LT6497B - Car diagnostic communication interface - Google Patents

Abstract

Car diagnostic communication interface comprising a casing from joinable parts, PCBs containing soldered electronic components, signal input and output ports. Signal output terminals include a USB connector connected to the circuit board in such a way that the USB connection housing rests against an additional support and a central support which protect against mechanical damage during irregular use of the interface, or using excess force when inserting a plug into the output jack. The housing also includes additional supports for sides of PCBs and is made of metal. PCBs are attached one to another using signal transmission connectors. A digital data storage media port is also installed inside the device in such a way that motion of the data storage media is restricted in all directions

Description

Field of the Invention

The invention relates to a communication interface between automotive electronics control units and diagnostics of automotive systems.

Description of the Related Art

The failure of car manufacturers, maintenance and repair companies (especially independent service stations) to simplify the use and performance of automotive fault detection and control units has led to the development of an automotive diagnostic device that connects to the vehicle communication interface via the standardized OBD-II connector.

On-board diagnostic communication OBD-II. on board diagnostics] as well as the OBD-I's main functions are communication (communication mediation) between the in-vehicle electronics control units and the personal computer (PC). Vehicle diagnostic communication interface allows communication with different vehicle control units, different protocols, different speeds. System failures, error codes and vehicle system parameters are detected (scanned) by the vehicle control units themselves and communicated via a diagnostic communication interface to a technical inspection operator working with the auto diagnostic equipment. Convenient display of information received from control units to a computer user.

The automotive diagnostic communication interface typically includes a housing that contains a mounting board that contains soldered electronic components along with signal input and output sockets. Because standard information transfer connections, such as USB, are connected to the motherboard as a point of reference, such connections are often a bottleneck for devices: improperly or excessively plugged into an output jack may damage the output jack connector or it. to break it altogether. Especially when the equipment is for commercial use and, accordingly, the connection of the connectors is much more frequent than when used for diagnostics of consumer electronics.

The closest analogue is described in U.S. Pat. US8480433 B2. The on-board diagnostic interface has a standardized (SAE-J1962) connector on the vehicle's OBD II connector and a USB 2.0 type B port for communication with

AK. The SAE-J1962 connector that connects to the OBD-II connector is connected to the automotive diagnostic communication interface via a multiplexer printed circuit board. The USB-B connector is soldered to the processor printed circuit board. The multiplexer and the soak processor printed circuit boards are interconnected via two connectors (AMP5179009-1 and AMP5179029-1). The main disadvantage of using a USB connection is not mechanical resistance when trying to connect the USB cable in the wrong position or at the wrong angle. Consumer electronics practice shows that a USB 2.0 Type B connector is often damaged by incorrect cable connection: the connector is broken from the printed circuit board, or the printed circuit board is damaged, or the connector itself is mechanically damaged.

The present invention is directed to overcoming the above disadvantage.

Brief Description of the Invention

An automotive diagnostic communication interface comprising a housing for interconnecting parts, which contains integrated circuit boards that contain soldered electronic components together with signal input and output sockets. The signal output connectors include a USB connector plugged into the motherboard so that the USB connector housing rests on an additional support bracket and center support that protect the interface from mechanical damage by improperly or using excess power when inserting the plug into the output jack. The housing also includes peripheral supports and additional mounting plate supports. The mounting plates are interconnected with each other by means of inter-plate connections, through which electrical signals are transmitted, and a digital data storage slot is also located inside the device, in which all directions of movement of the storage medium are limited. the body parts of the device are made of light metal.

Brief description of the drawings

Other features and advantages of the invention are described in the detailed description of the invention with reference to the following drawings:

Fig. is a view of the body of the assembled device

Figure 2a. is a view of the first mounting plate inserted into the first part of the housing

Figure 2b is a view of the second mounting plate inserted into the second part of the housing

Figure 3a is a view of the first part of the housing

Figure 3b is a view of the second part of the housing

Figure 4a one example of a power supply bracket is provided

Figure 4b another example of a power supply bracket is shown in fig. is a representation of the interconnected circuit boards with a visible digital data carrier

Before referring to the detailed description of the invention, with reference to the drawings in which the invention is exemplified, it is to be understood that identical elements are designated by the same numerals throughout the drawings.

Detailed Description of the Invention

It should be understood that many specific details are set forth to provide a full and comprehensible description of an exemplary embodiment of the invention. However, it will be apparent to one skilled in the art that the level of detail of exemplary embodiments of the invention does not limit the scope of the invention, which may be practiced without such specific guidance. The well-known techniques, procedures, and ingredients have not been described in detail to avoid the confusion of exemplifying embodiments of the invention. Furthermore, this description is not to be construed as limiting the embodiments provided.

The device (1) according to the invention is an automotive diagnostic communication interface for connecting a vehicle communication connector OBD-II to a personal computer, a smartphone and the like.

