The invention relates to a plug connectors.
In general, a plug connector comprises a plurality of electrical contact elements, and is used as a connecting piece at cables, or directly at housings, as a built-in plug or socket. Protection classes with regard to sealing against dust, water spray or immersion must be observed here.
In addition to electrical contact elements, a generic plug connector also comprises an elastic sealing body in order to provide adequate sealing to a housing wall on which the plug connector is to be mounted.
In general it is desirable to provide an illuminated indicator that shows the state of an electrical interface for which the plug connector is used.
In the case of devices with a low protection class such as IP20, status indicators are frequently integrated directly into the plug connectors. In the case of RJ45 plugs such as are used for network cables, illuminated signals can show the status of a network connection, for example in relation to a connection structure or to a data transfer through the plug connector. Devices with a higher protection class, such as IP67, on the other hand, use separate LEDs for status indicators that are arranged in respective openings at the housing, independently of the plug connector. The openings can have their own seal, but can also, for example, be glued transparently or provided with a screw-in lens. This means that a significantly greater effort must usually be accepted to provide a status indicator for higher protection classes.
DE 10 2012 202 225 B4 shows a plug connector with contact elements and elastic seals at a cable-end and at a plug-end of the plug connector. A plug connector with a seal between two housing parts is known from both DE 20 2016 104 369 U1 and from DE 20 2016 008 383 U1. A status indicator is not described in these documents. DE 20 2017 100 608 U1 describes a plug connector with a status indicator. LEDs with corresponding electronics are accommodated for this purpose in the housing of the plug connector.
One object of the invention is that of providing a plug connector that offers an illuminated indication with the best possible sealing and a simple construction. A corresponding sealing body is also to be given.
According to the invention, in the plug connector of the above-mentioned type the elastic sealing body comprises a transparent sealing ring that is connected to at least one light guide arm that extends away from the sealing ring.
Since a sealing ring of transparent material is used, the sealing ring can not only be used for sealing, but at the same time also for the output of light. The transparency should be present here in the visible wavelength range, or at least a partial range thereof. The at least one light guide arm makes it possible for light from a light source to be guided to the sealing ring. The light source can in particular be arranged in a housing at which the plug connector is to be attached. As a result, apart from the plug connector, no additional components are required in order to guide light from a light source onwards and to radiate it out.
A single housing opening is thus enough for the plug connector, and no additional opening is necessary for a light indication.
The light guide arm can extend away from the sealing ring in an axial direction. The light guide arm thus passes from the sealing ring into the housing, meaning away from the plug end at which the electrical contact elements are located. The axial direction identifies the longitudinal direction of the plug connector; the sealing ring runs in an annular manner around this axis. Apart from an axial direction component, the longitudinal axis of the light guide arm can also comprise another direction component. The light guide arm can, for example, be spiral or have a spiral section. The light guide arm can alternatively also extend inwards from the sealing ring in a radial direction. A light guide arm can, in addition, also comprise one or a plurality of kinks or bends. It is furthermore possible that two or more light guide arms have different shapes.
In one form of embodiment of the invention, the sealing ring and the at least one light guide arm are formed as one piece, through injection molding for example, wherein both consist of the same transparent and elastic material. A one-piece design can be advantageous so that even under pressure an unbroken connection between the light guide arm and the sealing ring is ensured if the seal is pressed against a housing wall.
The plug connector can comprise a nut to press the sealing ring against a housing wall. This can be screwed onto an external thread of an enclosing wall of the plug connector, and be adjustable relative to the sealing ring, in order to develop a pressure between the sealing ring and the housing wall.
Even if the sealing ring and the at least one light guide arm are not formed as one piece, they can consist of the same material. Light losses resulting from reflections that occur at boundary surfaces between materials with different refractive indices can hereby be avoided or at least reduced. The at least one light guide arm can, however, also be connected to the sealing ring via a respective sprue gate.
The terms outer jacket face, inner face, end face and sealing face will be used in the present description to identify the various faces of the sealing ring. The outer jacket face here identifies the surrounding surface that runs around the longitudinal axis of the plug connector. Opposite the outer jacket face, i.e. facing inward, the inner face bounds the sealing ring. The end face of the sealing ring faces toward a plug end/connecting end of the plug connector. The end face can be planar, or can also have another shape, for example corrugated or rounded. Opposite the end face, the sealing ring comprises the sealing face, which is preferably planar to provide a seal against, in particular, a housing wall.
