AT525512B1 - Diagnostic device - Google Patents

Abstract

The invention relates to a diagnostic device (100) with a diagnostic device (1) for connection to a diagnostic interface of a vehicle, wherein the diagnostic device (1) has a plug part (3), which forms a diagnostic plug (4), and a housing part (2), wherein preferably the plug part (3) is detachably arranged and/or can be arranged on the housing part (2) and at least one contact pin (5) of the diagnostic plug (13) is arranged in the plug part (3), wherein the diagnostic device (100) is one of the diagnostic device ( 1) has a separate energy supply module (6) with one or more energy storage units (7), the energy supply module (6) being detachably connected and/or connectable to the diagnostic device (1). According to the invention, the energy supply module (6) can be connected to the diagnostic device (1) between the housing part (2) and the plug part (3) via a plug contact section (6b).

Description

Description

DIAGNOSIS DEVICE

The invention relates to a diagnostic device with a diagnostic device for connection to a diagnostic interface of a vehicle, wherein the diagnostic device has a plug part which forms a diagnostic plug and a housing part, wherein preferably the plug part is detachably arranged and/or can be arranged on the housing part and in At least one contact pin of the diagnostic plug is arranged on the plug part, wherein the diagnostic device has a power supply module that is separate from the diagnostic device and has one or more energy storage units, wherein the power supply module is detachably connected and/or connectable to the diagnostic device.

In today's motor vehicles, diagnostic interfaces (on-board diagnostics or OBD OBD interfaces) are installed as standard. Such a diagnostic interface is designed, for example, according to the ISO 15031-3 (2016) standard, which defines both a plug and an associated socket with sixteen contact pins. A diagnostic device can be connected to a diagnostic interface in the vehicle, in particular to read diagnostic data from the vehicle or to generally enable data communication with the vehicle - also in both directions. Diagnostic devices are already known for this purpose, which are connected to the diagnostic interface in the vehicle using a diagnostic cable and diagnostic connector. However, this requires handling a cable, and the diagnostic device itself must be placed somewhere safe on or in the vehicle during use, which is particularly difficult when the vehicle is in motion.

Diagnostic devices are also known that are plugged directly into the diagnostic interface in the vehicle without using a cable. For this purpose, such diagnostic devices have a male plug part that is plugged into the female plug part of the diagnostic interface in the vehicle. In the context of the present disclosure, a male plug part is understood to mean a protruding element, while a female plug part is understood to be a recess or receptacle, the protruding element and the recess or receptacle being designed to correspond to one another. The male plug part is arranged at one end of the diagnostic device and an electronic circuit for evaluation and, if necessary, external communication is arranged in the housing of the diagnostic device. The housing therefore requires a certain size and cannot be made as small as desired. The OBD pins of the male connector part must of course also be connected to the electronic circuit. For example, EP 3 117 491 B1 and CN 206908038 U show such a diagnostic device.

Typically, such diagnostic devices are supplied with energy via the vehicle to be examined. However, this can lead to problems if the power supply is interrupted when the vehicle ECU is restarted due to the diagnosis.

[0005] For this reason, there are already diagnostic devices in the prior art that have an independent power supply. For example, EP 2 601 502 B1 shows a diagnostic tool in which a capacitor is installed, which is supplied with energy via the vehicle. This makes it possible to bridge short-term supply fluctuations lasting less than a second, for example if the diagnostic tool is connected to an unreliable energy source. The disadvantage is that the capacitor is permanently installed in the device - complex measures are necessary in the event of defects or replacement due to wear and tear.

EP 2 316 086 B1 describes a portable diagnostic tool system in which a diagnostic tool and a vehicle communication interface are equipped for wireless communication in real time. For this purpose, according to paragraph [0019], the diagnostic tool is equipped with a battery, not described in more detail, which can be connected to an alternating current source using a power supply connection in the diagnostic tool.

Here too, the energy supply is permanently installed, so it cannot be changed as required or adapted to the respective intended use. This is a major disadvantage with diagnostic tools because, when used as intended, hundreds of diagnostic processes can occur every day, which puts a high strain on conventional batteries.

Comparable diagnostic devices with energy supply are also shown, for example, in US 2009/063745 A1, CN 106004794 A, JP 2018016138 A, WO 2008/045277 A2, CN 101936815 A, EP 2 189 921 A2 and EP 2 601 502 B1.

It is therefore an object of the invention to provide a diagnostic device that has its own energy supply in order to bridge longer-lasting supply gaps and can be adapted to different purposes.

This object is achieved according to the invention with a diagnostic device mentioned at the outset in that the energy supply module between the housing part and the plug part can be connected to the diagnostic device via a plug contact section.

In this way, the power supply module can be installed and uninstalled easily and reproducibly.

