This application is based on Japanese Patent Application No. 2014-4130 filed on Jan. 14, 2014, the disclosure of which is incorporated herein by reference.
The present disclosure relates to a sensor module with a sensor assembly configured separately from a sensor cover.
An electronic throttle described in Japanese Patent No. 5212488 is known as a conventional technology. This electronic throttle includes a throttle body that accommodates a throttle valve, and a sensor module that is attached to this throttle body. The sensor module includes a throttle opening degree sensor that detects a rotation angle of the throttle valve, and a sensor cover that holds this throttle opening degree sensor. For the sensor cover, there are provided a connector for wiring connection with an electronic control unit (ECU), and a wiring unit for electrically connecting together the throttle opening degree sensor and a connection terminal in the connector.
The wiring unit includes a connecting member extending from the connector to a central part of the sensor cover in its width direction, and a wiring member extending from the central part of the sensor cover in its width direction to the vicinity of the sensor. A first connection terminal provided for the connecting member, and a second connection terminal provided for the wiring member are electrically joined to the wiring unit. As a result of the above-described configuration, when it becomes necessary to change a position of the connector due to, for example, a constraint on location for installation of the electronic throttle, the wiring unit does not need to be changed, and the same type of sensor cover with only a connector position different can be used.
However, according to the conventional technology described in Japanese Patent No. 5212488, in case of not only the change of the connector position but also a change of an attachment shape of the sensor cover, a design change particularly for small-quantity production or special shapes cannot be dealt with. Moreover, elaboration of accuracy such as an attachment position of the sensor is necessary at the time of the change of the attachment shape of the sensor cover. Accordingly, there is an issue of a significant increase in cost.
The present disclosure addresses at least one of the above issues. Thus, it is an objective of the present disclosure to provide a sensor module that can deal with a change in shape of a sensor cover at low cost and that can minimize elaboration of accuracy relevant to an attachment position of a sensor.
To achieve the objective of the present disclosure, there is provided a sensor module adapted to be attached to an actuator body incorporating an electric actuator. The sensor module includes a sensor assembly, a sensor cover, and a connector housing. The sensor assembly includes a sensor detection part and a sensor housing. The sensor detection part is configured to detect a physical change amount of a driven body driven by the electric actuator and to convert the physical change amount into an electrical signal. The sensor housing incorporates the sensor detection part. The sensor cover is provided separately from the sensor housing and is attached to the actuator body. The sensor module is configured integrally by attaching the sensor assembly to the sensor cover. A connector terminal electrically connected to a connection terminal of the sensor detection part is insert-molded in the connector housing. The connector housing is provided integrally with the sensor housing.
The above and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
Embodiments for the present disclosure will be described in detail below.
In a first embodiment, there will be described an example of application of a sensor module of the present disclosure to an electronic throttle for adjusting an intake air amount of an engine. As illustrated in
The throttle valve 2 includes a shaft 7 that is rotatably supported by the throttle body 3 via bearings 5, 6, and a circular disk-shaped valving element 8 that is fixed to this shaft 7. As a concrete example of the bearing 5, 6,
The valve driving means includes a motor (electric actuator) 10 that generates torque upon supply of electric power, and a gear train (described later) that transmits this torque of the motor 10 to the shaft 7. The motor 10 is, for example, a widely-known direct current motor, and is accommodated in a motor chamber 11 which is formed in the throttle body 3 to be controlled by an ECU (not shown) via a motor drive circuit (not shown). The ECU calculates a target throttle opening degree based on outputted information from an accelerator opening degree sensor (not shown) that detects a pressing amount of an accelerator pedal, and performs feedback control on the electric power supplied to the motor 10 such that the actual opening degree of the throttle valve 2 detected by the throttle opening degree sensor coincides with the target throttle opening degree.
The gear train is a gear deceleration means which is configured by combination of spur gears. Specifically, the gear train includes a motor gear 12 that is provided for an output shaft 10a of the motor 10, a valve gear 13 that is attached to one end part of the shaft 7, and intermediate gears 14, 15 that transmit rotation of the motor gear 12 to the valve gear 13. The intermediate gears 14, 15 include a large-diameter gear 14 in engagement with the motor gear 12, and a small-diameter gear 15 in engagement with the valve gear 13. Both the gears 14, 15 are integrally formed concentrically and supported rotatably by a common intermediate shaft 16. The throttle opening degree sensor is, for example, a position sensor of non-contact type using a Hall IC 17, and detects a rotational position of a permanent magnet 18 attached to the inner periphery of the valve gear 13 to output an electrical signal in proportion to the magnitude of a magnetic field produced by the permanent magnet 18.
The sensor module SM of the present disclosure will be described below. The sensor module SM includes a sensor cover 19 that is attached to the throttle body 3, and a sensor assembly SA that is attached to this sensor cover 19. As illustrated in
As illustrated in
The sensor assembly SA is configured by incorporation of the Hall IC 17, which is a sensor detection part of the present disclosure, into a sensor housing 26 made of resin. The sensor housing 26 includes a fitting part 26a for attachment to the sensor cover 19. This fitting part 26a has a cylindrical shape that is fitted into the attachment hole 20 of the sensor cover 19. A circumferential groove in which to attach an O-ring 27 is formed on an outer peripheral surface of the fitting part 26a. The sensor housing 26 includes a connector 28 for connection to the ECU through an external wiring (not shown). This connector 28 includes a connector housing 28b that is formed from resin integrally with the sensor housing 26, and connector terminals 29, 30 that are insert-molded in this connector housing 28b.
