 and 120 in the cold district operation mode, and condensation of refrigerant may be performed in both of the first and second indoor heat exchangers 110 and 120. In contrast, the refrigerant may pass the first indoor heat exchanger 110, the electronic expansion valve 163, and the second indoor heat exchanger 120 sequentially, and the refrigerant may be condensed in the first indoor heat exchanger 110 and evaporated in the second indoor heat exchanger 120, in the dehumidifying operation mode. In other words, in the dehumidifying operation mode, the first indoor heat exchanger 110 may be operated as the condenser and the second indoor heat exchanger 120 may be operated as the evaporator, such that the dehumidified air may be exhausted toward the front glass window as discussed above.
With reference to
Accordingly, in the cold district heating operation mode, the refrigerant may be drawn into both of the first and second indoor heat exchangers 110 and 120, and the refrigerant may be condensed in the indoor heat exchangers 110 and 120. However, in the dehumidifying operation mode, a predetermined amount of refrigerant may pass the solenoid valve 164 and the first indoor heat exchanger 110, and the remaining refrigerant may pass the electronic expansion valve 165 and the second indoor heat exchanger 120. Also, in the dehumidifying operation mode, the refrigerant may be condensed in the first indoor heat exchanger 110 and evaporated in the second indoor heat exchanger 120.
When the outdoor temperature is less than a predetermined temperature (for example, approximately 0° C.), the controller 180 may control the valve device 160 such that the refrigerant is condensed in the first indoor heat exchanger 110 and the second indoor heat exchanger 120, such that the air conditioning device is operated in the cold district heating operation mode. In contrast, when the outdoor temperature is the predetermined temperature or greater, the controller 180 may control the valve device 160 such that the refrigerant is condensed in one of the first indoor heat exchanger 110 or the second indoor heat exchanger 120 and is drawn into the other one such that the air conditioning device may be operated in the normal heating operation mode.
The controller 180 may operate the air conditioning device in the cold district heating operation mode or the normal heating operation mode, or it may stop the air conditioning device, based on the battery residue. The controller 180 may control the valve device 160 based on the battery residue, to enhance the coefficient of heating performance of the air conditioning device or to enhance the heating performance of the air conditioning device.
Conversion of the cold district heating operation mode to the normal heating operation mode is described with reference to the valve device 160 according to the embodiments disclosed herein and detailed description thereof has been omitted accordingly.
The air conditioner having the structure discussed above may be operated in the cold district heating operation mode and the normal heating operation mode based on outdoor temperature, battery residue, and indoor humidity via a single cycle. Therefore, the air conditioner for an electric vehicle according to embodiments disclosed herein stably perform a heating operation at a low temperatures in cold districts. Further, the air conditioner for an electric vehicle according to embodiments disclosed herein may enhance heating performance or coefficient of heating performance in the cold districts. Still further, the air conditioner for an electric vehicle according to embodiments disclosed herein may enhance the heating performance or coefficient of heating performance, considering the efficiency of the battery based on an outdoor temperature. Still further, the air conditioner for an electric vehicle according to embodiments disclosed herein may perform the heating operation simultaneously with the dehumidifying operation.
Embodiments disclosed herein provide an air conditioner for an electric vehicle that is able to stably perform a heating operation at low temperatures in cold districts. Further, embodiments disclosed herein provide an air conditioner for an electric vehicle that is able to enhance heating performance or a coefficient of heating performance in cold districts.
Furthermore, embodiments disclosed herein provide an air conditioner for an electric vehicle that is able to enhance the heating performance or coefficient of heating performance, considering efficiency of a battery based on an outdoor temperature. Additionally, embodiments disclosed herein provide an air conditioner for an electric vehicle that is able to perform the heating operation simultaneously with a dehumidifying operation.
Embodiments disclosed herein provide an air conditioner for an electric vehicle driven by a battery as a driving source that may include an air conditioning unit or device including a compressor that compresses a refrigerant; first and second indoor heat exchangers that suck the refrigerant exhausted from the compressor; an expansion valve that expands the refrigerant having passed one of the first and second indoor heat exchangers; an outdoor heat exchanger that sucks the refrigerant having passed the expansion valve; a valve unit or device that adjusts a flow rate of the refrigerant sucked into the first and second indoor heat exchangers; and a controller that checks a residue of the battery and an outdoor temperature and controls the valve unit to flow the refrigerant into at least one of the first and second indoor heat exchangers to meet a required heating performance and desired coefficient of heating performance.
