This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2015-148038 filed on Jul. 27, 2015, the disclosure of which is incorporated by reference herein in its entirety.
Technical Field
Preferred embodiments relate to a fuel tank structure.
Related Art
A structure in which a canister is provided in order to adsorb evaporative fuel (i.e., fuel vapor) is known as a structure for a fuel tank that is mounted in an automobile. In this kind of structure, because the evaporative fuel that has been adsorbed in the canister is purged using negative pressure from the intake manifold, pumping loss increases and it is difficult to improve fuel consumption.
To counter this, a structure has been disclosed in Japanese Patent Publication No. 5299565 in which a gas separator is connected to the fuel tank. In this structure, by operating the gas separator so that atmospheric constituents inside the fuel tank are discharged to the outside, the internal pressure in the fuel tank is reduced, and evaporative fuel that has been adsorbed in the canister is purged.
However, in the fuel tank structure disclosed in Japanese Patent Publication No. 5299565, in addition to the gas separator that is used to reduce the internal pressure in the fuel tank, a mechanism to switch opening/closing of the canister and the gas separator is also required, so that the complexity of the structure increases. Moreover, because energy (i.e., power) to operate the gas separator is also required, there is also room for improvement from the standpoint of improving fuel consumption.
In consideration of the above circumstances, an object of preferred embodiments is to provide a fuel tank structure that makes it possible to improve fuel consumption by means of simple structure.
A fuel tank structure of a first aspect of the disclosure includes a fuel tank that is mounted in a vehicle and that is provided with a holding portion that holds fuel; a canister that communicates with the outside atmosphere; a first pipe that joins together the holding portion and the canister; a first shut-off valve that opens and closes the first pipe; a filler pipe that is connected to the holding portion, and that is provided with a refueling aperture into which a nozzle of a fueling gun is inserted and that remains closed other than during refueling; a second pipe that joins together the filler pipe and the canister; a second shut-off valve that opens and closes the second pipe; a pressure sensor that detects an pressure inside the holding portion; a fuel pump that feeds the fuel inside the holding portion to an engine; and a control unit that opens the first shut-off valve during refueling so that evaporative fuel is permitted to move from the holding portion to the canister, and that closes the first shut-off valve after refueling, and that also opens the second shut-off valve when the pressure inside the holding portion which is detected by the pressure sensor drops below a predetermined pressure which is lower than the atmospheric pressure.
In the fuel tank structure according to the first aspect of the disclosure, the fuel tank is provided with a holding portion that is used to hold fuel. A filler pipe is connected to the holding portion. The holding portion is joined to a canister by a first pipe and a first shut-off valve is provided at the first pipe. The filler pipe and the canister are joined together by a second pipe and a second shut-off valve is provided at the second pipe. Here, during refueling, the first shut-off valve is opened by the control unit so that the movement of evaporative fuel from the holding portion of the fuel tank to the canister is permitted. As a consequence of this, during refueling, the evaporative fuel inside the holding portion flows through the first pipe and is adsorbed in the canister, while gaseous components other than the evaporative fuel are discharged into the atmosphere. In this manner, the evaporative fuel is prevented from being discharged into the atmosphere.
After refueling, the first shut-off valve is closed. In this state, when the fuel inside the holding portion is fed to the engine by the fuel pump, the pressure inside the holding portion drops. In the event that the pressure inside the holding portion which is detected by a pressure sensor drops below a predetermined pressure that is lower than the atmospheric pressure, the control unit opens the second shut-off valve. As a consequence of this, air is introduced into the second pipe, and the evaporative fuel that had been adsorbed by the canister is purged from the canister. This evaporative fuel then flows into the filler pipe through the second pipe and flows into the holding portion. In this manner, it is possible to recover the evaporative fuel adsorbed by the canister by a simple structure without having to use an apparatus such as a gas separator.
The fuel tank structure of a second aspect of the disclosure, in the fuel tank structure according to the first aspect, wherein the second shut-off valve is formed so as to be able to adjust a flow rate of the evaporative fuel flowing through the second pipe, and the control unit controls the second shut-off valve such that the flow rate of the evaporative fuel flowing through the second pipe is less than a flow rate of the fuel being fed to the engine by the fuel pump.
In the fuel tank structure according to the second aspect of the disclosure, the flow rate of the evaporative fuel flowing through the second pipe is less than the flow rate of the fuel that is fed to the engine from the fuel pump. As a consequence of this, it is possible to maintain the pressure inside the holding portion as a negative pressure, and to stably recover evaporative fuel from the canister.
The fuel tank structure of a third aspect of the disclosure, in the fuel tank structure according to the first and second aspects, wherein the holding portion is formed so as to be able to expand and contract and a plurality of ribs are provided standing upright on a bottom portion of the holding portion.