It can be preferable if the at least one light guide arm is connected to the sealing ring at the inner face of the sealing ring. Light is thus guided into the sealing ring from the light guide arm at the inner face. Deformations resulting from the sealing pressure are relatively low at the inner face, which can be advantageous for the desired light guidance.
Each light guide arm can comprise a deflection face at which light travelling inside the light guide arm is reflected in the direction of the sealing ring. The deflection lace can be located in the axial direction at the level of the sealing ring, and can be oriented at an angle of 45°, or, more generally, of between 35° and 55°, to the axial direction.
Seen in the radial direction, a light guide arm and its deflection face can thus be arranged in a central region inside the sealing ring.
The deflection face can be oriented at an angle to the light guide arm, so that light is reflected to the deflection face through total internal reflection. As a result, no further components are required for light guidance and deflection. The angle at which total internal reflection is possible depends on the refractive index of the material of the light guide arm and on the wavelength of the light, wherein, in the present case, light from the visible spectral band is to be assumed. An angle of incidence relative to a normal to the surface must be sufficiently large for total internal reflection; to enable this, each light guide arm can have two deflection faces following one another. Light is thus reflected twice in sequence, and thereby deflected by a total of about 45°.
Deflection can also be achieved by mirroring the deflection face instead of by total internal reflection. A reflective layer of, for example, silver can be vaporized here on to the surface.
An outer jacket face and/or an end face of the ring can be roughened to radiate light diffusely. On the other hand, an inner face of the ring, and the surface of the at least one light guide arm, can be smooth in order to avoid light being coupled out at these surfaces. The terms “rough” and “smooth” can be understood to mean that the roughened faces have greater roughness than the smooth faces. The surface of the light guide arm should comprise its light inlet face as well as its side faces, which can be oriented essentially perpendicularly with respect to its light inlet face.
The term “light guide arm” can be understood to mean an elongated shape whose primary extension component can extend in the axial direction of the plug connector. One end of the light guide arm that points away from the sealing ring can represent the light inlet face.
To achieve in particular a more uniform light distribution in the sealing ring, a cross-section of the at least one light guide arm can become greater towards the sealing ring. Alternatively or in addition, the light deflection face can be convex for the same purpose, so that reflected light is fanned out.
So that the light propagation in the sealing ring is as uniform as possible, the sealing ring can also be widened in the radial direction at each connecting region to a light guide arm.
For a more uniform light propagation, scattering centers can also be formed inside the sealing ring, for example gas bubbles or interfering enclosures.
The sealing ring can protrude radially outward further than the other components of the plug connector that lie, in the installed state, outside the housing. The end face of the sealing ring is thus not completely covered. As a result, outward light radiation at the end face is at least not completely blocked by other components of the plug connector. In other words, a radius of the sealing ring can be greater than a radius of the other components of the plug connector that are located between the sealing ring and a plug end of the plug connector. If a fastening component, in particular a screw, a nut or a washer, and a corresponding opposing piece, are used at the end face of the sealing ring in order to press the sealing ring against the housing wall, the sealing ring accordingly has a greater diameter. A pressing region of the sealing ring is consequentially smaller than the surface of the end face (or smaller than the area of the sealing face) of the sealing ring.
Multiple light guide arms can also be connected to the sealing ring. These can extend parallel to one another. Light from a respective light source can be guided via each light guide arm. The light guide arms can be distributed uniformly in the circumferential direction, for example two light guide arms located opposite one another, or three light guide arms each arranged 120° apart. If light sources that radiate in the same spectral region are used, then a more uniformly distributed light radiation can be achieved around the circumference of the sealing ring. In the case of light sources that radiate in different spectral regions, the sealing ring can radiate light of different colors via the different light guide arms. Different statuses can, for example, be indicated in this way.
The invention also comprises an electronic device with a housing that has at least one opening it which a plug connector according to the invention is arranged. The sealing ring establishes a seal of the plug connector against the housing wall in which the opening is formed. The opening is thus, for example, sealed against fluids according to IP67. At least one light source is present in the housing, and is arranged such that light radiated from the light source is coupled via a light inlet face into the at least one light guide arm of the plug connector. Light can thus be guided via the light guide arm that extends through the opening out of the housing, where it is emitted by the sealing ring that lies against an outer face of the housing, for a light indication of the electronic device.