The device (1) according to the invention comprises a first body part (2 ') made of a light metal or light metal alloy, for example aluminum. The first body portion (2 ') is configured to insert a first printed circuit board (SMP') such as a microprocessor printed circuit board, to insert an input connector such as an OBD-II connector into the cavity (3 ') and an output connector such as a USB connector (4). ) for anchorage, limiting the direction of movement of the digital data carrier. The device (1) also includes a second body part (2 ') made of light metal or light metal alloy, such as aluminum. The second body portion (2 ") is configured to insert a second printed circuit board (SMP"), such as a multiplexer printed circuit board, for inserting an input connector such as an OBD-II connector into a cavity (3 ") and an output connector (4), e.g. USB connector, for support mounting.

The first body portion (2 ') of the device (1) comprises a central multifunction support (5) and peripheral supports (12') of the first printed circuit board (SMP ') on both lateral sides of the first body part (2'). The peripheral supports (12 ') are integrally formed with the side walls of the first portion (2') of the housing at the base of said walls and extend at least a portion of the length of said walls. The minimum number of peripheral supports (12 ') to ensure stable mounting of the mounting plate is four, which are arranged to restrict the movement of the edges of the first printed mounting plate (SMP') towards the base of the first housing part (2 '). The first part (2 ') of the housing (1) of the device (1) also comprises at least one inner support element (9') adjacent to the sidewall suitable for securing the two housing parts and the comparatively heavy real-time clock (RTC) battery (6). for supporting the bracket (7). The first part (2 ') of the housing (1) of the device (1) also includes a cavity (4') for guiding the externally inserted plug which is connected to the output connector (4) so that during the connection with the output connector a plane towards the exit joint coinciding with the longitudinal position of the exit joint. This ensures that the output joint will not be subjected to bending forces that occur as a result of the coupling year trying to match the plug and output joint planes.

The second body part (2 ") of the device (1) comprises peripheral supports (12") of a second printed circuit board (SMP ") on either side of the second body part (2") integrally formed with the side walls of the second body part (2). walls and extends at least part of the length of said walls. The minimum number of peripheral supports (12 ") to ensure stable mounting of the mounting board is four, which are arranged to limit the movement of the edges of the second printed mounting board (SMP") towards the base of the second housing part (2 "). At the base of the second housing part (2 "), additional supports (13) are formed at the cavity (4") for enclosing and securing the inlet connector to limit the end of the second printed circuit board (SMP ') to which the outlet connector is attached, moving toward the base of the first part (2 '). The second part (2 ") of the housing (1) of the device (1) also comprises at least one inner support element (9") adjacent to the sidewall suitable for securing two housing parts and a comparatively heavy real-time clock (RTC) battery (6). for supporting the bracket (7). The second part (2 ") of the housing (1) of the device (1) also comprises a cavity (4") for guiding the externally inserted plug which is connected to the output connector (4) so that during the connection with the output connector a plane towards the exit joint coinciding with the longitudinal position of the exit joint. This ensures that the output joint will not be subjected to bending forces that occur when the joint is made during the attempt to match the plug and outlet joint planes.

In the first part (2 ') of the housing, a first printed circuit board (SMP') is mounted using a bracket (7) having an attached RTC battery (6). The first printed circuit board (SMP ') is inserted into the first body portion (2') by resting its peripheral edges on the peripheral supports (12 ') so that the edges of said first printed circuit board rigidly rest on the first body part (2'). peripheral supports (12 ') and walls. The first printed circuit board (SMP ') is provided with a digital data carrier (L) connector (15) in which the movement of the inserted carrier is completely restricted by the carrier insert connector (15) and the side wall plane of the first body portion (2'). This ensures that the media (L) remains permanently in the media connector (15) during use of the assembled device (1).

The RTC power element (6) is substantially inserted into the RTC holding cavity of the holder (7) such that said power element (6) is restricted to movement at least parallel to the plane of the first mounting plate (SMP ') perpendicular to said plane; which prevents free movement perpendicular to said plane in the direction thereof. The holder (7) of the battery (6) further comprises a cavity (10) substantially conforming to the shape of the center support member (5) and adapted to fit the central support member (5) into the cavity (10) of the holder (7) (7) the space between the walls of the cavity (10) and the center support (5) should be as small as possible, preferably without leaving any space.

The holder (7) of the RTC battery (6), which is fixedly attached to the first mounting board (SMP '), further comprises peripheral recesses (8, 11). One of the peripheral recesses (11) is adapted to rigidly insert the rear part of the output connector (4), and the second peripheral recess (8) of the holder (7) is adapted to rest against the inner part of the first and second part (2 ', 2 "). a wall-formed side member (9 ', 9'), further restricting the movement of the holder at least parallel to the wall planes of the first portion (2 ') of the tray. The second recess (8) may be a substantially flat wall. The central support element (5) is fixedly seated in the cavity (10) of said bracket (7) such that the movement of the bracket is restricted at least parallel to the wall planes of the first portion (2 ') of the tray.

