Patent Grant
8346090
This application is based on and incorporates herein by reference Japanese Patent Application No. 2009-86704 filed on Mar. 31, 2009.
The present invention relates to an infrared communication system, a movable object, and a supply facility. The present invention further relates to a method for performing an infrared communication in the same.
In recent years, a fuel cell vehicle (FCV) has been developed. The FCV has a fuel cell to cause a chemical reaction of hydrogen and oxygen so as to generate electric energy. The FCV consumes the generated electric energy to activate a motor so as to obtain driving force of the vehicle. The FCV is connected with a feed pipe in a hydrogen station to supply hydrogen (fuel) to the FCV through the feed pipe. So as to efficiently charge hydrogen, it is desirable to charge high-pressure hydrogen to the FCV. However, in view of safety, monitoring of a temperature and a pressure of a hydrogen tank of the FCV is required when hydrogen is charged to the hydrogen tank. In addition, control of a supply pressure of hydrogen is required in the hydrogen station according to the monitored temperature and the monitored pressure when hydrogen is charged. Therefore, a communication system for transmitting a temperature and a pressure monitored by the FCV to the hydrogen station is needed. For example, such a communication system may employ an electric wave communication or an infrared communication (see JP-A-2009-10682).
In general, the directivity of an electric wave is low, and an electric wave may easily diffuse around. Therefore, when multiple FCVs perform an electric wave communication in a hydrogen station, interference may arise in the electric wave communication. On the other hand, the directivity of infrared ray is high. Accordingly, in an infrared communication system, the optic axis of an infrared communication device of the FCV needs to coincide with an infrared communication device of the hydrogen station so as to perform an infrared communication. The optic axis of an infrared communication device of the FCV is changed in dependence upon the position and the direction of the FCV. Therefore, it is hard to adjust the optic axis of the infrared communication device of the FCV to coincide with the optic axis of the infrared communication device of the hydrogen station.
In view of the foregoing and other problems, it is an object of the present invention to produce an infrared communication system, a movable object, and a supply facility, configured to perform a communication between the movable object and the supply facility while restricting interference in the communication. It is another object of the present invention to produce a method for performing an infrared communication in the infrared communication system.
According to one aspect of the present invention, an infrared communication system configured to perform an infrared communication between a movable object having a connection port and a supply facility for supplying fluid to the movable object through a feed pipe connectable with the connection port, the infrared communication system comprises a movable-object-side infrared communication device provided to the movable object. The infrared communication system further comprises a supply-facility-side infrared communication device provided to the feed pipe of the supply facility and configured to be located in a position in which the supply-facility-side infrared communication device is capable of communicating with the movable-object-side infrared communication device via an infrared communication when a feed connector of the feed pipe is connected with the connection port. A rotation phase of the feed connector of the feed pipe is variable around an axial direction when the feed pipe is connected with the connection port. At least one of the movable-object-side infrared communication device and the supply-facility-side infrared communication device includes a plurality of infrared communication elements. At least one of the plurality of infrared communication elements is in a communicable position in which the at least one of the plurality of infrared communication elements is capable of performing the infrared communication, regardless of the rotation phase.
According to one aspect of the present invention, a method for performing an infrared communication between a movable object and a supply facility, the supply facility being for supplying fluid to the movable object through a feed pipe of the supply facility, the feed pipe being connectable with a connection port of the movable object, a rotation phase of a feed connector of the feed pipe being variable around its axis when the feed pipe is connected with the connection port, the method comprises detecting at least one of a plurality of infrared communication elements, which is provided to one of the feed connector of the feed pipe and the movable object and communicable with an infrared communication device on an opposite side of the at least one of the plurality of infrared communication elements when the feed pipe is connected with the connection port. The method further comprises performing an infrared communication via the detected at least one of the plurality of infrared communication elements when the feed pipe is connected with the connection port, regardless of the rotation phase.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
An overview structure of a hydrogen station (supply facility) 1 and a vehicle (movable object) 3 of an infrared communication system will be described with reference to
The hydrogen tank 5 includes a feed apparatus 5a for discharging hydrogen stored in the hydrogen tank 5 to the charging nozzle 9 through a hydrogen supply pipe (feed pipe) 12. The control system 7 includes a communication control unit 13 and a charging control unit 15. The communication control unit 13 is respectively connected with the multiple infrared communication devices 11a, 11b, and the like via communication channels 17a, 17b and the like. The communication control unit 13 has a function to select one of the communication channels 17a, 17b, and the like used for an infrared communication. The function will be described later in detail. The communication control unit 13 inputs a vehicle tank temperature and a vehicle tank pressure via the one of the communication channels 17a, 17b, and the like and outputs the vehicle tank temperature and the vehicle tank pressure to the charging control unit 15. The charging control unit 15 has a function to determine a pressure (hydrogen supply pressure) when the feed apparatus 5a supplies hydrogen based on the vehicle tank temperature and the vehicle tank pressure inputted from the communication control unit 13.
