JP3788264B2 - Lubrication system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an oil supply system used for a vehicle such as an automobile, and more particularly to an improvement for integrating a plurality of lines.
[0002]
[Prior art]
In general, in a vehicle such as an automobile, an oil supply system as shown in FIG. 3 is known.
[0003]
In such a case, the filler tube 2 that guides the fuel into the tank body 1a of the fuel tank 1 is provided with the tip opening 2a facing the fuel supply port.
[0004]
A filler cap 3 is provided at the tip opening 2a of the filler tube 2 so as to open and close the tip opening 2a.
[0005]
A vent valve 4 is provided on the upper wall 1b of the tank body 1a. The vent valve 4 is connected to a canister 7 through an inflow side tube 6 a of the vent line 6, a refuel control valve 5, and an outflow side tube 6 b of the vent line 6.
[0006]
Among these, the refuel control valve 5 is defined by the diaphragm 5a in the first chamber 5b and the second chamber 5c, and the inflow side tube 6a and the outflow side tube 6b of the vent line 6 face the second chamber 5c. The inflow side tube 6a and the outflow side tube 6b are configured to be communicated or blocked by opening and closing the diaphragm 5a.
[0007]
Further, an evaporation cut valve 8 is provided on the upper wall portion 1b of the tank body 1a. The evaporation cut valve 8 is connected to the canister 7 via an engine vacuum cut valve 9 and a fuel vapor line 10.
[0008]
The refuel control valve 5 is connected to the vicinity of the tip 2 a of the filler tube 2 via a signal line 11.
[0009]
And the upper wall part 1b of the said tank main body 1a and the front-end | tip 2a vicinity of the filler tube 2 are connected via the recirculation line 12. FIG.
[0010]
Next, the operation of this conventional oil supply system will be described.
[0011]
In this conventional oil supply system, when the filler cap 3a is tightened during traveling, the pressure in the filler tube 3 is also the same as the pressure in the tank body 1a. Thereby, since the pressure in the 1st chamber 5b of the refuel control valve 5 and the inflow side tube 6a of the vent line 6 become the same pressure, the refuel control valve 5 maintains a closed state.
[0012]
When the fuel control valve 5 is closed and the pressure in the tank body 1a increases and reaches a certain set value, the engine vacuum cut valve 9 opens and the fuel vapor passes through the fuel vapor line 10 to the canister 7. Discharged.
[0013]
In the canister 7, after the fuel component is adsorbed, the purified gas is released to the atmosphere.
[0014]
Then, when refueling, the filler cap 3 of the filler tube 2 is removed, a refueling nozzle is inserted from the opening of the tip 2a, and fuel flows down from the filler tube 2 into the fuel tank 1. The
[0015]
Part of the fuel in the fuel tank 1 becomes fuel vapor and is sent from the vent line 6 to the canister 7 through the refuel control valve 5.
[0016]
That is, the signal in the tank body 1a is connected to the tip 2a of the filler tube 2 which becomes higher than the atmospheric pressure due to the evaporative gas pressure and the inflow pressure of the fuel, but becomes a negative pressure due to the entrainment of the atmosphere when the fuel flows in. Since the line 11 is connected to the first chamber 5b of the refuel control valve 5, the first chamber 5b of the refuel control valve 5 has a negative pressure when fuel flows in.
[0017]
Thereby, the diaphragm 5a is opened, the fuel vapor is guided to the canister 7 through the vent line 6, and after the fuel is adsorbed, the air is released to the atmosphere.
[0018]
In this way, the gas is removed from the tank body 1a, so that the fuel can be supplied smoothly.
[0019]
This fuel vapor is also circulated in the recirculation line 12 via the signal line 11.
[0020]
Then, the liquid level 13a of the fuel in the fuel tank 1 rises and reaches the lower end 4a of the vent valve 4, the float in the vent valve 4 rises and closes the lower end of the inflow side tube 6a. Vent valve 4 is closed.
[0021]
For this reason, the pressure in the fuel tank 1 rises, the liquid level 13a of the fuel 13 rises the filler tube 2, and the auto-stop mechanism provided in the fueling nozzle is operated to stop the fueling. ing.