In the fuel tank structure according to the third aspect of the disclosure, the holding portion is expanded as a result of fuel being supplied to the holding portion. The holding portion is contracted as a result of the fuel inside the holding portion decreasing. Here, because the plurality of ribs are provided standing upright on the bottom portion of the holding portion, a flow path for the fuel can be secured even when the holding portion is contracted, and fuel can be stably fed to the fuel pump.
As has been described above, according to the fuel tank structure of a first aspect of the disclosure, fuel consumption can be improved by a simple structure.
According to the fuel tank structure of a second aspect of the disclosure, the evaporative fuel recovery performance can be improved.
According to the fuel tank structure of a third aspect of the disclosure, a flow path can be secured for the fuel even when the holding portion is formed by a bag-shaped component that is able to expand and contract.
Preferred embodiments will be described in detail based on the following figures, wherein:
Hereinafter, a fuel tank structure according to an embodiment will be described. Note that an arrow UP that is shown in the respective drawings shows the upward side of the fuel tank. Moreover, in the embodiments, the upward side of the fuel tank coincides with the upward side in the vertical direction of the vehicle.
As is shown in
The holding portion 14 is provided inside the tank main body portion 12. The holding portion 14 is formed such that it is able to expand and contract, and is formed in a bag shape that is able to internally hold a fuel liquid (referred to below as ‘fuel GS’). Note that the term ‘able to expand and contract’ used here is not limited to structures in which the actual holding portion 14 itself expands and contracts, but includes bag-shaped components in which the volume of the holding portion 14 is variable and can be shrunk by folding the holding portion 14, and expanded by unfolding the holding portion 14. Furthermore, the holding portion 14 of the present embodiment is not a component that shrinks in parallel with the decrease of the fuel GS but is provided with enough rigidity to maintain its shape until a predetermined pressure (i.e., negative pressure) is applied to it. The shape of the holding portion 14 shown by the solid line in
A substantially cylindrical filler pipe 18 is connected to the holding portion 14. A refueling aperture 18A is formed in a top end portion of the filler pipe 18. Refueling is performed by inserting a nozzle 100A of a fueling gun 100 into the refueling aperture 18A and pouring the fuel GS into the holding portion 14 (see
The refueling aperture 18A in the top end of the filler pipe 18 is opened and closed by a fuel cap 20. A fuel lid (not shown) that is provided on a side panel or the like of the vehicle body is placed on the outside of the fuel cap 20.
The fuel cap 20 closes the refueling aperture 18A except for during refueling, and restricts access to the filler pipe 18 by the fueling gun 100. In contrast to this, as is shown in
A liquid level sensor 22 is provided inside the filler pipe 18. The liquid level sensor 22 detects the volume of fuel GS by detecting the level of the fuel GS that is being held inside the holding portion 14. In the present embodiment, the liquid level sensor 22 is formed by an electrostatic capacitance sensor. Note that it is also possible to detect the volume of fuel GS inside the holding portion 14 using another type of sensor. Furthermore, a fuel vapor recovery pipe 44 is also connected to the filler pipe 18 as a second pipe. The fuel vapor recovery pipe 44 is described below in detail.
A filter 24 that is used to capture foreign matter in the fuel GS is provided in a bottom portion of the interior of the holding portion 14. A supply pipe 26 that extends to the outside of the holding portion 14 is connected to the filter 24, and the filter 24 is joined to a fuel pump 30 via the supply pipe 26. The fuel pump 30 feeds the fuel GS to an engine which is an internal combustion engine (not shown). A feeder pipe 32 extends from the fuel pump 30 to the engine. As a consequence, when the fuel pump 30 is operated, the fuel GS inside the holding portion 14 is supplied to the fuel pump 30 through the filter 24, and is then fed to the engine by the fuel pump 30.
Here, as is shown in
Moreover, as is shown in
A fuel vapor introduction pipe 38 that serves as a first pipe is connected to a top end portion of the holding portion 14. The fuel vapor introduction pipe 38 joins the holding portion 14 to a canister 40, and is constructed such that evaporative fuel (i.e., fuel vapor) inside the holding portion 14 flows through the fuel vapor introduction pipe 38. The canister 40 communicates with the outside air via an air release pipe 41.
A float valve 39 is provided in the fuel vapor introduction pipe 38. The float valve 39 is provided in a top wall of the tank main body portion 12, and is provided with a float valve body 39A. When the fuel GS reaches the float valve 39, the float valve body 39A floats upwards and blocks off the flow path of the fuel vapor introduction pipe 38. Consequently, the fuel GS is prevented from flowing further towards the canister 40 side from the float valve 39.