The vehicle 3 being a fuel cell vehicle (FCV) includes a hydrogen tank 19 for storing hydrogen, a hydrogen charging control ECU 21 for controlling a communication with the vehicle 3, a receptacle (connection port) 23, and multiple infrared communication devices 25a, 25b, and the like. The number of the multiple infrared communication, devices 25a, 25b may be two and may be a number greater than or equal to three, such as three, four, five, or six.
The hydrogen tank 19 includes a temperature sensor 27 for detecting its temperature (vehicle tank temperature) and a pressure sensor 29 for detecting its pressure (vehicle tank pressure). The hydrogen charging control ECU 21 includes a data processing unit 31, a communication control unit 33, and a storage unit 34. The data processing unit 31 periodically obtains the vehicle tank pressure from the pressure sensor 29 and the vehicle tank temperature from the temperature sensor 27. The data processing unit 31 outputs the obtained vehicle tank temperature and the obtained vehicle tank pressure to the communication control unit 33. The communication control unit 33 is respectively connected with the multiple infrared communication devices 25a, 25b, and the like via communication channels 35a, 35b and the like. The communication control unit 33 has a function to select one of the communication channels 35a, 35b, and the like used for the infrared communication. The function will be described later in detail. The communication control unit 33 is configured to transmit the vehicle tank temperature and the vehicle tank pressure to either one of the multiple infrared communication devices 11a, 11b, and the like via the infrared communication using the selected one of the communication channel 35a, 35b, and the like. The storage unit 34 is configured to store various data.
The receptacle 23 is provided to the exterior of the body of the vehicle 3 and mechanically connectable with the charging nozzle 9. The receptacle 23 has an inner portion connectable with the hydrogen tank 19 through a hydrogen supply pipe 37. Hydrogen is supplied to the receptacle 23 through the charging nozzle 9, and the hydrogen is fed into the hydrogen tank 19 through the hydrogen supply pipe 37. The vehicle 3 further has a generally-known structure as a FCV.
Subsequently, a structure around the charging nozzle 9 and the receptacle 23 will be described further in detail with reference to
The receptacle 23 is a doughnut-shape member having a circular hole 45 at the center. The diameter of the hole 45 is slightly greater than the outer diameter of the inner pipe 39 and smaller than the outer, diameter of the outer pipe 41. Therefore, only the projection 43 of the inner pipe 39 can be inserted in the hole 45. The multiple infrared communication devices 25a, 25b, and the like are located on the lateral surface of the receptacle 23 and arranged along the hole 45. The multiple infrared communication devices 25a, 25b, and the like are arranged along the periphery of the hole 45 at a regular interval, for example. The multiple infrared communication devices 25a, 25b, and the like are arranged to enable infrared communication along a direction perpendicular to a main surface of the receptacle 23, i.e., in an opposite direction to the solid arrow in
Each infrared communication device is configured to emit infrared ray in a constant spread range to have a specific communication range. Accordingly, each infrared communication device need not be exactly coaxial with an opposed infrared device to enable an infrared communication. Even when a communication range of each infrared communication device is narrow, an infrared communication can be enabled, regardless of the rotation phase of the charging nozzle 9, by increasing the number of the infrared communication devices to reduce the distance between adjacent infrared devices. On the contrary, when a communication range of each infrared communication device is wide, the number of the infrared communication devices may be small.