One peripheral recess (11) formed in the holder (7) of the RTC battery (6) corresponds to the shape of the rear part of the output connector socket (4) so that the rear part of the output connector socket (4) fits into said socket (11) the walls of the output connector socket (4) and the recess (11) of the bracket (7). Said additional recess (11), which corresponds to the shape of the rear part of the output connector socket (4), is formed concentrically outside the cavity (10) of the central support element (5). In this way, the central support (5), the battery holder (7) mounted on it, and the inner wall support (9 ') of the side wall form a reinforced support assembly on which the output connector socket (4) rests and acts as an additional protection against the output socket. (4) with respect to the first and second portions (2 ', 2') of the body of the reversing device (1).

The second printed circuit board (SMP ') is connected to the first printed circuit board (SMP') via connectors (14 ', 14 "), for example AMP5179009-1 and AMP5179029-1. The connectors are shaped so that one connector is like a socket and the other is a plug, and yes, it connects both mounting boards (SMP ', SMP'). It is desirable that such interconnections include two pairs, each of which is located at different ends of the device (1) for additional reinforcement of the interconnection.

The second body part (2 ') of the device (1) is mounted on the first body part (2') of the device (1) by clamping the first body parts (2 ') and the second body (2) of the device body (1). The edges of the at least one sidewall of both housing portions (2 ', 2 ") may have a stepped profile, and when the first housing portion (2') is com- pressed with the second housing portion (2"), the stepped profiles are aligned. This ensures a stronger connection of the housing parts. By connecting both housing parts (2 ', 2 "), one inner support member (9') of the first part (2 ') is joined to one inner support member (9") of the second part (2 ") as follows: , so that both form a continuous member to which the RTC battery holder (7) wraps itself.

The printed circuit boards (SMP ', SMP') inside the assembled device (1) are positioned with high precision and fixed relative to each other and to both housing parts (2 ', 2'). For this purpose, the first printed circuit board (SMP ') is fixedly mounted on the first housing part (2') and the second printed circuit board (SMP ') is fixedly mounted on the second housing body (2'). Both housing parts integrally formed with their peripheral supports (12 ', 12 ") lightly press both printed mounting plates (SMP', SMP") to the first housing (2 ') and the second housing (2 "), respectively in the other direction by interconnecting them via inter-plate connections (14 ', 14'). A second body part (2 ") presses the first mounting plate (SMP ¹ ) to the peripheral supports (12 ') of said first body part (2') through at least the second mounting plate (SMP") and the RTC battery (6).

While many features and advantages have been enumerated in the description of the invention, together with the structural details and features of the invention, the description is exemplary of the invention. Changes may be made to the details, in particular the shape, size and layout of the materials, without departing from the principles of the invention, in accordance with the most widely understood meanings of the terms used in the claims.

Claims (3)

A car diagnostic device (1) comprising a housing, an input connector and an output connector, a circuit board with electronic components attached thereto, characterized in that the automotive diagnostic device (1) comprises: - a first housing part (2 ') comprising peripheral supports (12') of the first mounting plate (SMP '), a central support element (5), an additional lateral support element (9'), a cavity guiding the plug towards the outlet connector (4) ( 4 '); - a first mounting board (SMP ') with electronic components, further comprising interconnectors (14'); - a second housing part (2 ") comprising peripheral supports (12", 13) of the second mounting plate (SMP "), a central support element (5), an additional lateral support element (9"), guiding the plug towards the outlet connector (4). a cavity (4 "); - a second mounting board (SMP "), further comprising inter-board connectors (14"), a power supply (6) carrier (7) on which the output connector (4) rests, and a digital data carrier (15). A vehicle diagnostic device (1) according to claim 1, characterized in that - peripheral supports (12 ') of the first body portion (2') formed integrally with the side walls of the first body portion (2 ') with spaces therebetween; - the central support element (5) is integrally formed with the bottom of the first housing part (2 ') and is opposite to the mounting end of the inlet connection (3); - the peripheral edges (12 ") of the second body portion (2") are formed integrally with the side walls of the second body (2 "), with spaces therebetween; - the peripheral supports of the second body part (2 ') include peripheral supports (13) extending from the first body part in the base area beneath the output connector (4); - the power supply bracket (6) is fixedly attached to the first mounting plate (SMP ') and comprises a power supply insertion cavity, a central support (5) insertion cavity (10) and peripheral recesses (8, 11). ), wherein one of the peripheral recesses (11) is adapted to rigidly insert the rear portion of the output connector (4) and the second peripheral recess (8) of the holder (7) is adapted to rest against the first and discovery portions (2 ', 2). "), The lateral connecting member (9 ', 9") of the housing parts (2', 2 ") formed by the inner wall, further restricting the movement of the holder (7) at least parallel to the wall planes of the first part (2 ') of the tray 5) rigidly engages in a cavity (10) of said holder (7) such that movement of the holder is limited at least parallel to the planes of the walls of the first portion (2 ') of the tray; - the digital data carrier (15) is mounted such that when the second mounting board (SMP) is inserted into the second housing part (2 "), movement of the digital medium is prevented in all directions; - a second housing part (2 ") presses the first mounting plate (SMP ') to the peripheral edges (12') of said first housing part (2 ') through the second mounting plate (SMP") and the power supply bracket (7). Car diagnostic device according to claim 1 or 2, characterized in that the first and second housing parts (2 ', 2') are made of metal.