Here, a fuel vapor introduction valve 42 is provided as a first shut-off valve at the fuel vapor introduction pipe 38 on the canister 40 side of the float valve 39. When the fuel vapor introduction valve 42 is opened, the fuel vapor introduction pipe 38 is also opened, and movement of the evaporative fuel inside the holding portion 14 to the canister 40 is permitted. On the other hand, when the fuel vapor introduction valve 42 is closed, the fuel vapor introduction pipe 38 is also closed, and movement of the evaporative fuel to the canister 40 is restricted. In the present embodiment, the fuel vapor introduction valve 42 is closed by the ECU 36 after oil is supplied thereto.
Moreover, in the present embodiment, the portion of the fuel vapor introduction pipe 38 that is located on the holding portion 14 side of the float valve 39 is formed by a flexible tube. Because of this, the state of connection between the holding portion 14 and the float valve 39 can be maintained even during the expansion and contraction of the holding portion 14.
The fuel vapor recovery pipe 44 is connected to the fuel vapor introduction pipe 38 adjacently to the canister 40. One end of the fuel vapor recovery pipe 44 is connected to the fuel vapor introduction pipe 38 between the canister 40 and the fuel vapor introduction valve 42. The other end of the fuel vapor recovery pipe 44 is connected to the filler pipe 18. Namely, the filler pipe 18 is joined to the canister 40 by the fuel vapor recovery pipe 44. Moreover, a fuel vapor recovery valve 46 is provided as a second shut-off valve at the fuel vapor recovery pipe 44. When the fuel vapor recovery valve 46 is opened, the fuel vapor recovery pipe 44 is also opened, and movement of the evaporative fuel from the canister 40 to the filler pipe 18 is permitted. On the other hand, when the fuel vapor recovery valve 46 is closed, the fuel vapor recovery pipe 44 is also closed, and movement of the evaporative fuel from the canister 40 to the filler pipe 18 is restricted.
A pressure sensor 48 and a temperature sensor 50 are provided in a top end portion of the holding portion 14. The pressure sensor 48 and the temperature sensor 50 are located adjacent to the connection portion where the fuel vapor introduction pipe 38 is connected to the holding portion 14, and they respectively detect a pressure and a temperature inside the holding portion 14. Here, in the present embodiment, the liquid level of the fuel GS in a full tank state is set such that when the holding portion 14 has been fully filled with the fuel GS, a distal end portion of the pressure sensor 48 and a distal end portion of the temperature sensor 50 are not submerged in the fuel GS. Moreover, the pressure sensor 48 and the temperature sensor 50 are respectively connected to the holding portion 14 by a flexible tube. Because of this, the state of connection between the holding portion 14 and the pressure sensor 48 and temperature sensor 50 can be maintained even during the expansion and contraction of the holding portion 14.
The fuel pump controller 34, the fuel vapor introduction valve 42, the fuel vapor recovery valve 46, the pressure sensor 48, and the temperature sensor 50 are electrically connected to the ECU 36. The adsorption of evaporative fuel in the canister 40 and the recovery of evaporative fuel from the canister 40 are carried out as a result of the fuel vapor introduction valve 42 and the fuel vapor recovery valve 46 being opened and closed based on signals from the ECU 36. Hereinafter, the adsorption of evaporative fuel in the canister 40 during refueling and the recovery of evaporative fuel from the canister 40 will each be described. Note that, in the following description, unless specifically stated otherwise, the fuel vapor introduction valve 42 and the fuel vapor recovery valve 46 are maintained in a closed state.
Firstly, the adsorption of evaporative fuel in the canister 40 during refueling will be described. As is shown in
Next, the recovery of evaporative fuel from the canister 40 will be described. As is shown in
If the fuel GS inside the holding portion 14 further decreases from the state shown in
When the fuel vapor recovery valve 46 is opened, negative pressure is applied to the canister 40 and atmospheric air is introduced through the canister 40 into the fuel vapor recovery pipe 44. In addition, the evaporative fuel that has been adsorbed in the canister 40 is purged. The purged evaporative fuel flows into the holding portion 14 through the fuel vapor recovery pipe 44 and the filler pipe 18. In this way, the evaporative fuel adsorbed by the canister 40 is recovered.
Here, the fuel vapor recovery valve 46 of the present embodiment is constructed such that it is possible to adjust the flow rate of the evaporative fuel flowing through the fuel vapor recovery pipe 44. Namely, by altering the opening angle of the fuel vapor recovery valve 46, it is possible to adjust the flow rate of the evaporative fuel flowing through the fuel recovery pipe 44.