[0012] This can ensure that if the energy supply is interrupted by the vehicle being examined, a consistent and error-free diagnosis is still possible. The energy supply module can be designed so that supply gaps of 30 seconds, 60 seconds or longer can be bridged. Due to the detachability, the diagnostic device can be used with a separate power supply or supplied via the vehicle, depending on the application. It is also possible to quickly replace a used, discharged power supply module with a fresh, full module. Because the diagnostic device does not fail if the supply is interrupted - for example by restarting the vehicle control unit - and therefore there are no waiting times, diagnostic processes can be carried out more quickly and without errors.

[0013] Within the scope of the present disclosure, a diagnostic device therefore has a diagnostic device and a separate energy supply module.

Various known solutions can be used as energy storage units, for example batteries or accumulators. In a variant of the invention, at least one energy storage unit of the energy supply module is designed as a capacitor, preferably as a supercapacitor. Capacitors are an established energy storage solution that can provide sufficient energy for normal diagnostic processes. It is possible to operate the diagnostic device for 30 to 60 seconds or longer without any problems. Since capacitors, unlike batteries, contain only small amounts of chemical substances, the risk of fire can be greatly reduced. Supercapacitors differ from conventional capacitors in that they have a higher energy and power density. They also have the advantage that they allow a service life of several 10,000 charging and discharging cycles - up to over 500,000 such cycles are possible.

In the context of the present disclosure, supercapacitors are considered to be capacitors that have a capacity of 25 F or more. Double-layer capacitors with a capacity of 25 F or more are preferably used as supercapacitors. The high energy density and compact size enable long supply gaps to be bridged. Advantageously, the voltage requirement of the supercapacitor(s) used is selected so that the sum of the components corresponds to the vehicle voltage - this means that no complex voltage regulation is required in the diagnostic device, which enables energy-saving operation.

In order to enable a further range of uses, the energy supply module has at least one connection device for connecting to an external energy supply source.

[0017] In this way, an external supply can be connected to the energy supply

to charge the storage unit and/or to operate the diagnostic device directly and/or to supply a vehicle to be examined via the plug part and diagnostic plug, for example if it does not have its own battery, is discharged or the vehicle as such is parked or deactivated.

In one variant, the plug part is designed in one piece with the plug contact section and adjoins the plug contact section in a direction away from the housing part, and the energy supply module can be connected to the housing part via a first connection region of the plug contact section.

In other words, the power supply module has the plug part and the diagnostic plug integrated into the plug contact section. The diagnostic device therefore consists of as few parts as possible, and at the same time it can be easily adapted to different vehicles by retaining the housing part but replacing the power supply module with the plug part.

In a further variant, the power supply module can be connected to the housing part via a first connection area of the plug contact section and the plug contact section is detachably connected and/or connectable to the plug part via a second connection area.

[0021] This allows the maximum possible modularity to be achieved.

In order to make the system particularly compact and space-saving, the energy supply module has an energy storage part for accommodating the energy storage units, with the energy storage part extending in a direction away from the plug part along a longitudinal axis of the diagnostic device in the assembled state of the energy supply module. Preferably, the energy storage part extends along a longitudinal axis of the diagnostic device and a longitudinal axis of the housing part, with these two longitudinal axes usually coinciding.

[0023] Advantageously, the energy supply module lies against the housing part in a mounted state. In other words, a wall section of the power supply module facing the housing part rests on the housing part, or this wall section and the housing part touch each other.

In a variant of the invention, a width and a length of the energy storage part are smaller or the same size as a width and a length of the housing part of the diagnostic device.

In this way, the diagnostic device can be made compact and space-saving by keeping the external dimensions as small as possible. The presence of the energy supply module also makes it possible to reach diagnostic interfaces arranged at an angle.

In order to enable easy handling, the power supply module has at least one holding device for detachably connecting to the diagnostic device, the holding device preferably connecting the power supply module to the diagnostic device in the area of the housing part. This holding device can be designed as a clamping element, fixing loop or snap connection, so that a secure hold of the power supply module on the diagnostic device is guaranteed even when handling the diagnostic device in a multidimensional manner.

The invention is explained in more detail below using a non-limiting exemplary embodiment, which is shown in the figures. In it shows

1 shows a perspective overall view of a diagnostic device according to the invention;

2 is a perspective view of a power supply module according to the invention;

3 shows an exploded view of a diagnostic device according to the invention; 4 shows a front view of a diagnostic device according to the invention;

5 shows a partial sectional view of the plug part and plug contact section of a diagnostic device according to the invention in a section along line AA in FIG. 4;

6 is a bottom view of a diagnostic device according to the invention; 7 shows a side view of a diagnostic device according to the invention;

8 shows a sectional view of a diagnostic device according to the invention in a section along line BB in FIG. 6;

9 shows a partially transparent top view of a power supply module according to the invention; and

10 shows a partially transparent side view of a power supply module according to the invention.

