阅读说明：本技术 联接装置的状态指示 (Status indication of coupling device ) 是由 安德斯·托勒 于 2018-06-25 设计创作，主要内容包括：一种用于提供牵引车辆的联接装置的状态指示的布置，该布置包括：传感器布置(20)，该传感器布置能操作来检测该联接装置的联接销何时处于接合联接位置，发光装置(10)，该发光装置电连接到该传感器布置、并且被配置用于发射指示该联接销何时处于接合联接位置的光信号，发光装置(10)被布置在传感器附近。该布置进一步包括光波导(11)，该光波导被布置用于接收该光信号并且引导该光信号；以及耦合输出结构(17；18)，该耦合输出结构被布置用于将该光信号从该光波导耦合输出。(An arrangement for providing an indication of the status of a coupling device of a towing vehicle, the arrangement comprising: -a sensor arrangement (20) operable to detect when a coupling pin of the coupling device is in an engaged coupling position, -a light emitting device (10) electrically connected to the sensor arrangement and configured for emitting a light signal indicating when the coupling pin is in the engaged coupling position, the light emitting device (10) being arranged in the vicinity of the sensor. The arrangement further comprises an optical waveguide (11) arranged to receive the optical signal and to guide the optical signal; and an out-coupling structure (17; 18) arranged for out-coupling the optical signal from the optical waveguide.)

1. An arrangement for providing an indication of the status of a coupling device of a towing vehicle, the arrangement comprising:

a sensor arrangement (20) operable to detect when a coupling pin of the coupling device is in an engaged coupling position,

a light emitting device (10) electrically connected to the sensor arrangement and configured for emitting a light signal indicating when the coupling pin is in an engaged coupling position,

the light emitting means (10) is arranged in the vicinity of the sensor,

it is characterized in that

An optical waveguide (11) arranged to receive the optical signal and to guide the optical signal; and

a coupling-out structure (17; 18) arranged for coupling out the optical signal from the optical waveguide.

2. An arrangement according to claim 1, wherein the optical waveguide (11) is a flexible optical fibre (12).

3. An arrangement according to claim 2, wherein the out-coupling structures (18) extend along a surface of the optical fibre so as to provide out-coupling of light in a radial direction along the optical fibre.

4. An arrangement according to claim 3, wherein the optical fiber (12) is arranged in a path in a horizontal plane so as to emit light in all directions in the horizontal plane.

5. The arrangement according to claim 1 or 2, wherein the optical waveguide (10) has: a first end (12a) adjacent to the light emitting device, the first end being arranged for receiving the light signal; and a second end portion (12b) at a position (13) at a distance from the sensor, an end surface (17) of the waveguide (10) forming the out-coupling structure.

6. Arrangement according to claim 5, wherein said location (13) is on the outside (14) of the towing vehicle (1).

7. The arrangement according to claim 6, wherein the location is on a driver side (14) of the towing vehicle.

8. The arrangement according to any of claims 5-7, wherein the out-coupling structure comprises a lens (15) configured for emitting the optical signal in a desired direction.

9. Arrangement according to any of claims 5-7, wherein the light emitted by the second end (12b) is directed towards the front of the towing vehicle.

10. Arrangement according to any of the preceding claims, wherein the light emitting device (10) comprises at least one Light Emitting Diode (LED).

11. Arrangement according to any of the preceding claims, wherein the coupling device further comprises a locking pin (20) configured for mechanically locking the coupling pin (4) in its engaged coupling position, and wherein said sensor arrangement (22) is configured for detecting when the coupling pin (4) is in the engaged coupling position by detecting the position of said locking pin (20).

12. Arrangement according to claim 11, wherein, when the coupling pin (4) is in its engaged coupling position, the locking pin (20) is movable in a substantially horizontal direction to an insertion position in which the locking pin (20) prevents disengagement of the coupling pin (4).

Technical Field

The present invention relates to an arrangement for providing an indication of the status of a coupling device of a towing vehicle.