As illustrated in
As illustrated in
Operation and effects of the first embodiment will be described below. In the sensor module SM of the first embodiment, the sensor assembly SA is provided separately from the sensor cover 19. Accordingly, the sensor assembly SA can be made common to various sensor covers 19 having different attachment shapes. As a result, when an attachment shape of the sensor cover 19 attached to the throttle body 3 is changed, a design change of the entire sensor module SM including the sensor assembly SA is unnecessary, and only the sensor cover 19 needs to have its shape changed. Thus, when the sensor covers 19 having different attachment shapes are produced in small amounts, or when the sensor cover 19 having a special shape is produced, the sensor assembly SA can be made common. Consequently, the design of the sensor module SM can be efficiently changed. Furthermore, since the connector 28 is provided for the sensor housing 26 instead of the sensor cover 19, the case where the position of the connector 28 needs to be changed can easily be attended to. Therefore, the attachment position (circumferential position) of the sensor assembly SA to the sensor cover 19 only needs to be set in accordance with the required connector position.
In the sensor module SM described in the first embodiment, the Hall IC 17 is not attached to the sensor cover 19. Accordingly, every time when the attachment shape of the sensor cover 19 is changed, accuracy of the position of the Hall IC 17 does not need to be elaborated. As a result, an increase in cost involved in the shape change of the sensor cover 19 can be minimized. Moreover, at the time of attachment of the sensor assembly SA to the sensor cover 19, the pinching terminals 31 and the relay terminals 25 can be easily connected together only through male/female fitting. Furthermore, the two attachment flanges 32 provided for the sensor housing 26 only need to be fastened and fixed to the sensor cover 19 by the screws 33 or the like. Consequently, the sensor module SM can easily be assembled. In addition, the O-ring 27 is attached on the outer periphery of the fitting part 26a provided for the sensor housing 26, and the fitting part 26a is fitted into the attachment hole of the sensor cover 19. As a consequence, sealing properties can be ensured by the O-ring 27, and the accuracy of the position of the Hall IC 17 relative to the sensor cover 19 can be improved.
Another embodiment of the present disclosure will be described below. The same reference numeral as in the first embodiment is given to an illustration of a component or configuration in common with the first embodiment, and its detailed explanation will be omitted.
This second embodiment is an example in which a motor connector terminal 30 and a relay terminal 25 are joined together by welding or the like as illustrated in
Modifications to the above embodiment will be described below. In the first embodiment, there has been described an example of application of the sensor module SM of the present disclosure to the electronic throttle 1. However, the first embodiment is not limited to the electronic throttle 1. For example, the sensor module SM can be applied to an exhaust gas recirculation (EGR) system that recirculates a part of exhaust gas discharged from an engine to an air-intake side. In the first embodiment, there has been described an example of the sensor assembly SA being fixed to the sensor cover 19 by the screws 33. However, for example, the sensor assembly SA may be fixed by welding, adhesive joining, laser welding or the like.
To sum up, the sensor module SM in accordance with the above embodiments can be described as follows.
A sensor module SM is adapted to be attached to an actuator body 3 incorporating an electric actuator 10. The sensor module SM includes a sensor assembly SA, a sensor cover 19, and a connector housing 28b. The sensor assembly SA includes a sensor detection part 17 and a sensor housing 26. The sensor detection part 17 is configured to detect a physical change amount of a driven body 7 driven by the electric actuator 10 and to convert the physical change amount into an electrical signal. The sensor housing 26 incorporates the sensor detection part 17. The sensor cover 19 is provided separately from the sensor housing 26 and is attached to the actuator body 3. The sensor module SM is configured integrally by attaching the sensor assembly SA to the sensor cover 19. A connector terminal 29 electrically connected to a connection terminal 17a of the sensor detection part 17 is insert-molded in the connector housing 28b. The connector housing 28b is provided integrally with the sensor housing 26.
As a result of the above-described configuration, the sensor detection part 17 is incorporated in the sensor housing 26 to configure the sensor assembly SA, and this sensor assembly SA is provided separately from the sensor cover 19. Accordingly, the sensor assembly SA can be made common to various sensor covers 19 having different shapes. As a result, when an attachment shape of the sensor cover 19 attached to the actuator body (3) is changed, a design change of the entire sensor module SM including the sensor assembly SA is unnecessary, and only the sensor cover 19 needs to have its shape changed. Consequently, a design change can be carried out efficiently for small-quantity production or special shapes. Moreover, because the connector 28 is provided for the sensor housing 26 instead of the sensor cover 19, the position change of the connector 28 can easily be attended to. Specifically, the attachment position (circumferential position) of the sensor assembly SA to the sensor cover 19 only needs to accord with the position of the connector 28. In addition, in sensor module SM of the present disclosure, the sensor detection part 17 is not attached to the sensor cover 19. Consequently, every time when the attachment shape of the sensor cover 19 is changed, accuracy of the position of the sensor detection part 17 does not need to be elaborated.
While the present disclosure has been described with reference to embodiments thereof, it is to be understood that the disclosure is not limited to the embodiments and constructions. The present disclosure is intended to cover various modification and equivalent arrangements. In addition, while the various combinations and configurations, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the present disclosure.
Number | Date | Country | Kind |
---|---|---|---|
2014-4130 | Jan 2014 | JP | national |