Subsequently, a method for transmitting the vehicle tank temperature and the vehicle tank pressure from the vehicle 3 to the hydrogen station 1 via an infrared communication will be described. As described above, the data processing unit 31 of the vehicle 3 periodically obtains the vehicle tank temperature and the vehicle tank pressure. The communication control unit 33 of the vehicle 3 detects one of the multiple infrared communication devices 25a, 25b, and the like, which is in a position to be communicable via an infrared communication. Specifically, the communication control unit 33 performs a negotiation with the one of the multiple infrared communication devices 25a, 25b. That is, the communication control unit 33 and the one of the multiple infrared communication devices 25a, 25b exchange data (test data) for test in a condition where only one of the multiple infrared communication devices 25a, 25b, and the like is activated (turned ON). The communication control unit 33 repeats the negotiation while switching the one activated infrared communication device. In the state shown in
The communication control unit 33 of the vehicle 3 transmits the vehicle tank temperature and the vehicle tank pressure via an infrared communication using the one of the multiple infrared communication devices 25a, 25b, and the like, which is determined to be in a position in which the one device is capable of performing an infrared communication. The communication control unit 13 of the hydrogen station 1 receives the vehicle tank temperature and the vehicle tank pressure transmitted using the one of the multiple infrared communication, devices 25a, 25b, and the like, which is determined to be in a position in which the one device is capable of performing an infrared communication. The communication control unit 13 outputs the received vehicle tank temperature and the received vehicle tank pressure to the charging control unit 15.
In the present embodiment, an infrared communication, which is high in directivity, is used. Therefore, even when, for example, multiple vehicles 3 are close to the hydrogen station 1, interference can be restricted in the infrared communication, dissimilarly to a communication using an electric wave.
Further, in the present embodiment, even when the rotation phase of the charging nozzle 9 connecting with the receptacle 23 changes, an infrared communication can be regularly maintained. Therefore, when the charging nozzle 9 is connected to the receptacle 23, the rotation phase of the charging nozzle 9 need not be adjusted, and thereby an infrared communication can be easily performed.
Further, in the present embodiment, the rotation phase of the charging nozzle 9 need not be fixed at a specific phase when being connected with the receptacle 23. Therefore, a mechanism for adjusting the rotation phase of the charging nozzle 9 at a specific phase need not be provided. Therefore, the structure of the charging nozzle 9 and the receptacle 23 can be simplified, compared with a structure including such a mechanism for adjusting the rotation phase. Thus, a manufacturing cost of the infrared communication system can be reduced.
In addition, in a case where such a mechanism is provided to fix the rotation phase of the charging nozzle 9 at a specific phase when being connected with the receptacle 23, each of the receptacle 23 and the charging nozzle 9 need to conform to a specific standard. When a standard, which the receptacle 23 conforms, is different from a standard, which the charging nozzle 9 conforms, the charging nozzle 9 cannot be connected to the receptacle 23. On the contrary, according to the present embodiment, the rotation phase of the charging nozzle 9 need not be adjusted at a specific phase when connecting with the receptacle 23. Therefore, such a problem of connection can be avoided.
As shown in
Summarizing the above embodiments, the infrared communication system is configured to perform an infrared communication between a movable object having a connection port and a supply facility for supplying fluid to the movable object through a feed pipe connectable with the connection port. The movable object includes a movable-object-side infrared communication device. The supply facility includes a supply-facility-side infrared communication device at the feed pipe. The supply-facility-side infrared communication device is located in a position in the feed pipe such that the supply-facility-side infrared communication device is communicable with the movable-object-side infrared communication device via an infrared communication when the feed pipe is connected to the connection port. Specifically, for example, the supply-facility-side infrared communication device is located in a position where an optic axis of the movable-object-side infrared communication device substantially coincides with an optic axis of the supply-facility-side infrared communication device when the feed pipe is connected to the connection port.