[0022]
Other types of oil supply systems include those described in U.S. Pat. No. 4,714,172, and the recirculation line 12 for the purpose of reducing air entrainment from outside the tank body during oil supply. There is known an oil supply system or the like for setting.
[0023]
[Problems to be solved by the invention]
However, in such a conventional fueling system, two signal lines 11 are provided from the upper wall portion 1b in the fuel tank 1 through the recirculation line 12, the vent valve 4 and the refuel control valve 5, Since it protrudes and is extended to the front-end | tip opening 2a vicinity of the filler tube 2, there existed a problem that manufacturing cost was high and the freedom degree of layout was low.
[0024]
In addition, after the liquid level 13a of the fuel 13 reaches the lower end 4a of the vent valve 4 and automatically stops, the return pressure of the vent valve 4 (the valve opens again when the liquid level drops after the valve is closed). There was also a problem that the necessary pressure was increased.
[0025]
In order to solve this problem, a configuration using a vent valve 4 having a two-stage float structure is also known. However, since the structure becomes complicated, there is a risk that the cost may increase.
[0026]
Therefore, the object of the present invention is to solve the above-mentioned problems, integrate the two lines and reduce the number of parts, simplify the layout, suppress the increase in manufacturing cost, and provide additional lubrication. An object of the present invention is to provide an oil supply system that can be easily performed.
[0027]
[Means for Solving the Problems]
In order to solve the above-described problem, in the invention described in claim 1, the fuel tank includes a tank body and a filler tube connected to the tank body for refueling the tank body, A refuel control valve that is connected to the canister via a vent line and that is provided in the middle of the vent line includes a first chamber and a first chamber defined by a diaphragm provided in a case of the refuel control valve. An oil supply system that is opened and closed by a differential pressure between two chambers,
The tank body is connected to the first chamber through an inflow side tube of the vent line, and an outflow side tube of the vent line is connected to the canister, and the bottom chamber of the second chamber A vertical tube inserted into the tank body is provided, and a vertical tube derived from a branch point at a predetermined height in the tank body of the vertical tube has a horizontal tube connected to the filler tube, and the vertical tube is An integration that combines the function as a signal line and the function of a recirculation line that reduces air entrainment from outside the tank body during refueling by forming an inlet opening at a predetermined height in the tank body line is provided, wherein the second chamber of the refueling control valve, an inlet opening located below the inlet opening of the integrated line In addition to connecting a supercharging prevention tube, the integrated line has an orifice that allows additional oiling by generating pressure loss and increasing the pressure in the tank body to gradually vent the air. It features a refueling system that is formed .
[0028]
According to the first aspect of the present invention, when the fuel is supplied, the filler tube is opened to atmospheric pressure, and when fuel is poured into the filler tube, the fuel that has flowed down into the tank body Is circulated into the filler tube from the inlet opening of the integrated line through a part of the vertical tube and the horizontal tube of the integrated line .
[0029]
For this reason, entrainment of air during refueling is prevented, and new generation of fuel vapor is suppressed.
[0030]
When refueling proceeds and the fuel level reaches the inlet opening of the integrated line, the level rises in a portion of the vertical tube of the integrated line. At this time, the pressure in the first chamber of the fuel control valve provided in the middle of the vent line is higher than the pressure in the second chamber, and the diaphragm moves due to the differential pressure, so that the fuel control valve When opened, the fuel vapor in the tank body is discharged in the direction of the canister.
[0031]
When refueling further proceeds, the liquid level in the integrated line reaches the branch point position, the fuel vapor loses escape, and the pressure difference between the pressure in the first chamber of the refuel control valve and the pressure in the second chamber. The diaphragm is closed by the diaphragm, and the pressure in the tank body rises.
[0032]
For this reason, the fuel level rises in the filler tube and is automatically stopped.
Further, since the inlet opening of the supercharging prevention tube is positioned below the inlet opening of the integrated line, when the fuel level reaches the inlet opening of the supercharging prevention tube, The pressure in the tank body rises due to the pressure loss of the orifice provided in the integrated line, and the fuel liquid level rises in the filler tube, so that an automatic stop can be applied.
After the initial auto-stop, when additional fuel is supplied at a low flow rate, the fuel vapor can be supplied through the integrated line through the inlet opening of the integrated line through the integrated line toward the filler tube.