Background

In many trailer couplers, the operating arm of the coupling pin (typically a vertically movable coupling pin) will act as the first locking means of the coupler. The position of the operating arm will also provide an indication of the status of the coupling device (i.e. locked or unlocked). However, in many jurisdictions, there are local regulations that specify secondary safety devices in addition to the operating arm. Such secondary security means may be provided, for example, by a locking pin or other member operable to engage with the coupling pin to ensure its unlocked position.

To determine the status of such secondary safety devices, secondary safety devices are typically provided with sensors that can detect the status of the device. Further, means are provided for providing status indications to the driver. As an example, the state may normally be "green" (indicating that the coupling pin is also locked) or "red" (indicating that the state of the coupling pin is unknown).

In some cases, the indicator is disposed in the operator's compartment (e.g., on the dashboard) and is in electrical connection with the sensor, which is typically hardwired. Thus, the indicator may provide an indication to the driver.

In other cases it may be sufficient to provide an indication on the side of the vehicle, which the driver can observe, for example in the rear view mirror. One simple way of providing such an indication is to arrange a light emitting device (e.g. an LED) on the side of the vehicle and to connect the wires of the light emitting device to the sensor. However, this has the disadvantage that the electrical connections and the lighting device are required to meet electrical safety requirements. Furthermore, the light emitting device and its connections are susceptible to corrosion, which may deteriorate the indicating function.

Disclosure of Invention

It is an object of the present invention to overcome the above problems and to provide an improved status indication of a coupling device.

According to a first aspect of the present invention, this and other objects are achieved by an arrangement for providing an indication of the status of a coupling device of a towing vehicle, the arrangement comprising: a sensor arrangement operable to detect when a coupling pin of the coupling device is in an engaged coupling position, a light emitting device electrically connected to the sensor arrangement and configured to emit a light signal indicating when the coupling pin is in the engaged coupling position, the light emitting device being arranged in the vicinity of the sensor. The arrangement further comprises an optical waveguide arranged to receive the optical signal and to guide the optical signal; and an out-coupling structure arranged to out-couple the optical signal from the optical waveguide.

By "adjacent" is here meant that the light emitting means is in the same electrical safety zone as the sensor (and any other electrical circuitry associated with the coupling means).

By using optical waveguides to guide the optical signals, the optical signals can be emitted in an easily observable manner and location. The use of optical waveguides to guide light further avoids problems associated with electrical safety regulations in places not belonging to the safety classification. Also, electrical problems caused by corrosion, moisture and dirt are reduced or eliminated.

The optical waveguide may be a flexible optical fiber. Such fibers are readily available and have properties suitable for the present invention.

In some embodiments, the out-coupling structure extends along a surface of the optical waveguide so as to provide out-coupling of light in a radial direction along the optical fiber. The out-coupling structure may simply be a grating or other irregularity on the surface of the optical waveguide to break the total internal reflection that would otherwise occur in the optical waveguide. By providing coupling-out along the entire waveguide, optical signal emission can be easily observed.

The optical fibers may be arranged as paths in a horizontal plane so as to emit light in all directions in the horizontal plane. For example, the optical fiber may be arranged in one or several rings or loops, e.g. around the coupling device. Such an arrangement ensures that the light signal is emitted in all directions around the towing vehicle, so that the light signal is easily observed.

In other embodiments, the optical waveguide has: a first end adjacent to the light emitting device, the first end arranged to receive the light signal; and a second end at a distance from the sensor at which an end surface of the second end forms an out-coupling structure. In this case, the optical waveguide is used to shift the optical signal emitted by the light emitting device to the position.

This position can be on the outside of the towing vehicle, easily observable. Preferably, the position is on the driver's side of the towing vehicle, so that the driver can see the status indication in the rear view mirror.

The out-coupling structure may comprise an optical element, such as a lens, configured to emit the optical signal in a desired direction. For example, where the second end is on the side of the towing vehicle, the lens may direct the optical signal toward the front of the towing vehicle.

The light emitting device may comprise at least one Light Emitting Diode (LED). Each indication may be a separate color LED (e.g., one red and one green LED), or a single LED may be controlled to emit different colors (or otherwise emit different signals using, for example, intensity modulation).