The at least one light source can be located on a circuit board in the housing. The light inlet face of the at least one light guide arm can be arranged next to the at least one light source. The elastic material of the light guide arm can, in principle, be pressed in direct contact against the light source. In order to avoid self-reflections, a clearance between the light inlet face and the associated light source can, however, also be provided. The light inlet face can, moreover, be concave, i.e. curving to the inside, so that light impinging upon it is coupled in as completely as possible.
Multiple light sources that differ in the spectral bands that they transmit can be arranged on the circuit board. As described earlier, the light of the multiple light sources can be guided via multiple light guide arms. Alternatively, it can also be possible for the light of the multiple light sources to be guided to the sealing ring by way of the same light guide arm. A surface of the light inlet face can, for this purpose, be sufficiently large that it is adjacent to multiple light sources on the circuit board.
The plug connector can have a cylindrical segment that is inside the housing when in the installed state. The cylindrical segment can, for example, consist of metal, and for each light guide arm can have an axial groove to accommodate the respective light guide arm. A grip of the sealing body on other components of the plug connector can hereby be improved.
The electronic device can comprise an electronic control unit that is configured always to switch the at least one light source on when a data transfer takes place via the associated plug connector. A status indicator can be formed in this way without separate housing openings being necessary for this purpose. In the case of multiple light sources, whose light can be guided by way of the light guide arms, the electronic control unit can be configured to indicate various states by activating the different light sources.
The plug connector of the invention can also, for example, be integrated into a switch as an interface with display. The invention can be employed flexibly for various applications, for example also as a wall feed-through. The physical size and geometry can, in principle, be arbitrary here. When embodied as a round plug, the sealing ring can have a circular, annular cross-section. With other plug forms, however, the sealing ring can also have a different cross-section, for example a rounded, annular rectangular form. The plug connector can be designed as a male plug or built-in plug, or as a female coupling or socket. The electrical contact elements can accordingly be contact pins or contact openings.
The present invention also relates to a sealing body. This comprises an elastic, transparent sealing ring that is connected to at least one light guide arm that extends away from the sealing ring. Advantageous embodiments of the sealing body correspond to the variants that are described in relation to the sealing body of the plug connector. The sealing body according to the invention can be employed for the plug connector described here, also for other electrical or electronic components that are to be attached in a sealed manner to a housing opening. These can, for example, be switches, buttons, input devices, cable outlets, sensors, displays or transmitters.
Exemplary embodiments of the invention are illustrated in the drawings and are explained in more detail below. In the drawings:
The figures partially contain simplified, schematic illustrations. The same elements are usually identified by consistent reference signs.
The exemplary embodiment of a plug connector 1 according to the invention is described with reference to
As shown in
The plug connector 1 comprises a sealing body 4 in order to establish a desired sealing of the plug connector 1 against the housing wall 12. The sealing body 4 is shown more precisely in
As shown in
The arrows 16 in
The sealing body 5 shown in
An end face 6 and a jacket face 7 of the sealing ring 5 are roughened so that light is coupled more easily and as uniformly as possible out of the sealing ring 5. Since outward coupling, and the direction of outward radiation, depends on the angle of incidence of the light at the end face 6 or at the jacket face 7, a rough surface leads to a more uniform outward radiation. Because as little outward coupling of the light as possible should take place at the other faces of the sealing body 4, the other faces can, on the other hand, be made smoother than the end face 6 and the jacket face 7.
Because light can be radiated out by way of the end face 6, this should not be completely covered. As shown in
In the forms of embodiment described above, the plug connector of the invention offers an illuminated indication with good sealing against a housing wall, without additional optical openings being necessary in the housing wall for the illuminated indication.
Even when different aspects or features of the invention are each shown in combination in the figures, it will—unless otherwise stated—be clear to the skilled person that the combinations illustrated and discussed are not the only possibilities. In particular, units or feature complexes from different exemplary embodiments that correspond to one another can be exchanged with one another.
Number | Date | Country | Kind |
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10 2018 125 121.1 | Oct 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2019/100870 | 10/8/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/074044 | 4/16/2020 | WO | A |
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Number | Date | Country | |
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20210226379 A1 | Jul 2021 | US |