DE19743826A1 - Sea lantern for marking ship navigation channel - Google Patents

Abstract

The lantern has an electrically switched LED light source with a number of individual LED elements (11), spaced across the surface of a common flexible circuit board (10), which is bent into a cylinder. The LED elements may be arranged in individually switched rows around the periphery of the cylindrical circuit board.

Description

The invention relates to a lantern with an elek tric controllable light source, ins special to a sea lantern.

Electric sea lanterns are traditionally one Light source in the form of incandescent or halogen lamps equips and serves to mark shipping routes or as a navigation aid for ships. These lanterns are there designed to have a specific identification light signal submit, which is according to the respective marking purpose of the lantern in question. For example, that Identifier view signal from a periodically bright and dun again light signal with a predefinable period stand.

The invention is the technical problem of providing a lantern that can be used in particular as a sea lantern based on the herge with relatively little effort represents and can be operated and with which is in operation can achieve an even, good all-round light distribution.

The invention solves this problem by providing it a lantern with the features of claim 1. This La  terne contains an LED egg light source as the light source A large number of individual LED elements, which are distributed over a large area on the outside of a common, cylindrical curved NEN, flexible circuit card are arranged. The production this lantern is consequently simplified in that al le LED elements on the flexible plan of the previous month can be tiert, after which the circuit board in the desired Cylindrical shape is bent. This results in a cylindrical, on the cylinder jacket radiating light source, to the reali only one, suitable with the LED elements pieceed circuit board is required. By suitably the same moderate arrangement of the LED elements on the circuit board can a particularly homogeneous light intensity distribution and on request a large vertical spread of the from the cylinder jacket to the outside radiated light can be achieved.

In a further developed according to claim 2 lantern LED elements arranged so that the central axis of their jewei radiation cone runs radially, which is one for many Preferred radiation characteristics of the LED Total light source leads.

In a further developed according to claim 3 lantern The LED light source has multiple rows of LED elements around the circumference of the cylindrical circuit board stretch and in the direction of the PCB cylinder axis follow one another. As a result, all or only, depending on your needs a selected part of the LED rows to achieve a ge desired light intensity distribution can be activated.

In a further embodiment of this lantern are according to claim 4 the LED elements of adjacent LED rows in the circumferential direction arranged offset by a predeterminable angle, preferably by half the angular distance between two adjacent LED elements in a row. This favors the achievement of a particular uniform light intensity distribution of the emitted light tes.  

A lantern developed according to claim 5 includes one into a primary circuit and one of these electrically isolated ten, d. H. e.g. B. using transformers or optocouplers gal vanically separated secondary circuit split light sources control. The primary circuit includes a DC / DC Converter unit, while the secondary circuit is coupled to it pelt on the LED control unit that controls the LED elements points. This isolation is for some applications advantageous, e.g. B. when used as a sea lantern.

In a further embodiment of the invention, according to An saying 6 an identifier control unit for controlling the LED Control unit provided for the delivery of an identifier Light signal with a user on an identifier Allow specifiable identifier by the LED light source. This can be particularly the case when a sea lantern is used especially around special marking identifiers of shipping act because of.

In a further embodiment of this lantern is according to claim 7 between the identification control unit and the LED driver unit is provided to generate the LED ele to be able to control them clocked. The clocked control can increase the light with certain types of LEDs serve strength. In addition, the frequency of the so generated Clock signal modulated for the optical transmission of data be.

In a lantern developed according to claim 8 is also the DC / DC converter unit to the identifier control unit closed and follows their shutdown commands with a specified switch-off delay. This can cause for identifiers with a relatively quick change from bright and dark phases do not always restart the converter unit must, while in long dark periods the identifier is unnecessary low idle power consumption of the converter unit is avoided.  

A lantern developed according to claim 9 includes one Fault monitoring unit, which the function of the LED on control unit monitors and if an error is detected corresponding error message generated.

