Method and system for detecting malfunction of fastening bolt in CVVT

Abstract

A method for detecting malfunction of a fastening bolt in a continuous variable valve timing (CVVT) includes: deciding whether a camshaft position sensor is operating normally; learning the most retarded angle position of the camshaft using the camshaft position sensor; deciding whether the learning of the most retarded angle position of the camshaft is normal; and comparing a PWM duty value used in the learning with a set first reference value when the learning of the most retarded angle position of the camshaft is normal.

Claims

1. A system for detecting malfunction of a fastening bolt in a CVVT, the system comprising: a CVVT actuator configured to include a housing and a rotor mounted in the housing; a camshaft position sensor learning the most retarded angle position of a camshaft; and a controller configured to transmit a PWM duty value for rotation of a camshaft and a PWM duty value for operation of the CVVT actuator and store the transmitted PWM duty values, wherein, when it is determined that the learning of the most retarded angle position of the camshaft is normal, and a PWM duty value used in the learning is smaller than a set first reference value, the controller determines that malfunction has occurred in the fastening bolt in the CVVT.

2. The system of claim 1, wherein, when the learning of the response speed of the CVVT actuator is normal, and a PWM duty value used in the learning is greater than a set second reference value, the controller determines that malfunction has occurred in the fastening bolt in the CVVT.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

(2) FIGS. 1 and 2 are flowcharts illustrating a continuous variable valve timing (CVVT) bolt release detection logic in accordance with an embodiment of the present invention; and

(3) FIG. 3 is a configuration view illustrating a system for detecting malfunction of a fastening bolt in a CVVT in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION

(4) Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Reference now should be made to the elements of drawings, in which the same reference numerals are used throughout the different drawings to designate the same elements. In the following description, detailed descriptions of known elements or functions that may unnecessarily make the gist of the present invention obscure will be omitted.

(5) Hereinafter, exemplary embodiments of a system and method for detecting malfunction of a fastening bolt in a continuous variable valve timing (CVVT) in accordance with the present invention will be described with reference to the accompanying drawings.

(6) In the present invention, the malfunction of the fastening bolt in the CVVT is detected through a CVVT bolt release detection logic for respectively comparing a PWM duty value used in learning of the most retarded angle position of a camshaft and a PWM duty value used in learning of the response speed of a CVVT actuator with set duty values.

(7) That is, in the present invention, an engine control unit (ECU) detects a release phenomenon of the fastening bolt in the CVVT using the PWM duty values used in the learning of the most retarded angle position of the camshaft and the learning of the response speed of the CVVT actuator.

(8) Meanwhile, if changes in PWM duty value are observed based on various samples at the maximum operating position of the camshaft, a PWM duty value not more than 45% of the PWM duty value learned at the maximum operating position of the camshaft cannot be detected, and simultaneously, a PWM duty value not less than 38% of the PWM duty value cannot be detected based on the maximum operating speed of the CVVT.

(9) That is, when a problem caused by bolt release occurs in a vehicle having the CVVT mounted therein, the ECU can detect that there has occurred a release phenomenon of the fastening bolt when a PWM duty value out of the range of the limit value described above is transmitted, in order to set the position of the camshaft to a target value.

(10) Accordingly, if the ECU detects a PWM duty value out of the limit value of the PWM duty value as described above, the ECU decides that the fastening bolt has been released.

(11) Flowcharts of the CVVT bolt release detection logic that is the present invention in which a control logic is implemented as described above are illustrated in FIGS. 1 and 2.

(12) As shown in these figures, the CVVT bolt release detection logic includes deciding whether a camshaft position sensor is operating normally (S100), learning the most retarded angle position of a camshaft using the camshaft position sensor (S200), deciding whether the learning of the most retarded angle position of the camshaft is normal (S300), and when the learning of the most retarded angle position of the camshaft is normal, comparing a PWM duty angle used in the learning with a set first reference value (S400).

(13) First, it is decided whether the camshaft position sensor capable of detecting a rotational angle of the camshaft is operating normally. Then, if it is decided that the camshaft position sensor is operating normally, the most retarded angle position of the camshaft is learned using the camshaft position sensor.