When the fuel level rises again in the tank body due to the additional refueling and reaches the inlet opening of the integrated line, the fuel vapor cannot escape in the direction of the filler tube, and the pressure in the tank body rises. .
For this reason, the fuel level rises in the filler tube, auto-stop is applied, and refueling ends.
[0033]
According to a second aspect of the present invention, the oil supply system according to the first aspect is characterized in that a roll-over valve is provided at a tank body side connection portion of the inflow side tube of the vent line.
[0034]
According to the second aspect of the present invention configured as above, liquid leakage is prevented at the time of vehicle rollover by the rollover valve provided at the tank body side connection portion of the inflow side tube of the vent line.
[0035]
Since the inflow side tube of the vent line does not need to have a function of detecting the liquid level, the rollover valve having a simple structure can be used, and an increase in manufacturing cost can be suppressed.
[0041]
Furthermore, those claims are described in section 3, the second chamber has a fuel supply system of claim 1 or 2 wherein wherein than the first chamber is constructed so as to positioned below the features.
[0042]
According to the third aspect of the present invention configured as described above, since the second chamber is configured to be positioned below the first chamber, fuel is supplied from an integrated line connected to the second chamber. Even if the liquid flows in, the liquid pool does not occur, and there is no fear that the path of the integrated line is blocked by the liquid pool.
[0043]
For this reason, it can always be used as an integrated line in which the function as a circulation line and the function as a signal line are integrated.
[0044]
DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1
Hereinafter, a specific first exemplary embodiment of the present invention will be described together with illustrated examples. In addition, the same code | symbol is attached | subjected and demonstrated about the part thru | or equivalent to the said prior art example.
[0045]
FIG. 1 shows an oil supply system according to Embodiment 1 of the present invention. In addition, the same code | symbol is attached | subjected and demonstrated about the part thru | or equivalent to the said prior art example.
[0046]
First, the structure will be described. In the fuel supply system of the first embodiment, the fuel tank 16 provided in the vehicle body of the automobile is provided with a filler tube 2 that is used for fuel supply and guides the fuel into the fuel tank 16. It has been.
[0047]
A filler cap 3 is provided at the tip opening 2a of the filler tube 2 so as to open and close the tip opening 2a.
[0048]
A rollover valve 17 is provided on the upper wall portion 16a of the fuel tank 16 so as to guide the fuel vapor in the fuel tank 16 to the canister 7 through a vent line 6.
[0049]
A refuel control valve 18 is provided in the middle of the vent line 6.
[0050]
The refuel control valve 18 is mainly located in a diaphragm 18a extending substantially horizontally in the case 18a, a first chamber 18b defined by the diaphragm 18a, and a lower side than the first chamber 18b. And a second chamber 18c.
[0051]
Among these, the inflow side tube 6a of the vent line 6 is connected to the first chamber 18b.
[0052]
The tank body side connection portion 6d of the inflow tube 6a is connected to the tank body 16a via the rollover valve 17 located in the tank body 16a.
[0053]
The tip opening 6c of the outflow side tube 6b of the vent line 6 is in contact with the upper surface side of the diaphragm 18a in the first chamber 18b.
[0054]
The tip opening 6c is opened and closed by the movement of the diaphragm 18 in the in-plane direction, and is closed when the pressure in the first chamber 18b is equal to the pressure in the two chambers 18c. When the pressure in the first chamber 18b becomes larger than the pressure in the two chambers 18c, the pressure is released away from the upper surface side of the diaphragm 18a, and the fuel vapor in the tank main body 16a is released to the canister 7 direction. It is configured to discharge.
[0055]
The second chamber 18c is provided with an integrated line 19 that serves both as a signal line and as a recirculation line that reduces air entrainment from outside the tank body 16a during refueling. .
[0056]
The integrated line 19 is substantially from a vertical tube 20 inserted into the tank body 16a from the bottom surface portion 18d of the second chamber 18c and a branch point 20b of the vertical tube 20 at a predetermined height position h1 in the tank body 16a. A horizontal tube 21 led out in the horizontal direction and connected to the vicinity of the tip opening 2a of the filler tube 2 is mainly constituted.