In a further embodiment of this measure is according to claim 10 the error signal of the error monitoring unit half conductor switching element can be supplied, which against overvoltage and Overcurrent is protected and its blocking in the event of a fault Condition. This eliminates an advantageous error security realized.

In a further developed according to claim 11 lantern LED light source arranged inside an upper housing part, the openable is connected to a lower housing part. A safety shutdown unit detects whether the housing upper part is properly mounted on the lower part of the housing or not. If the dismantled state is recognized, deactivated the safety shutdown unit the DC / DC converter unit. There with an undesired switching on of the LED light source prevented open housing.

In a lantern developed according to claim 12, this Upper part of the housing on an opening that from a thermally conductive cover cap is covered. This allows the heat generated by the LED light source is well dissipated to the outside leads, even if the upper housing part otherwise not be made of a particularly good heat-conducting material stands.

An advantageous embodiment of the invention is in the Drawings shown and will be described below. Here show:

Fig. 1 is a longitudinal sectional view through a sea lantern with LED light source and

Fig. 2 is a block diagram of a controller used in the lantern of Fig. 1 for the LED light source.

The lake lantern shown in longitudinal section of Fig. 1 in its construction has a lower housing part 1 with a built-in connector 2 , via which the necessary electrical connections are made to the outside, and with a conventional light sensor, not shown, for detecting the outside brightness. With the lower housing part 1 , a housing upper part 4 is connected via screw connections 32 and a folding hinge 3 . By loosening the screw connections 32 between the housing upper part 4 and the lower housing part 1 , the lantern housing thus formed can be opened with the aid of the folding hinge 3 . The upper housing part 4 contains a transparent, cylindrical plexiglass hood 5 with a large top opening 6 , which is covered by an attached, highly heat-conductive cover cap 7 made of aluminum, which closes with a gull deflector 8 formed into a spiral spring on the top.

In the interior of the upper housing part 4 there is a cylindrical fastening bracket 9 , to which a flexible circuit board 10, which is bent in a cylindrical manner, is fastened. This circuit card 10 is preferably equipped in one side in its still flat state with a large number of distributed across ordered LED elements 11 such that the LED elements 11 in the assembled, bent state of the circuit board 10 on the outside thereof with radially outward-pointing radiation cone center axis are positioned. The circuit board 10 with the LED elements 11 thus acts as a cylindrical LED light source with which a particularly homogeneous light intensity distribution with a comparatively large vertical scatter can be achieved by suitable arrangement of the LED elements 11 , as is the case for use in the electrical sea lantern is desired. The LED elements 11 are in the example shown in sixteen horizontal rows 12 ₁ , 12 ₂ , each extending around the circumference of the circuit board 10 . . ., 12 ₁₆ arranged on, which follow each other in the direction of the circuit card cylinder axis 13 , which coincides with the longitudinal axis of the lantern. Each LED row contains fifty-three LED elements 11 connected in series, the LED rows 12 ₁ , 12 _2,. . ., 12 ₁₆ individually switchable, ie can be controlled for the purpose of switching the associated LED elements 11 on and off. It is understood that the number of LED rows and the number of LED elements per LED row can vary as required.

The LED elements 11 of adjacent LED rows are preferably arranged with an angular offset in the circumferential direction. This favors the achievement of a uniform distribution of luminous intensity, the offset in particular being equal to half the angular distance between two adjacent LED elements of an LED row, so that each LED element on the row in the circumferential direction of the printed circuit board 10 in the middle between two LED elements of a neighboring row of LEDs.

To control the LED light source 10 , 11 , the Seela terne has an associated light source control inside the lantern housing, the structure of which is shown in the block diagram of FIG. 2. As can be seen from Fig. 2, the light source control includes a framed power supply unit 14 , to which a + 12V supply voltage can be fed, which is led via an input fuse 15 and an input filter 16 to the input side of a DC / DC converter 17 , which increases the DC input voltage of 12V to an operating DC voltage of, for example, 175V. The converter 17 is assigned an associated voltage setting 18 and a reference voltage generation unit 31 . Furthermore, the power supply 14 is a Sicherheitsabschalteinheit 18 with a reed contact 18 a on which is mounted in the lower housing part 1 and is actuated by an attached in the upper housing part 4 magnet when the upper housing part 4 is in its mounted on the lower housing part 1 position. If it is recognized in this way that the upper housing part 4 is not properly mounted on the lower housing part 1 or the later ne is just open, the safety shutdown unit 18 deactivates the DC / DC converter 17 and thus the lighting operation of the lantern.