The controller may operate the air conditioning unit in a cold district heating operation mode by controlling the valve unit for the refrigerant to pass the first and second indoor heat exchangers to enhance the coefficient of heating performance, when the outdoor temperature is less than a predetermined temperature. The controller may operate the air conditioning unit in a normal heating operation mode by controlling the valve unit for the refrigerant to be drawn into the first indoor heat exchanger or the second indoor heat exchanger to reduce the battery residue, when the outdoor temperature is the predetermined temperature or more. The predetermined temperature may be 0° C.
The first indoor heat exchanger may be located adjacent to an outlet of indoor air, and the second indoor heat exchanger may be located adjacent to an inlet of indoor air. The controller may control the refrigerant to flow into the first indoor heat exchanger in the normal heating operation mode.
The controller may operate the air conditioning unit in the cold district heating operation mode or the normal heating operation mode or stop the operation of the air conditioning unit, based on a residue of the battery. The controller may control the valve unit to enhance a coefficient of heating performance of the air conditioning unit or heating performance of the air conditioning unit, based on a residue of the battery.
The valve unit may include a first solenoid valve that adjusts a flow rate of refrigerant drawn into the second indoor heat exchanger from the compressor, a second solenoid valve that adjusts a flow rate of the refrigerant exhausted from first indoor heat exchanger, and a first electronic expansion valve that adjusts a flow rate of the refrigerant transferred to the second indoor heat exchanger from the first indoor heat exchanger. The controller may control the first and second solenoid valves to be open and the first electronic expansion valve to be closed in the cold district heating operation mode, and may control the second solenoid valve to be open and the first solenoid valve and the first electronic expansion valve to be closed in the normal heating operation mode.
The valve unit may include a third solenoid valve that adjusts a flow rate of refrigerant drawn into the first indoor heat exchanger from the compressor and a second electronic expansion valve that adjusts a flow rate of refrigerant drawn into the second indoor heat exchanger. The controller may control the third solenoid valve and the second electronic expansion valve to be open in a cold district heating operation mode, and the first solenoid valve or the second electronic expansion valve to be closed in a normal heating operation mode.
Embodiments disclosed herein further provide an air conditioner for an electric vehicle driven by a battery as a driving source that may include an air conditioning unit or device including a compressor that compresses a refrigerant; a first indoor heat exchanger arranged adjacent to an outlet of indoor air that sucks and a second indoor heat exchanger arranged adjacent to an inlet of indoor air, the first and second indoor heat exchangers sucking the refrigerant exhausted from the compressor; and a valve unit or device that adjusts a flow rate of the refrigerant sucked into the first and second indoor heat exchangers; and a controller that checks two or more of a residue of the battery, an outdoor temperature, and an indoor humidity and to control the valve unit for the refrigerant to be condensed or evaporated in the first and second indoor heat exchangers.
An air conditioner for an electric vehicle according to embodiments may perform a heating operation at low temperatures in cold districts stably. Further, an air conditioner for an electric vehicle according to embodiments may enhance heating performance or coefficient of heating performance in the cold districts.
Furthermore, an air conditioner for an electric vehicle according to embodiments may enhance heating performance or a coefficient of heating performance, considering an efficiency of the battery based on an outdoor temperature. Still further, an air conditioner for an electric vehicle according to embodiments may perform a heating operation simultaneously with a dehumidifying operation.
It is to be understood that both the foregoing general description and the following detailed description of the embodiments or arrangements are exemplary and explanatory and are intended to provide further explanation of the embodiments as claimed.
Any reference in this specification to “one embodiment,” “an embodiment,” “example embodiment,” etc., means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the purview of one skilled in the art to effect such feature, structure, or characteristic in connection with other ones of the embodiments.
Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2012-0012193 | Feb 2012 | KR | national |