[0057]
The lower end of the vertical tube 20 of the integrated line is configured to communicate with the tank body 16a through an inlet opening 20a provided at a predetermined height h2 in the tank body 16a.
[0058]
Next, the operation of the first embodiment will be described.
[0059]
In the first embodiment, at the time of refueling, the filler cap 3 provided at the tip opening 2a of the filler tube 2 is removed, the inside of the filler tube 2 is opened to atmospheric pressure, and the filler tube 2 is illustrated in the figure. An abbreviated refueling nozzle is inserted and fuel is poured.
[0060]
Fuel vapor generated by the fuel flowing down into the tank main body 16a enters the filler tube 2 from the inlet opening 20a of the integrated line 19 through a part of the vertical tube 20 and the horizontal tube 21 of the integrated line 19. Circulated.
[0061]
For this reason, entrainment of air during refueling is prevented, and new generation of fuel vapor is suppressed.
[0062]
When refueling proceeds and the fuel liquid level 13a reaches the inlet opening 20a of the integrated line 19, the fuel liquid level 13a rises part of the vertical tube 20 of the integrated line 19.
[0063]
At this time, the pressure in the first chamber 18b of the refuel control valve 18 provided in the middle of the vent line 6 is higher than the pressure in the second chamber 18c, and the diaphragm 6c is moved by the differential pressure. The front end opening 6c of the outflow side tube 6a provided inside the refuel control valve 16 is opened away from the diaphragm 6c, and the fuel vapor in the tank body 16a passes through the outflow side tube 6a. And discharged in the direction of the canister 7.
[0064]
Further, as the refueling progresses, the liquid level 16a in the integrated line 19 reaches the branch point 20b as shown by f1 in FIG. The pressure difference between the pressure in the chamber 18b and the pressure in the second chamber disappears, the diaphragm 6c closes the tip opening 6c of the refuel control valve 18, and the pressure in the tank body 16a increases.
[0065]
For this reason, the fuel level 13a rises in the filler tube 2 to cause the auto-stop mechanism of the refueling nozzle to function and auto-stop is applied.
[0066]
The tank body side connecting portion 6d of the inflow side tube 6a of the vent line 6 is provided with a rollover valve 17 to prevent liquid leakage during vehicle rollover.
[0067]
Since the inflow side tube 6d of the vent line 6 does not need to have a function of detecting the liquid level, the rollover valve 17 having a simple structure can be used, and an increase in manufacturing cost can be suppressed.
[0068]
Furthermore, in the fuel control valve 18 according to the first embodiment, the second chamber 18c is configured to be positioned below the first chamber 18b, so that the second chamber 18c is connected to the second chamber 18c. Even if fuel flows in from the integrated line 19, no liquid pool is generated, and there is no possibility that the path of the integrated line 19 is blocked by the liquid pool.
[0069]
For this reason, the integrated line 19 can always be used while exhibiting a function as a circulation line and a function as a signal line.
[0070]
Embodiment 2
FIG. 2 shows an oil supply system according to Embodiment 2 of the present invention. Note that portions that are the same as or equivalent to those in the first embodiment will be described with the same reference numerals.
[0071]
In the fuel supply system of the second embodiment, in addition to the configuration of the first embodiment, a supercharging oil prevention tube is further provided on the bottom surface portion 118d of the second chamber 118c located below the refuel control valve 118. 22 is connected.
[0072]
The supercharging oil prevention tube 22 is inserted into the tank body 16a from the upper wall portion 16b, and the height position h3 below the branch point 20b or the inlet opening 20a of the vertical tube 20 of the integrated line. An inlet opening 22a is provided.
[0073]
Further, in the vertical tube 20 of the integrated line 19, a pressure loss is generated above the inlet opening 20a and below the height position h1 to which the horizontal tube 21 is connected to generate a tank. An orifice 23 that allows additional oil supply is formed by increasing the pressure in the main body 16a and gradually releasing air.
[0074]
Next, the operation of the second embodiment will be described.