As a further component, the power supply unit 14 has an identification control unit 19 , which is supplied with the output signal 20 of a user-operable, not shown, provided in the lower housing part 1 , and sends the dependent control signal. The identifier can, for. B. with so-called DIP switches for setting the ge desired, from the lantern in the form of a corresponding Ken voltage light signal verses to be verses hen. This DIP switch can be adjusted in the desired manner after removing the housing upper part 4 by the user. A newly set identifier is then adopted after a brief interruption in the supply voltage. Furthermore, the power supply unit 14 includes a switching stage 21 for transmitting a supplied error signal 22 to an error output of the light source control, which has a semiconductor switching element which is protected against voltages and overcurrents and which is in its blocking state in the event of an error.

The entire power supply unit 14 is located on a power supply board in the interior of the lower housing part 1 , which also contains the necessary wiring elements. For the power supply unit 14 , a potential separation, in particular also relating to the DC / DC converter 17, is seen by means of a transformer or optocoupler, which galvanically decouples the power supply unit 14 as the primary circuit from a secondary circuit, which consists of the other components shown in FIG. 2. Specifically, the secondary circuit includes the actual LED control unit, which comprises a constant current source unit 23 , which for each individually switchable and switchable LED row of the LED light source to be controlled comprises its own constant current source and which has an associated current setting 25 and a series switching and series switching unit 26 are assigned. The LED control unit is located on a corresponding control board in the upper housing part 4 and is coupled to the DC / DC converter 17 and the reference voltage generating unit 31 . At the current setting 25 , the current strengths to be provided by the individual constant current sources can be set. The series switching and series switch-off unit 26 summarizes user-operated switches, for. B. DIP switches, with de NEN the LED series 12 ₁ , 12 ₂ ,. . ., 12 ₁₆ can be switched on or off individually. Furthermore, the secondary circuit housed in the upper part 4 of the housing has an error monitoring unit 27 which monitors the individual constant current sources of the constant current source unit 23 and which outputs the error signal 22 supplied to the switching stage 21 in the power supply unit 14 if at least one of the constant current sources provides a current which is greater than a specifiable measure deviates from the setpoint.

The individual constant current sources of the constant current source unit 23 are operated as a function of a supplied voltage control signal 28 , which is generated by the identification control unit 19 , this signal if necessary by an optional additional component of the secondary circuit between the identification control unit 19 and the constant current source unit 23 provided clock generation unit 29 can be modulated. This clock generating unit 29 with which the LED elements 11 with a frequency of z. B. 1kHz clocked can be operated, can cause an increase in light intensity with certain types of LEDs. It can also be used to modulate the frequency of the output signal emitted by the identification control unit 19 as carrier frequency egg ne from the LED light source 24 to be optically emitted data information. The constant current source unit 23 then activates and deactivates the LED elements 11 of the LED light source as a function of the supplied identification control signal 28 for the purpose of emitting a corresponding identification light signal, for. B. a periodically bright and dark light signal with a characteristic period.

Another output signal 30 of the identification control unit 19 is fed to the DC / DC converter 17 in order to inform the latter about the progress of the identification control signal 28 or the identification light signal to be emitted. The DC / DC converter 17 is designed so that it follows the course of the Kennungssteuersig signal 28 with an implemented switch-off delay of z. B. ten seconds follows. This ensures that the power supply unit 14 , especially the DC / DC converter 17 , does not always have to restart when there are rapid changes between light and dark phases of the identification light signal, but on the other hand no unnecessary idle current consumption of the DC / DC converter 17 in long dark periods occurs.