The coupling means may be of the type comprising a locking pin configured for mechanically locking the coupling pin in its engaged coupling position. Such locking pins are referred to as "second safety devices". In this case, the sensor arrangement may be configured to detect when the coupling pin is in the engaged coupling position by detecting the position of the locking pin. In a typical coupling device, the locking pin may move in a substantially horizontal direction above the coupling pin when the coupling pin is in its engaged (lowered) coupling position, thereby preventing the coupling pin from moving upward and disengaging.

Drawings

The present invention will be described in more detail with reference to the accompanying drawings, which show preferred embodiments of the invention.

Fig. 1 is a schematic and partially exploded top view of a towing vehicle having a coupling device and a status indication arrangement according to an embodiment of the invention.

Fig. 2a and 2b schematically show a coupling device with a coupling pin and a drawbar with a drawbar eye.

Fig. 3a and 3b are cross-sectional views of an exemplary coupling device including some elements of a status indication arrangement according to an embodiment of the present invention.

Detailed Description

Fig. 1 very schematically shows a top view of a towing vehicle 1 provided with a coupling device 2 mounted to a towing beam 3. The rear part of the vehicle 1 has been exploded to clearly show the coupling device 2. It should be noted that in this case the towing vehicle is a motorized truck, but the intermediate trailer, i.e. the trailer which is pulled by the truck and in turn pulls the following trailer, may also be referred to as "towing vehicle".

As is very schematically illustrated in fig. 2a and 2b, the coupling device 2 is of the type comprising a vertically displaceable coupling pin 4 (see also fig. 3a and 3 b). The tow bar 5, which is mounted to the trailer, has an opening at its forward end, referred to as a tow bar "hitch" 6. The drawbar 5 is insertable into the coupling device 2 to a position such that the suspension loop 6 is located directly below the coupling pin 4. The coupling device 2 preferably has some kind of guiding funnel 7 or coupling mouth to help guide the drawbar 5 into position. When the drawbar eye 6 is in position, the coupling pin 4 is lowered into the eye 6, thereby securing the drawbar 5 in the coupling device 2 (see fig. 2 b). The operating handle 8 of the coupling device 2 moves together with the coupling pin 4 and can thus be used as a first indication of when the coupling pin 4 is lowered. Further, the illustrated coupling device 2 comprises a second safety device in the form of a spring-loaded locking pin 20. In fig. 2a, the locking pin 20 abuts the coupling pin 4 (or some part of its operational arrangement) and protrudes slightly outside the coupling housing. In fig. 2b, the locking pin is free to move to the insertion position when the coupling pin 4 is lowered. The operating arrangement is configured such that the locking pin 20 can only be moved to its insertion position when the coupling pin is fully lowered and thus engages the drawbar eye 6. The operation of the locking pin 20 will be described in more detail with reference to fig. 3a and 3 b.

It is critical for the driver or other operator to know when the coupling device 2 engages the drawbar 5. For this purpose, the status indicator arrangement may be arranged for providing a visual indication of the status of the coupling device 2. In a simple case, the state relates to the position of the coupling pin 4, i.e. whether it is in the raised position (fig. 2a) or in the lowered position (fig. 2 b). Alternatively, the status indication relates to the status of the secondary safety device such that the first signal indicates that the connector is positively engaged (e.g. green light) and the second signal (e.g. red light) indicates that there is no engagement.

In the illustrated example, the indicator arrangement comprises a light emitting device 10, for example comprising one or several light sources 9a, 9b, such as LEDs, arranged near the coupling pin 4. The light emitting device 10 is connected to a sensor 22 (see fig. 3a and 3b) which is able to detect when the coupling pin 4 is engaged. In fig. 2a, the first LED 9a emits an optical signal when the coupling pin 4 is raised. In fig. 2b, the second LED 9b emits an optical signal when the coupling pin 4 is lowered.

Since the coupling device 2 comprises sensors and control circuits (not shown) requiring a voltage, the device 2 needs to comply with electrical safety regulations. Therefore, little additional work and cost are required to electrically connect the light emitting device to the sensor. In particular, it does not require any additional safety legislation guarantees.