(14) It will be apparent that the learning of the most retarded angle position of the camshaft is performed with a PWM duty value transmitted from the ECU.

(15) Meanwhile, it is determined whether the learning of the most retarded angle position of the camshaft is normal. In this case, a normal range of the most retarded angle position is stored in the ECU, and it is decided whether the most retarded angle position of the camshaft is within the range.

(16) Subsequently, when the most retarded angle position of the camshaft is within the normal range previously stored in the ECU, a PWM duty value used in learning of the most retard position of the camshaft is compared with a first reference value previously stored in the ECU.

(17) That is, when the learning of the most retarded angle position of the camshaft is normal, it is decided that the fastening bolt in the CVVT has been released when the PWM duty value used in the learning is smaller than the first reference value, for example, 45%.

(18) Meanwhile, the present invention, as shown in FIG. 2, further includes comparing a PWM duty value used in learning of the response speed of the CVVT with a set second reference value so that the release phenomenon of the fastening bolt in the CVVT is more accurately and surely decided together with the method of the PWM duty value used in the learning with the first reference value.

(19) That is, the CVVT bolt release detection logic, as shown in FIG. 2, further includes, after the comparing the PWM duty value used in the learning with the set first reference value when the learning of the most retarded angle position of the camshaft is normal, learning a response speed of the CVVT actuator (S500), deciding whether the learning of the response speed is normal as the learning response speed is within a set range (S600), and when the learning of the response speed is normal, comparing the PWM duty value used in the learning with a set second reference value (S700).

(20) First, if it is decided that the PWM duty value in the learning is smaller than the first reference value when the learning of the most retarded angle position of the camshaft is normal, the learning of the response speed of the CVVT actuator is performed.

(21) A CVVT actuator 100, as shown in FIG. 3, includes a housing 110 and a rotor 120. The housing 110 is connected to a camshaft sprocket (not shown), and the rotor 120 mounted in the housing 110 is connected to the camshaft (not shown). The response speed of the CVVT actuator 100 means a response speed when the rotational phase of the rotor 120 with respect to the housing 110 is changed.

(22) In this state, it is decided whether the learning of the response speed is normal as the learned response speed is within a set range. In this case, the set range is also stored in the ECU, so that it is decided whether the response speed is first within a normal range.

(23) When it is decided that the response speed is within the normal range, the PWM value used in the learning of the response speed is compared with the second reference value.

(24) In this state, when the PWM duty value used in the learning of the response speed is greater than the set second reference value, for example, 38%, it is decided that the release phenomenon of the fastening bolt in the CVVT has occurred.

(25) That is, it is characterized that the first reference value is 45% and the second reference value is 38%. When the PWM duty value used in the learning is smaller than the set first reference value when the learning of the most retarded angle position of the camshaft is normal, and the PWM duty value used in the learning is greater than the set second reference value when the learning of the response speed is normal, it is decided that malfunction has occurred in the fastening bolt in the CVVT.

(26) Meanwhile, FIG. 3 is a configuration view illustrating a system for detecting malfunction of a fastening bolt in a CVVT in accordance with an embodiment of the present invention.

(27) As shown in this figure, the system includes a camshaft position sensor 200, the CVVT actuator 100 including the housing 110 and the rotor 120 mounted in the housing 110, and a controller (ECU) 300 that transmits a PWM duty value for rotation of the camshaft and a PWM duty value for operation of the CVVT actuator 100, and stores the transmitted PWM values. The controller 300 decides that malfunction has occurred in the fastening bolt in the CVVT when the PWM duty value in the learning is smaller than the set first reference value when it is decided that the learning of the most retarded angle position of the camshaft is normal.

(28) Also, the controller 300 decides that the malfunction has occurred in the fastening bolt in the CVVT when the PWM duty value used in the learning is greater than the set second reference value when it is decided that the learning of the response speed of the CVVT actuator 100 is normal.

(29) According to the method and system of the present invention configured as described above, it is possible to trace the history of a vehicle with respect to the termination of starting. Further, it is possible to facilitate the establishment of service plan. Further, it is possible to more accurately and easily detect the release phenomenon of the fastening bolt.

(30) Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.