Overall, it follows from the above description that the one shown Sea lantern comparatively easy to manufacture and operate and a very homogeneous distribution of the emitted light tes with a desired high vertical spread depending on Light intensity z. B. may provide up to 400. About her conventional, not shown light sensor as a dam The lantern is suitable for automatic switches Night operation by this light sensor ensures that the Light source control always with the + 12V supply voltage is applied when the ambient brightness ei falls below a certain, selectable limit. The ge showed lantern can of course be seawater proof, d. H. adequately sealed against the ingress of moisture, to build.

It goes without saying that in addition to the shown further reality The lantern according to the invention is possible for the person skilled in the art are, such lanterns not being used as Seela tern are limited, but also in other areas can replace conventional electric lanterns.

Claims (12)

1. lantern, especially sea lantern, with

• - an electrically controllable light source that can be switched on and off,
  characterized in that
• - The light source is an LED light source ( 10 , 11 ), which consists of a plurality of individual LED elements ( 11 ), which are distributed on the outside of a common, cylindrical, flexible circuit board ( 10 ) angeord net.

2. Lantern according to claim 1, further characterized in that the LED elements ( 11 ) are arranged with a radially extending Abstrahlke gel central axis. 3. Lantern according to claim 1 or 2, further characterized in that the LED light source ( 10 , 11 ) a plurality of individually switchable, each around the circumference of the cylindrical ge bent circuit card ( 10 ) around LED rows ( 12 ₁ , 12 ₂ ,..., 12 ₁₆ ), which follow one another in the direction of the printed circuit board cylinder axis ( 13 ). 4. Lantern according to claim 3, further characterized in that the LED elements ( 11 ) of adjacent LED rows ( 12 _i , 12 _{i + 1} ; i = 1,..., 15) by a predetermined angle in the circumferential direction of the circuit board 10 are arranged offset. 5. Lantern according to one of claims 1 to 4, further characterized by a light source control in a primary circuit and a potential-separated secondary circuit divided by this, the primary circuit a DC / DC converter unit ( 17 ) and the secondary circuit a coupled to it LED elements ( 11 ) driving LED control unit ( 23 , 25 , 26 ). 6. Lantern according to claim 5, further characterized by an identification control unit ( 19 ) for controlling the LED-on control unit ( 23 , 25 , 26 ) such that the LED elements ( 11 ) for emitting an identification light signal in accordance with an identifier on an egg predeterminable identifier. 7. Lantern according to claim 6, further characterized in that between the identification control unit ( 19 ) and the LED control unit ( 23 , 25 , 26 ), a clock generating unit ( 29 ) is provided for the clocked control of the LED elements ( 11 ). 8. Lantern according to claim 6 or 7, further characterized in that the DC / DC converter unit ( 17 ) with the identification control unit ( 19 ) is connected and whose switch-off commands follows with a specifiable switch-off delay. 9. Lantern according to one of claims 5 to 8, further characterized by an error monitoring unit ( 27 ), which che monitors the function of the LED control unit ( 23 , 25 , 26 ) and generates an error message when an error is detected. 10. Lantern according to claim 9, further characterized in that the error monitoring unit ( 27 ) generated error signal ( 22 ) is supplied to a lantern output side, protected against voltage and overcurrent protected semiconductor switching element, which assumes its blocking state in the event of an error. 11. Lantern according to one of claims 1 to 10, further characterized in that

• - This LED light source ( 10 , 11 ) is arranged in the interior of an at least partially transparent upper housing part ( 4 ) which is openably connected to a lower housing part ( 1 ) and
• - A safety shutdown unit ( 18 ) is provided, which senses an opening dismantling of the upper housing part and then the fourth DC / DC converter unit ( 17 ) deactivated.

12. Lantern according to claim 11, further characterized in that the upper housing part ( 4 ) has an opening ( 6 ) on the upper side, which is covered by a heat-conducting cover cap ( 7 ).