However, it is desirable to make the status indication more visible, and for this purpose the arrangement may be provided with an optical waveguide (light guide) 11, for example in the form of one or several optical fibers 12, and coupling-out structures 17, 18 for coupling out light from the waveguide 11. Light emitted by the light emitting device 10 is coupled into the light guide 11 and then guided to a desired position by the light guide 11. To reduce losses during coupling-in, the arrangement may comprise suitable coupling-in elements 19 in optical contact with the ends of the light-emitting means and the light-guide 11. Such optical coupling-in elements are often used in conjunction with optical waveguides, such as optical fibers, in order to reduce losses.

The out-coupling structure may be any structure that breaks the total internal reflection that confines the light in the light-guide 11. The simplest example is the end 12b of the light-guide, where light can be emitted through the end surface 17. However, the out-coupling structures may also be formed along the longitudinal axis of the light-guide 11, for example in the form of gratings 18 or other surface structures. The exact design and location of the out-coupling structure(s) 17, 18 depends on the desired light emission location and appearance.

According to one example, the light-guide 11 is provided with longitudinal out-coupling structures (e.g. gratings 18) and arranged as paths in a horizontal plane. For example, the light guide 11 may be arranged as a ring or coil around the coupling device 2. As a result, light is coupled out from the light-guide 11 in all directions in the horizontal plane and is thus easily visible in all directions.

In the case illustrated in fig. 1 and 2, each optical fiber has a first end 12a arranged for receiving light emitted by the light-emitting device 10, and a second distal end 12b arranged at a desired position 13, here located on an outer side 14 of the vehicle 1, preferably on the driver's side. In fig. 1, one light source 9a, 9b is used for each of the two status indications (e.g. one red and one green), and two optical fibers 11 are used for guiding light from the respective light sources. In fig. 2, light from two light sources 9a, 9b is coupled into a single optical fiber 12.

Further, as will be appreciated by those skilled in the art, it is also possible to have a single light source capable of emitting two different light signals. For example, the light source may be a light source capable of emitting different colors (e.g. a color controllable LED) or a composite light source comprising several LEDs of different colors. Alternatively, the first signal and the second signal may be the same color but have different characteristics, such as steady light or flashing light. When a single light emitting device is used to transmit both signals, only a single optical fiber is required.

An optical element, such as a suitable lens 15, may be disposed adjacent to the end surface 17 of the optical fiber(s) 12 and configured to couple light from the optical fiber 12 in and direct the light in a suitable manner. For example, the lens 15 may be configured to direct the light signal towards the front of the vehicle 1 so that the driver can more easily see the light signal in the rear view mirror 16. Alternatively, the lens 15 is simply configured to spread the light from the optical fiber to ensure that it is visible in all directions.

Fig. 3a and 3b show the coupling device of fig. 2a and 2b in a sectional view. In the figure, the coupling pin 4 is seen more clearly in its raised position (fig. 3a) and in its lowered position (fig. 3 b). Fig. 3a shows how the locking pin 20 abuts against the coupling pin 4, while fig. 3b shows how the locking pin is free to move further into the coupling housing.

The coupling device 2 further comprises a sensor 22 arranged for detecting the position of the locking pin 20. The sensor is preferably a non-contact sensor, such as an inductive sensor, a magnetic sensor, a hall effect sensor, an optical sensor, or any other suitable form of sensor. The sensor is electrically connected to the light emitting device 10 such that a first light signal (e.g. green) is emitted when the sensor 22 detects that the locking pin 20 is in the inserted position (fig. 3b), and a second light signal (e.g. red) is emitted when the sensor detects that the locking pin 20 is in the extracted position (fig. 3 a). It should thus be noted that the first optical signal indicates that the coupling pin 4 is definitely in its lowered (engaged) position, whereas the second signal only indicates that this is not the case and that the exact position of the coupling pin 4 is unknown. For example, it is not certain that the coupling pin 4 is in its fully raised position.

The person skilled in the art realizes that the present invention by no means is limited to the preferred embodiments described above. On the contrary, many modifications and variations are possible within the scope of the appended claims. For example, different types of optical elements may be used for coupling in, coupling out and guiding light.