Moreover, the fuel vapor recovery valve 46 is controlled by the ECU 36 such that the flow rate of the evaporative fuel flowing through the fuel vapor recovery pipe 44 (hereinafter, referred to as a ‘flow rate q’) is less than the flow rate of the fuel that is fed to the engine from the fuel pump 30 (referred to below as a ‘flow rate Q’). Specifically, the ECU 36 uses information that is received from the fuel pump controller 34 to acquire the flow rate Q of the fuel GS that is fed to the engine. The ECU 36 then adjusts the opening angle of the fuel vapor recovery valve 46 such that the flow rate q of the evaporative fuel flowing through the fuel vapor recovery tube 44 is less than the flow rate Q.
At this time, if the flow velocity of the evaporative fuel flowing through the fuel vapor recovery pipe 44 is taken as U, and the flow path area of the fuel vapor recovery pipe 44 is taken as A, then the flow rate q can be expressed using the following Formula (1):
[Formula 1]
q=U×A (1)
On the other hand, if the pressure shown by the pressure sensor 48 is taken as P1, and the atmospheric pressure is taken as P0, then P1−P0 can be expressed by the relational equation in the following Formula (2) using a pressure loss calculation formula (Fanning's equation). Note that in Formula (2), λ is the coefficient of pipe friction of the fuel vapor recovery pipe 44, l is the pipe length, d is the pipe diameter, and ρ is the density of the evaporative fuel.
By calculating U from Formula (2), and assigning it as the U in Formula (1), the flow rate q can be determined. Note that this calculation is performed by the ECU 36. The pipe diameter d is then adjusted by controlling the fuel vapor recovery valve 46 such that a determined flow rate q is less than the flow rate Q.
If the fuel GS inside the holding portion 14 decreases further from the state shown in
(Operations and Effects)
Next, the operations and effects of the fuel tank structure according, to the present embodiment will be described.
In the present embodiment, because the fuel vapor introduction valve 42 is opened based on a signal from the ECU during refueling, evaporative fuel moves from the holding portion 14 to the canister 40, and the evaporative fuel can be adsorbed in the canister 40. Moreover, gaseous components apart from the evaporative fuel are discharged into the atmosphere. As a result, it is possible to prevent evaporative fuel from being discharged into the atmosphere.
In the event that, as a result of the fuel GS inside the holding portion 14 being fed to the engine by the fuel pump 30, the pressure inside the holding portion 14 drops below a predetermined pressure that is lower than the atmospheric pressure, the fuel vapor recovery valve 46 is opened based on a signal from the ECU 36. As a result, the evaporative fuel adsorbed in the canister 40 is purged from the canister, and flows into the holding portion 14. In this manner, it is possible to recover the evaporative fuel adsorbed in the canister 40 by a simple structure without using an apparatus such as a gas separator. Moreover, because negative pressure from the intake manifold is not utilized, pumping loss is suppressed, and fuel consumption can be improved.
Furthermore, because evaporative fuel can be recovered to the holding portion 14 of the fuel tank 10 from the canister 40 even when the engine is in a stopped state, the present invention can also be applied to vehicles such as hybrid vehicles that travel using driving power from a motor when the engine is stopped.
Moreover, in the present embodiment, the fuel vapor recovery valve 46 is controlled such that the flow rate of the evaporative fuel flowing through the fuel vapor recovery pipe 44 is less than the flow rate Q of the fuel being fed to the engine from the fuel pump 30. For this reason, the negative pressure inside the holding portion 14 can be maintained when the evaporative fuel recovery is performed, and it is possible to stably recover evaporative fuel from the canister 40. Namely, the evaporative fuel recovery performance can be improved.
Furthermore, as is shown in
Embodiments of the present invention have been described above, however, it should be understood that the present invention is not limited to the above-described structure. Various modifications and the like may be made to the above-described structure insofar as they do not depart from the scope of the present invention. For example, in the present embodiment, the holding portion 14 has an expandable/contractible structure, however, the present invention is not limited to this and it is also possible to form the holding portion from a component that does not expand or contract.
Moreover, in the present embodiment, a structure is employed in which the fuel vapor introduction valve 42 is opened based on a signal from the ECU 36 at the same timing as the fuel lid is opened, however, the present invention is not limited to this. For example, it is also possible to provide a sensor that detects the open or closed state of the fuel cap 20, and to open the fuel vapor introduction valve 42 at the same timing as the fuel cap 20 is opened.
Furthermore, in the present embodiment, the fuel vapor recovery valve 46 is opened based on the pressure inside the holding portion 14 that is detected by the pressure sensor 48, however, the present invention is not limited to this. It is also possible to employ a structure in which the fuel vapor recovery valve 46 is opened based on information from both the pressure sensor 48 and the temperature sensor 50. Because the pressure inside the holding portion 14 decreases if the temperature inside the holding portion 14 falls, by detecting the pressure and temperature inside the holding portion 14 using the pressure sensor 48 and the temperature sensor 50, and controlling the fuel vapor recovery valve 46 based on information from these two sensors, the fuel vapor recovery valve 46 can be controlled even more accurately.
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