For reasons of clarity, similar elements are marked with the same reference numerals in the following figures.

1 shows a diagnostic device 100 according to the invention. The diagnostic device 100 consists of a diagnostic device 1 with a housing part 2 and a plug part 3. The plug part 3 forms a diagnostic plug part 4, which can be connected to a diagnostic interface of a vehicle. For this purpose, the plug part 3 has at least one contact pin 5, with only two contact pins being provided with reference numbers in FIG. 1 for reasons of clarity.

Furthermore, the diagnostic device 100 has an energy supply module 6, which is shown in FIG. 1 below the diagnostic device 1 and has one or more energy storage units 7 (see FIGS. 3, 8 and 10). The energy supply module 6 is designed separately from the diagnostic device 1 and is detachably connected or connectable to it.

A diagnostic device 100 in the sense of the present disclosure therefore comprises a diagnostic device 1 and a power supply module 6 that is separate from the diagnostic device 1 and is detachably connected or connectable to the diagnostic device 1.

2 shows the energy supply module 6 alone in a perspective view. It can be seen that the energy supply module 6 has an energy storage part 6a for accommodating the energy storage units 7 and a plug contact section 6b, via which the detachable connection to the diagnostic device can be established.

The diagnostic device 100 is shown in an exploded view in FIG. 3: The housing part 2 of the diagnostic device 1 consists of a first housing part 2a and a second housing part 2b, which are screwed together using screws 99.

[0044] The energy supply module 6 is also multi-part: The energy storage part 6a consists of a first energy storage part half-shell 6a' and a second energy storage part half-shell 6a', the second energy storage part half-shell 6a' being designed in one piece with the plug contact section 6b.

It can also be seen that the energy storage units 7 are located in the energy supply module 6, in particular in the energy storage part 6a. In principle, the energy storage units can be designed in various ways, for example with batteries, accumulators, capacitors or other storage solutions. In the exemplary embodiment shown, however, supercapacitors are used, with four of them being provided. Supercapacitors have the advantage that they can provide the energy required to operate the diagnostic device 100 over a period of 30 to 60 seconds or longer and also only have a reduced risk of fire or explosion - when handling in the vicinity of vehicles with internal combustion engines clear advantage.

[0046] Below, the supercapacitors are denoted by the reference numeral 7, which has been generally introduced for the energy storage units.

The supercapacitors 7 are arranged on a circuit board 8, on which a control unit 9 is also located, in order to ensure an orderly energy supply to the diagnostic device 1. The connection between the supercapacitors 7 and the plug contact section 6b and further to the housing part 2 and the plug part 3 takes place in a conventional manner and is not described in more detail here, as it is familiar to those skilled in the art.

3 it can also be seen that in the exemplary embodiment shown, the plug part 3 is designed to be detachable, specifically detachable from the housing part 2, so that the energy supply module 6 between the housing part 2 and the plug part 3 can be connected to the diagnostic device 1 via the plug contact section 6b .

[0049] This means that the power supply module 6 can be connected to the housing part 2 via a first connection area 10a of the plug contact section 6b and the plug contact section 6b is detachably connected and/or connectable to the plug part 3 via a second connection area 10b. The connection areas 10a, 10b are essentially designed as receptacles for pin sections of the housing part 2 and the plug part 3, which ensure a conductive connection between the two and additionally enable a connection to the supercapacitors 7. In the housing part 2, a housing connection area 2c (see FIG. 3) is designed so that a connection to the first connection area 10a is possible. The area of the plug part 3 corresponding to the second connection area 10b is not visible in the figures. Preferably, the connection areas in the housing part 2 (i.e. the housing connection area 2c) and in the plug part 3 are designed so that they can interact with each other as well as with the connection areas 10a, 10b of the plug contact section 6b. In this way, the diagnostic device 100 can be used properly with and without the power supply module 6.

In Figs. 9 and 10 it can be seen how the energy supply module 6 itself is designed: the supercapacitors 7 are located in the energy storage part 6a, the connection areas 10a, 10b are located in the area of the plug contact section 6b, which is connected to the energy storage part 6a.

In an exemplary embodiment, not shown, the plug part 3 is designed in one piece with the plug contact section 6b and is connected to the plug contact section 6b in a direction away from the housing part 2 - in the assembled state. Accordingly, only a first connection area 10a is required, with which a connection of the plug contact section 6b to the housing part 2 is established.

4 shows a front view of the diagnostic device in an assembled state and a section line AA - the associated sectional view is shown in FIG. 5: Here it can be seen that housing part 2 and plug part 3 are connected to one another via the plug contact section 6b, the connection by means of screws 99 guided in pipe sleeves 99a.