A portion of the feed pipe, such as a nozzle, connected to the connection port is in a phase (rotation phase of the feed pipe), which is variable around an axial direction when the feed pipe is connected to the connection port. At least one of the movable-object-side infrared communication device and the supply-facility-side infrared communication device includes multiple infrared communication elements. At least one of the multiple infrared communication elements is in a position in which the one element is communicable with the other infrared communication device via an infrared communication, regardless of the rotation phase of the feed pipe. When the one of the multiple infrared communication elements is included in the movable-object-side infrared communication device, the other infrared communication device is included in the supply-facility-side infrared communication device. Alternatively, when the one of the multiple infrared communication element is the supply-facility-side infrared communication device, the other infrared communication device is included in the movable-object-side infrared communication device.
In the infrared communication system, an infrared communication, which is high in directivity, is used. Therefore, even when, for example, multiple movable objects are close to the supply facility, interference can be restricted in the infrared communication, dissimilarly to a communication using an electric wave.
Further, in the infrared communication system, even when the rotation phase of the feed pipe changes when connecting with the connection port, an infrared communication can be regularly enabled. Therefore, when the feed pipe is connected to the connection port, the rotation phase of the feed pipe need not be adjusted, and thereby an infrared communication can be easily performed.
Further, in the infrared communication system, the rotation phase of the feed pipe need not be fixed at a specific phase when being connected with the connection port. Therefore, a mechanism for adjusting the rotation phase of the feed pipe at a specific phase need not be provided. Therefore, the structure of the infrared communication system can be simplified, compared with a structure including such a mechanism for adjusting the rotation phase. Thus, a manufacturing cost of the infrared communication system can be reduced.
In addition, in a case where such a mechanism is provided to fix the rotation phase of the feed pipe at a specific phase when being connected with the connection port, each of the connection port and the feed pipe need to conform to a specific standard. When a standard, which the connection, port conforms, is different from a standard, which the feed pipe conforms, the feed pipe cannot be connected to the connection port. On the contrary, according to the present embodiment, the rotation phase of the feed pipe need not be adjusted at a specific phase when connecting with the connection port. Therefore, such a problem of connection can be avoided.
For example, in the infrared communication system, the movable object may include a single element of the movable-object-side infrared communication device, and the feed pipe of the supply facility may include multiple supply-facility-side infrared communication elements. In this case, one of the multiple supply-facility-side infrared communication elements is in a position in which the one element is communicable with the movable-object-side infrared communication device via an infrared communication when the feed pipe is connected to the connection port. When the rotation phase of the feed pipe changes, another one of the multiple supply-facility-side infrared communication elements moves to a position in which the other one element is communicable with the movable-object-side infrared communication device via an infrared communication. That is, at least one of the multiple supply-facility-side infrared communication elements is in a position in which the at least one element is communicable with the movable-object-side infrared communication device via an infrared communication in substantially any rotation phase of the feed pipe.
For example, in the infrared communication system, the movable object may include multiple movable-object-side infrared communication elements, and the feed pipe of the supply facility may include a single element of the supply-facility-side infrared communication device. In this case, one of the multiple movable-object-side infrared communication elements is in a position in which the one element is communicable with the supply-facility-side infrared communication device via an infrared communication when the feed pipe is connected to the connection port. When the rotation phase of the feed pipe changes, another one of the multiple movable-object-side infrared communication elements moves to a position in which the other one element is communicable with the supply-facility-side infrared communication device via an infrared communication. That is, at least one of the multiple movable-object-side infrared communication elements is in a position in which the at least one element is communicable with the supply-facility-side infrared communication device via an infrared communication in substantially any rotation phase of the feed pipe.
For example, in the infrared communication system, the movable object may include multiple movable-object-side infrared communication elements, and the feed pipe of the supply facility may include multiple the supply-facility-side infrared communication elements. In the present structure, at least one of the multiple movable-object-side infrared communication elements is in a position in which the at lest one element is communicable with at least one of the multiple the supply-facility-side infrared communication elements via an infrared communication, regardless of the rotation phase of the feed pipe when the feed pipe is connected to the connection port.
In the infrared communication system, for example, when the movable object includes the multiple movable-object-side infrared communication elements, the movable object may include a detection unit configured to detect one of the multiple movable-object-side infrared communication elements, which is in a position in which the one element is communicable with the supply-facility-side infrared communication device via an infrared communication.