[0075]
In the second embodiment, when a fuel nozzle (not shown) is inserted into the filler tube 2 and fuel is poured, the fuel vapor generated by the fuel flowing down into the tank body 16a is transferred to the integrated line 19. The inlet tube 20 enters the horizontal tube 21 through a part of the vertical tube 20 of the integrated line 19 and enters the second chamber 118 c through the inlet port 22 a and enters a part of the vertical tube 20. , Enters the transverse tube 21 and is circulated in the filler tube 2.
[0076]
For this reason, entrainment of air during refueling is prevented, and new generation of fuel vapor is suppressed.
[0077]
When the refueling proceeds and the fuel liquid level 13a reaches the height h3 and reaches the inlet opening 22a of the supercharging prevention tube 22, the fuel liquid level 13a starts to rise inside the supercharging prevention tube 22. The fuel vapor in the tank body 16 a passes through the vertical tube 20 in which the orifice 23 is formed and is circulated from the horizontal tube 21 into the filler tube 2.
[0078]
At this time, the inlet opening 22a of the supercharging prevention tube 22 is located below the inlet opening 20a of the integrated line 19, so that the fuel level 13a is the inlet opening of the supercharging prevention tube 22. When reaching the portion 22a, the pressure in the tank body 16a rises due to the pressure loss of the orifice 23 provided in the integrated line 19, and the fuel liquid level 13a rises in the filler tube 2 so that auto-stop is performed. It can be used.
[0079]
After the initial auto-stop, when additional fuel is supplied at a low flow rate, the fuel vapor flows from the inlet opening 20a of the integrated line 19 and passes through the integrated line 19 in the direction of the filler tube 2 through the orifice 23 to supply the fuel. Is possible.
[0080]
When the fuel level 13a rises again in the tank body 16a due to the additional refueling and reaches the inlet opening 20a of the integrated line 19, the fuel vapor cannot escape in the direction of the filler tube 2 and the tank body 16a. The pressure inside rises.
[0081]
For this reason, the fuel liquid level 13a rises in the filler tube 2, an automatic stop is applied, and refueling ends.
[Brief description of the drawings]
FIG. 1 is a schematic diagram illustrating an entire configuration of an oil supply system according to a first embodiment of the present invention.
FIG. 2 is a schematic diagram illustrating an entire configuration of an oil supply system according to a second embodiment.
FIG. 3 is a schematic diagram showing an overall configuration of an oil supply system of a conventional example.
[Explanation of symbols]
6 Vent line 6a Inflow side tube 6b Outflow side tube 6d Tank body side connection 7 Canister 16 Fuel tank 16a Tank body 18, 118 Refuel control valves 18a, 118a Diaphragms 18b, 118b First chamber 18c, 118c Second chamber 18d, 118d Bottom face portions 18e, 118e Case 19 Integrated line 20 Vertical tube 20a Inlet opening 20b Branch point 21 Horizontal tube 22 Supercharging prevention tube 22a Inlet opening 23 Orifice

Claims (3)

A fuel tank has a tank body and a filler tube connected to the tank body for refueling. The tank body is connected to the canister via a vent line, and in the middle of the vent line. The refueling control valve provided is a fueling system that is opened and closed by a differential pressure between the first chamber and the second chamber defined by a diaphragm provided in the case of the refueling control valve,
The tank body is connected to the first chamber via an inflow side tube of the vent line, and an outflow side tube of the vent line is connected to the canister, and the bottom chamber of the second chamber A vertical tube inserted into the tank body is provided, and a vertical tube derived from a branch point at a predetermined height in the tank body of the vertical tube has a horizontal tube connected to the filler tube, and the vertical tube is An integration that combines the function as a signal line and the function of a recirculation line that reduces air entrainment from outside the tank body during refueling by forming an inlet opening at a predetermined height inside the tank body line is provided, wherein the second chamber of the refueling control valve, an inlet opening located below the inlet opening of the integrated line In addition to connecting a supercharging oil prevention tube, the integrated line has an orifice that allows additional oiling by generating pressure loss and increasing the pressure in the tank body to gradually vent the air. An oil supply system characterized by being formed .   The oil supply system according to claim 1, wherein a roll-over valve is provided at a tank body side connection portion of the inflow side tube of the vent line. The oil supply system according to claim 1, wherein the second chamber is configured to be positioned below the first chamber .

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