[0053] Figs. 6 and 7 show a further embodiment of the invention. As before, the energy storage part 6a is arranged in the assembled state of the energy supply module 6 in such a way that it extends in a direction facing away from the plug part 3 along a longitudinal axis 1a of the diagnostic device 1. The longitudinal axis 1a of the diagnostic device 1 coincides with the longitudinal axis of the housing part 2. Accordingly, the longitudinal axis of the housing part 2 is not shown, but is subsumed under the reference number 1a.

7 in particular, it can be seen that the energy supply module 6, in particular the energy storage part 6a, lies against the housing part 2 in the assembled state. This means that a wall section of the energy storage part 6a rests on a facing wall section of the housing part 2.

As a special feature of the exemplary embodiment in FIGS. 6 and 7, there is also a connection device on the energy supply module 6, here in particular on the energy storage part 6a

11 provided, via which the energy supply module 6 can be connected to an external energy supply source (not shown). The energy storage units 7 can be charged and/or discharged, the diagnostic device 1 can be operated or the vehicle to which the diagnostic device 100 is connected can be supplied with energy via this external source. Any combinations are also possible.

[0056] In addition, a holding device 12 is provided here, with which the energy supply module 6 is detachably connected to the diagnostic device 1. Here, the holding device 12 connects the energy supply module 6 in the area of the housing part 2 with the diagnostic device 1. In this way it is ensured that the weight of the energy storage units 7 and the circuit board 8 not only rests on the plug contact section 6b, but is also carried elsewhere.

As can be seen in particular in the sectional view in FIG. 8 - section line BB in FIG 1. As shown in particular in Fig. 4, the width of the energy supply module 6, especially the energy storage part 6a, in a direction normal to the longitudinal axis 1a of the diagnostic device 1 is also smaller than the width of the diagnostic device 1. Inevitably, the height of the energy supply module 6 is in one further direction normal to the longitudinal axis 1a of the diagnostic device 1 is greater than the height of the diagnostic device 1, but this results from the need to accommodate the energy storage units 7.

Overall, the solution according to the invention results in a compact diagnostic device that enables a self-sufficient energy supply that is also interchangeable or adaptable to various applications. In this way, the requirements for diagnostic processes in vehicles can be met to a greater extent than was the case with devices from the prior art.

Claims (9)

Patent claims 1. Diagnostic device (100) with a diagnostic device (1) for connection to a diagnostic interface of a vehicle, the diagnostic device (1) having a plug part (3) which forms a diagnostic plug (4) and a housing part (2), preferably the plug part (3) is detachably arranged and/or can be arranged on the housing part (2) and at least one contact pin (5) of the diagnostic plug (13) is arranged in the plug part (3), the diagnostic device (100) being one of the diagnostic device (1 ) has a separate energy supply module (6) with one or more energy storage units (7) and the energy supply module (6) is detachably connected and / or connectable to the diagnostic device (1), characterized in that the energy supply module (6) between the housing part (2) and Plug part (3) can be connected to the diagnostic device (1) via a plug contact section (6b). 2. Diagnostic device (100) according to claim 1, wherein at least one energy storage unit (7) of the energy supply module (6) is designed as a capacitor, preferably as a supercapacitor. 3. Diagnostic device (100) according to claim 1 or 2, wherein the energy supply module (6) has at least one connection device (11) for connecting to an external energy supply source. 4. Diagnostic device (100) according to one of claims 1 to 3, wherein the plug part (3) is designed in one piece with the plug contact section (6b) and adjoins the plug contact section (6b) in a direction away from the housing part (2) and the energy supply module ( 6) can be connected to the housing part (2) via a first connection area (10a) of the plug contact section (6b). 5. Diagnostic device (100) according to one of claims 1 to 3, wherein the energy supply module (6) can be connected to the housing part (2) via a first connection area (10a) of the plug contact section (6b) and the plug contact section (6b) via a second connection area (10b) is detachably connected and/or connectable to the plug part (3). 6. Diagnostic device (100) according to one of the preceding claims, wherein the energy supply module (6) has an energy storage part (6a) for receiving the energy storage units (7), the energy storage part (6a) being in the assembled state of the energy supply module (6) in one of The direction facing away from the plug part (3) extends along a longitudinal axis (1a) of the diagnostic device (1). 7. Diagnostic device (100) according to claim 6, wherein the energy supply module (6) rests on the housing part (2) in a mounted state. 8. Diagnostic device (100) according to claim 6 or 7, wherein a width and a length of the energy storage part (6a) are smaller than or equal to a width and a length of the housing part (2) of the diagnostic device (1). 9. Diagnostic device (100) according to one of the preceding claims, wherein the energy supply module (6) has at least one holding device (12) for releasably connecting to the diagnostic device (1), wherein preferably the holding device (12) holds the energy supply module (6) in the area of Housing part (2) connects to the diagnostic device (1). 4 sheets of drawings