JPH1123407A - Leakage testing method for engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a leakage testing method for an engine which quickly and accurately detects the presence of a leakage of a fuel at a higher detection capacity by conducting a leakage test directly for the fuel. SOLUTION: A leakage testing method of a fuel supplying device 100 is used for an engine of an automobile which has a high pressure fuel pump 101 driven interlocking a crank shaft 2 to supply a fuel boosted by the high pressure fuel pump 101 to a combustion chamber through a fuel supplying device 100. The crank shaft 2 is rotated by a motor 3 to drive the high pressure fuel pump 101 and the driving of the high pressure fuel pump 101 is stopped when the fuel reaches a fixed pressure. A subsequent drop in the pressure of the fuel is checked by the fuel pressure sensor 114 to detect the presence/absence of the leakage of the fuel, based on the gradient thereof.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a leak test method for checking the hermeticity (airtightness or liquid tightness) of a fuel supply device for an automobile engine.

[0002]

2. Description of the Related Art In recent years, in a gasoline engine, as in the case of a diesel engine, a direct injection gasoline engine that directly injects fuel into a cylinder has been realized. In such a direct injection gasoline engine, it is possible to greatly change the fuel injection timing according to the operating state of the engine, and to reduce the harmful components in the exhaust gas while improving the performance of the engine. Become.

[0003] However, for example, when fuel is injected during the compression stroke, a high fuel injection pressure is required. In an engine equipped with a supercharging mechanism, a high fuel injection pressure is generated according to the supercharging pressure during supercharging. Required. Therefore, the fuel supply device in the direct injection gasoline engine uses a high-pressure fuel pump to convert the fuel pressurized by the low-pressure fuel pump in the fuel tank so that a sufficiently high (for example, about several tens of atmospheres) fuel injection pressure is obtained. It is configured to further pressurize and supply the fuel to a fuel injection valve (injector).

[0004] This high-pressure fuel pump uses an engine-driven pump, which naturally operates in conjunction with the operation of the engine to generate a discharge flow rate according to the rotation speed of the engine. The discharge pressure is regulated by a regulator. The pressure is adjusted to a predetermined value. Further, a check valve is provided in a fuel passage of the fuel supply device in order to prevent a backflow of the fuel delivered from the high-pressure fuel pump.

In such a fuel supply system for a direct injection gasoline engine, a high-pressure fuel pump, a delivery pipe, an injector, and other components to which high pressure is applied are connected by a fuel pipe. It is necessary to perform a leak test comprehensively and under high pressure with all parts assembled to the cylinder head body.

Therefore, conventionally, a leak test of the fuel supply device was performed by the method shown in FIG. 3 (see Japanese Patent Application No. 8-66855 filed by the present applicant). First, the operation mode of the fuel supply device 100 will be briefly described with reference to FIG. 3. During normal operation, the fuel supplied from the fuel tank at 0.33 MPa by the electric feed pump (not shown) is reduced to 5 MPa by the high-pressure fuel pump 101. Pressurized, delivery pipe 1
02. After that, the required amount
3, and the rest returns to the fuel tank via the high-pressure regulator 104. On the other hand, at the time of startup, since the rotation speed of the high-pressure fuel pump 101 directly connected to the engine is low, sufficient flow rate and pressure cannot be generated, so that the high-pressure fuel pump 101 is bypassed through the check valve 107b.
Fuel is directly supplied to the delivery pipe 102 from the electric feed pump. Therefore, the fuel pressure is also controlled to a low pressure of 0.33 MPa. At the time of starting, the fuel pressure switching solenoid valve 105 is opened, and the residual fuel downstream of the delivery pipe 102 is returned to the fuel tank. After the engine starts, when the engine speed increases and the high-pressure fuel pump 101 starts operating, the fuel pressure switching solenoid valve 105 closes, the high-pressure regulator 104 operates effectively, and the fuel pressure is controlled to 5 MPa.

[0007] In the leak test of the fuel supply device 100, an air pressure source 111 is connected to the fuel return passage 106B side (fuel return port side) via a differential pressure leak tester 110. A master 112 having the same internal volume as the fuel supply device 100 is connected to the differential pressure leak tester 110. On the other hand, a fuel feed passage 106A upstream of the high-pressure fuel pump 101 is opened to the atmosphere and a flow meter (flow tester) 1 is provided in the passage 106A.
13 is interposed.