Alternatively, in the infrared communication system, for example, when the supply facility (supply pipe) includes the multiple supply-facility-side infrared communication elements, the supply facility may include a detection unit configured to detect one of the multiple supply-facility-side infrared communication elements, which is in a position in which the one element is communicable with the movable-object-side infrared communication device via an infrared communication.
In the present structure, an infrared communication can be smoothly performed using the one of the movable-object-side infrared communication elements or the one of the supply-facility-side infrared communication elements detected by the detection unit.
The detection unit may be configured to performs, for example, a negotiation. Specifically, test data may be exchanged in a condition where only one of the multiple infrared communication elements is activated. The exchange of test data is repeated, while the one activated infrared communication element is switched. Consequently, the infrared communication element, which can exchange the test data, is determined to be in a position in which the infrared communication element is communicable via an infrared communication. For example, when two or more infrared communication elements can exchange the test data, the test (negotiation) may be repeated to select one of the infrared communication elements, which has the highest number of successful exchanges of the test data.
In another way, for example, the detection unit may have software for detecting one infrared communication element, which actually completes successful exchange of test data in a state where all the multiple infrared communication elements are activated.
The connection port may be, for example, a hole provided in the movable object. The connection port may be, for example, a circular hole when viewed from its front side. The feed pipe may have, for example, a tip end having a nozzle configured to be inserted in the hole. The nozzle may have, for example, a circular cross section perpendicular to its axial direction. In this case, the feed pipe can be connected with the connection port (hole) by inserting the nozzle of the feed pipe into the hole of the movable object. When the difference between the diameter of the hole of the movable object and the outer diameter of the nozzle is set to be sufficiently small, the position of the nozzle inserted in the hole of the movable object and the axial direction of the nozzle can be uniquely determined at a specific position and a specific direction respectively. The rotation phase of the nozzle inserted in the hole of the movable object is variable.
For example, one of the movable-object-side infrared communication device and the supply-facility-side infrared communication device may be configured only to transmit an infrared ray, and the other of the movable-object-side infrared communication device and the supply-facility-side infrared communication device may be configured only to receive an infrared ray. Alternatively, for example, both the movable-object-side infrared communication device and the supply-facility-side infrared communication device may be configured to transmit and receive an infrared ray.
The movable object may be, for example, a vehicle, a vessel, an airplane, and the like. The vehicle may be, for example, a passenger car, a track, a two-wheeled vehicle, a railway car, and the like. A state of the fluid may be, for example, liquid or gas. The fluid may be various fuel. Specifically, the fluid may be, for example, hydrogen, gasoline, heavy oil, light oil, liquefied petroleum gas (LPG), alcohol such as ethanol, and the like.
In the infrared communication system, the movable object and the supply facility may exchange, for example, information specifying a state of a tank of the movable object for receiving fluid, identification information specifying the movable object and the supply facility, and the like. The state of the tank of the movable object may include a temperature of the fluid, a pressure of the fluid, a charged amount of the fluid, and/or the like.
The above processings such as calculations and determinations are not limited being executed by the control system 7, the hydrogen charging control ECU 21, and the like. The control unit may have various structures including the control system 7, the hydrogen charging control ECU 21, and the like shown as an example.
The above processings such as calculations and determinations may be performed by any one or any combinations of software, an electric circuit, a mechanical device, and the like. The software may be stored in a storage medium, and may be transmitted via a transmission device such as a network device. The electric circuit may be an integrated circuit, and may be a discrete circuit such as a hardware logic configured with electric or electronic elements or the like. The elements producing the above processings may be discrete elements and may be partially or entirely integrated.
It should be appreciated that while the processes of the embodiments of the present invention have been described herein as including a specific sequence of steps, further alternative embodiments including various other sequences of these steps and/or additional steps not disclosed herein are intended to be within the steps of the present invention.
Various modifications and alternations may be diversely made to the above embodiments without departing from the spirit of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2009-086704 | Mar 2009 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 5272350 | Solari et al. | Dec 1993 | A |
| 20100276031 | Saiki et al. | Nov 2010 | A1 |
| Number | Date | Country |
|---|---|---|
| 102005033854 | Jan 2007 | DE |
| 2009-010682 | Jan 2009 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20100247108 A1 | Sep 2010 | US |