In this state, with the fuel pressure switching solenoid valve 105 opened in the fuel supply device 100, the fuel return passage 106
The fuel supply device 10 is controlled by the air pressure source 111 from the B side.
During normal operation of the high-pressure fuel pump 101, high-pressure air pressurized to a pressure applied to the downstream side of the high-pressure fuel pump 101 is supplied, and the master 112 is also pressurized to the same pressure by the air pressure source 111 via the differential pressure leak tester 110. Supply high-pressure air.

Next, the differential pressure leak tester 110 detects a pressure difference between the air pressure supplied to the fuel supply device 100 by the air pressure source 111 and the air pressure supplied to the master 112. In this case, if the internal leak and the external leak do not occur, the fuel supply device 100 and the master 1
The pressure inside 12 is in an equilibrium state and no pressure difference occurs. Note that the external leak refers to a leak from the connection portion between the above-described parts of the fuel supply device 100 to the outside, and an internal leak refers to a leak inside the fuel supply device 100 and mainly leaks during a leak test. Here, as a case of the internal leak, for example, a leak from the check valves 107a, 107b, and 107c of the fuel supply device 100 can be considered. The pressure difference detected by the differential pressure leak tester 110 is converted into a flow rate. On the other hand, when a leak (an external leak or an internal leak) occurs, a pressure drop occurs on the fuel supply device 100 side, so that the pressure inside the fuel supply device 100 and the pressure inside the master 112 are different. There will be a pressure difference between them.

The amount of air discharged into the atmosphere through the flow meter 113 provided on the side of the fuel feed passage 106A, that is,
The flow meter 11 measures the amount of air due to internal leak (low pressure side leak).
3 to detect. Here, when the amount of air discharged into the atmosphere, that is, the internal leak is 0, it is considered that the pressure difference detected in the above-described step is caused only by the external leak.

Next, the presence or absence of a leak (high-pressure side leak) to the outside of the fuel supply device 100 is determined based on the difference between the detection results in the above-described respective detections. As a result, the difference between the amount of air obtained based on the pressure difference and the amount of air discharged into the atmosphere (internal leak) is an external leak. If the difference between the amount of air obtained based on the pressure difference and the amount of air discharged into the atmosphere (internal leak) is 0, no external leak has occurred. In the figure, reference numeral 106C denotes a fuel discharge (drain) passage.

Therefore, this leak test method has an advantage that the leak test is easy because the leak test can be performed with all parts of the fuel supply device 100 assembled. In addition, the total leak amount (internal leak and external leak) is measured by the differential pressure leak tester 110, while the leak amount (internal leak) coming out of the fuel inlet side is measured by the flow meter 113, and the difference is measured to the outside. Since the measurement is performed as a leak (external leak), there is an advantage that the external leak can be accurately detected. Further, the high-pressure fuel pump 101, which cannot apply high pressure from the upstream side due to its structure, can perform a leak test with the upstream side open to the atmosphere. Seal, etc.)
There is also an advantage that a leak test can be performed by applying a pressure equal to or higher than the fuel pressure during normal use of the fuel supply device 100 without damaging the fuel supply device.

[0013]

Incidentally, in the fuel supply device 100 as described above, recently, the structure of the high-pressure fuel pump 101 has been slightly changed to slightly improve the entire device. That is, as shown in FIG.
Since the swash plate type axial plunger pump system was changed from the swash plate type axial plunger system to the single plunger pump system, the pulsation damper 108 was interposed in the fuel feed passage 106A upstream of the high-pressure fuel pump 101 to pulsate the fuel pressure from the electric feed pump. , And a resonator 109 is interposed in the fuel feed passage 106A downstream of the high-pressure fuel pump 101 so that fuel is supplied from the high-pressure fuel pump 101 to the delivery pipe 102 at a constant pressure. Also, in order to reduce costs, the fuel pressure switching solenoid valve 105 (see FIG. 3) used conventionally has been abolished and replaced with a check port having a check valve 107d. still,
In the figure, reference numeral 114 denotes a fuel pressure sensor whose detection value is used for various control purposes.

However, the fuel supply device 10 as described above
At 0, when the leak test is performed in the same manner as in FIG. 3, the following problems occur. When the fuel pressure switching solenoid valve 105 is eliminated, a test pressure is applied to the check port. However, since this port is closed by the check valve 107d, the check valve 1 is closed.
It cannot be detected unless a differential pressure higher than the operating pressure of 07d (for example, 0.2 kg / cm ² ) is generated. For example, it is possible to detect only when there is a leak rate of 100 cc / min or more, and a target leak rate of 5 cc / min (converted to a gasoline leak rate of 5 mcc
/ min) cannot be demonstrated at all. With the addition of the resonator 109 to the high-pressure fuel feed passage 106A, it is difficult to perform a precise leak test under the influence of test oil remaining inside the resonator 109. That is, the residual test oil evaporates by being heated by high-temperature air due to compression during a leak test, and the vapor liquefies as the temperature of the air decreases, so that only data that leaks until this liquefaction is output. In other words, the data lacks authenticity. Therefore, the detection is performed after the temperature of the air decreases, but this requires a long time for the leak test.

An object of the present invention is to provide an engine leak test method applicable to such a fuel supply device and capable of quickly and accurately detecting the presence or absence of fuel leak with high detection capability. It is in.

[0016]

According to a first aspect of the present invention, there is provided an engine leak test method for testing whether a fuel supply device in an automobile engine has a leak. The fuel pump is driven by rotating the crankshaft by a predetermined driving source outside the engine, and when the fuel reaches a predetermined pressure, the driving of the fuel pump is stopped. It is characterized by detecting the presence or absence of a fuel leak. According to this, a fuel leak test can be performed quickly and accurately with high detection capability.

According to a second aspect of the present invention, there is provided a direct injection gasoline engine in which the engine directly injects fuel pressurized by a fuel pump into a combustion chamber via a fuel supply device and ignites the fuel. There is a feature. According to this, a fuel leak test in the engine having the high-pressure fuel pump can be performed quickly and accurately with a high detection capability.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an engine leak test method according to the present invention will be described in detail using embodiments with reference to the drawings.

FIG. 1 is a system configuration diagram showing one embodiment of an engine leak test method according to the present invention, and FIG. 2 is a relationship between an engine speed, fuel pressure (hereinafter referred to as fuel pressure), and fuel leak. FIG.

In FIG. 1, reference numeral 1 denotes a cylinder-injected gasoline engine which has been assembled. A fuel supply device 100 having the same structure as that shown in FIG. . Therefore,
The fuel supply device 100 includes a fuel pressure sensor 114 that detects the fuel pressure on the high pressure side, and a high pressure fuel pump 101 that is linked to a crankshaft 2 supported by a cylinder block 1b of the direct injection gasoline engine 1 via a camshaft (not shown). Equipped. An output shaft 3a of a motor (or rotating header) 3 is connected to the crankshaft 2.

The driving of the motor 3 is controlled by a controller 4.
Is input. The controller 4 outputs a drive signal to the motor 3 so that the in-cylinder injection gasoline engine 1 is motored through the crankshaft 2. When the fuel pressure on the side reaches a predetermined pressure, a stop signal is output to the motor 3 to stop the motoring.

Reference numeral 5 denotes a gradient measuring means for measuring a gradient in a fuel pressure drop, which will be described later, based on a detection signal from the fuel pressure sensor 114. Reference numeral 6 denotes a fuel supply device 100 which compares the measured value of the gradient measuring means 5 with a predetermined reference value. Is a comparing means for judging the presence or absence of a fuel leak in. Reference numeral 8 denotes a fuel tank provided with a feed pump (not shown).

With such a configuration, when conducting a leak test of the fuel supply apparatus 100, first, the in-cylinder injection gasoline engine 1 is driven by the motor 3 at a predetermined engine speed (for example, 600 rpm) by the drive signal of the controller 4. )
Motoring with.

As a result, the high-pressure fuel pump 101 linked to the engine 1 operates to increase the fuel pressure on the high-pressure side of the fuel supply device 100. For example, as shown in FIG. 2, the fuel pressure previously increased to 11.8 kg / cm ² by the feed pump of the fuel tank 8 is increased to 49.1 kg / cm ² (set pressure of the high-pressure regulator) in about 2.5 seconds.

When the fuel pressure reaches a predetermined pressure, the controller 4 which detects the fuel pressure by the fuel pressure sensor 114 outputs a stop signal to the motor 3 and outputs the stop signal to the direct injection gasoline engine 1.
Stop motoring.

After the stop, if there is a leak (including the internal leak and the external leak described in the related art) in the fuel supply device 100, the fuel pressure naturally drops. For example, as shown in FIG. 2, when there is only an internal leak, a fuel pressure change characteristic with a small gradient shown by a two-dot chain line is shown, and when there is both an internal leak and an external leak, it is shown by a solid line in the figure. It has been clarified by experiments and the like that the fuel pressure change characteristics exhibit a large gradient. It should be noted that the fuel pressure change characteristic indicated by the solid line in FIG. 2 is obtained by dummy-forming a quantitative leak situation by fuel injection by the injector, and it can be seen that the leak amount and the fuel pressure drop are clearly proportional.

In this embodiment, the fuel pressure drop is detected via the fuel pressure sensor 114, and the gradient is measured by the gradient measuring means 5. Then, the measured value of the gradient measuring means 5 is compared with a predetermined reference value (for example, a minimum value capable of distinguishing between a case where there is only an internal leak and a case where both an internal leak and an external leak exist), and The presence / absence of a fuel leak is determined by the comparing means 6.
The result of the determination is displayed on the display 7.

As described above, in this embodiment, since the leak test is performed after all the components in the fuel system are assembled, the leak test can be performed accurately and easily without leakage at inspection points. In addition, since it is a leak test using fuel, unlike the conventional method using gas, it is not affected by heat, so that a leak test can be performed quickly and with high accuracy.
It has the advantage of good correlation with leak test data from fuel pump manufacturers.

It should be noted that the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

[0030]

As described above, according to the first aspect of the present invention, there is provided a method for testing the presence or absence of leakage of a fuel supply device in an automobile engine, wherein the crankshaft is rotated by a predetermined drive source outside the engine. The fuel pump is driven, and when the fuel reaches a predetermined pressure, the driving of the fuel pump is stopped, and the presence or absence of the fuel leakage is detected based on the situation of the subsequent decrease in the fuel pressure. Leak test can be performed quickly and accurately with high detection capability.

According to the second aspect of the invention, the first aspect of the invention is applied to a direct injection gasoline engine in which fuel pressurized by a fuel pump is directly injected into a combustion chamber via a fuel supply device and ignited. A fuel leak test in the engine equipped with the high-pressure fuel pump can be performed quickly and accurately with high detection capability.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram showing an embodiment of an engine leak test method according to the present invention.

FIG. 2 is a graph showing a relationship among an engine speed, a fuel pressure, and a fuel leak.

FIG. 3 is a system configuration diagram of a conventional leak test method.

FIG. 4 is a system configuration diagram of a different conventional leak test method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 In-cylinder gasoline engine 2 Crankshaft 3 Motor 4 Controller 5 Gradient measuring means 6 Comparison means 7 Leakage / non-display 8 Fuel tank 100 Fuel supply device 101 High pressure fuel pump 114 Fuel pressure sensor

Claims (2)

[Claims] 1. A leak of the fuel supply device in an automobile engine having a fuel pump driven in conjunction with a crankshaft and supplying fuel pressurized by the fuel pump to a combustion chamber via a fuel supply device. A method for testing the presence or absence of the fuel pump, wherein the crankshaft is rotated by a predetermined driving source outside the engine to drive the fuel pump, and when the fuel reaches a predetermined pressure, the driving of the fuel pump is stopped. An engine leak test method, wherein the presence or absence of fuel leakage is detected based on the situation of a subsequent decrease in fuel pressure. 2. The engine according to claim 1, wherein the engine is a direct injection gasoline engine in which fuel pressurized by a fuel pump is directly injected into a combustion chamber via a fuel supply device and ignited. Leak test method.