DE102012106272A1 - Arrangement of optoelectronic component e.g. LED, has coupling element whose electrical resistance is higher and lower than that of optoelectronic component, so that heat is applied to coupling element by heating resistor - Google Patents

Abstract

The arrangement has contact portions which are in contact with the electrical contact of an optoelectronic component (103). A short circuit failure contact (110) is electrically connected in parallel with the contact portions, and is provided with a voltage-variable heating resistor and a coupling element. The electrical resistance of the coupling element is higher and lower than that of the optoelectronic component, when coupling element is in different operating state, so that heat is applied to the coupling element through heating resistor.

Description

The invention relates to an arrangement for an optoelectronic component and such an arrangement with an optoelectronic component.

In order to operate several components simultaneously with electric current of the same strength, the components can be coupled, for example, in a series connection. Compared to a parallel circuit then plays a possibly different current / voltage characteristics of the components no role and also the series circuit can be operated with higher voltage. Thus, smaller lead cross sections can be used since higher voltages can usually be provided with better efficiency than lower voltages, especially if they come within the range of typical valve threshold voltages, for example 0.7 volts for silicon rectifier diodes. In such series circuits, however, all components are de-energized, even if only one component is defective and has a power interruption.

It is desirable to provide an arrangement which enables a reliable series connection even with a power interruption of a component.

According to one embodiment of the invention, an arrangement for an optoelectronic component comprises a first and a second contact for electrically contacting the optoelectronic component. The arrangement includes a failure short-circuiter. The fail short circuiter is electrically coupled in parallel with the first and second contacts. The short-circuit fault has a voltage-variable heating resistor and a coupling element. In a first operating state, the coupling element has a higher electrical resistance than the electrical resistance of the optoelectronic component. The coupling element has a lower electrical resistance in a second operating state than in the first operating state. The coupling element is displaceable by the heating resistor by introducing heat from the first to the second operating state.

The failure short circuiter is thus connected in parallel with the contacts for the optoelectronic component. As long as electrical current can flow from the first to the second contact, for example through the optoelectronic device coupled to the first and second contacts, the coupling element is in its first operating state. As a result, no current or virtually no current flows through the short-circuit short-circuiter, in particular in comparison to the current flowing through the optoelectronic component.

As soon as the current flow between the first and the second contact is interrupted, for example because the optoelectronic component is defective, a higher voltage flows to the voltage-variable heating resistor, so that it heats up. As a result, the coupling element is heated and placed in its second operating state.

The second operating state is different from the first operating state. In the second operating state, the electrical resistance of the coupling element is reduced, so that a current flow through the short-circuited short-circuiting device is made possible. Thus, in the event of an interruption of the current flow through the component between the contacts, a current flow is nevertheless ensured in the operation, so that in the case of a series connection in which the first and the second contact are incorporated, a failure of all components can be avoided.

According to embodiments, the optoelectronic component comprises an LED and / or a semiconductor laser.

According to embodiments, the heating resistor has a current-voltage characteristic, so that at a predetermined electrical voltage no electric current flows through the heating resistor and is released from a further predetermined electrical voltage, an electric current flow at least a predetermined electric current through the heating resistor. The further predetermined electrical voltage is greater than the predetermined electrical voltage.

Thus, it is possible that in operation with an intact coupled optoelectronic component, when only a small voltage is applied to the heating resistor, a current flow through the heating resistor is avoided. When the current flow between the contacts is interrupted, the voltage at the heating resistor increases and the current flow through the heating resistor is released from a predetermined threshold value for the applied voltage across the heating resistor.

According to embodiments, the coupling element comprises a contact material which is not electrically conductive in the first operating state and can be displaced by heating into the second operating state in which it is electrically conductive. The contact material is each with coupled to the first and second contacts.

For example, the contact material comprises a mixture of a metal and a flux or a metal alloy and a flux. The metal or metal alloy and flux are so mixed or layered in their initial state that the contact material is not continuously electrically conductive between the first and second contacts. By heating by introducing heat through the heating resistor, the metal forms power line paths such that the contact material is electrically conductive between the first and second contacts. Thus, the contact material is inexpensive and the short-circuit shorts can be realized in a small space.

According to further embodiments, the heating resistor is made porous and the coupling element at least partially disposed within the heating resistor. For example, the heating resistor has a flux and Metallevampfung. By heating, the evaporated metal melts and forms an electrically conductive current path through the heating resistor. This makes it possible to further reduce the space requirement.

According to further embodiments, the coupling element comprises a mechanically biased electrical conductor, which is electrically coupled to the first contact. The coupling element further comprises a thermoplastic material coupled to each of the heating resistor and the biased electrical conductor so that the biased electrical conductor is electrically isolated from the second contact in the first operating state and electrically electrically connected to the second contact in the second operating state is coupled. The thermoplastic material is coupled to the heating resistor so that it is deformable by the heating resistor. The electrical conductor is displaceable by deformation of the thermoplastic material from the first to the second operating state.

The mechanically biased electrical conductor is held in the first operating state by the thermoplastic material spaced from the second contact. After heating, the thermoplastic material is deformable and the mechanically biased conductor comes into contact with the second contact. The electrical conductor is in particular movable by the spring force of the bias in the direction of the second contact. As soon as the electrical conductor is mechanically and electrically coupled to the second contact, a current flow from the first contact via the electrical conductor to the second contact is made possible. The thermoplastic material is, for example, a fusible metal, a metal alloy or a plastic.

According to further embodiments, the arrangement comprises at least two further contacts for a further optoelectronic component, which are arranged electrically in series with the first and the second contact and are electrically coupled in parallel with the short-circuited short-circuiter. This makes it possible, during operation, to couple two optoelectronic components with a single short-circuit short-circuiter, so that it is not necessary to provide exactly one short-circuit short-circuiter for each optoelectronic component. As a result, the arrangement is inexpensive to implement.

An arrangement with an optoelectronic component comprises such an arrangement and an optoelectronic component which is coupled to the first and the second contact. Due to the short-circuit short-circuiting device, a current flow between the first and the second contact is possible if the optoelectronic component is defective and does not permit a current flow between the first and the second contact.

The same, similar and equivalent elements can be provided with the same reference numerals. The elements and their proportions to each other are basically not to be considered as true to scale.

Show it:

1A and 1B a schematic representation of an arrangement according to embodiments,

2 1 is a schematic representation of a supply device with a basic current / voltage characteristic according to an embodiment,

3A a schematic representation of an arrangement according to an embodiment,

3B a current-voltage characteristic of a heating resistor according to an embodiment,

4A a schematic representation of an arrangement according to further embodiments,

4B a current-voltage characteristic of a heating resistor according to another embodiment,

5 an interconnection of a plurality of optoelectronic components and short-circuit terminators according to an embodiment,

6 1 is a schematic representation of a short-circuiting short-circuiter according to an embodiment,

7 1 is a schematic representation of a short-circuiting short-circuiting device according to one embodiment,

8A and 8B a schematic representation of a short-circuiting short-circuit according to a Embodiment in the first and in the second operating state,

9 a schematic representation of an arrangement according to an embodiment.

1A shows a plurality of optoelectronic devices 103 , The optoelectronic components 103 are connected in series. The optoelectronic components 103 are with a supply device 106 coupled, which are the series-connected optoelectronic components 103 supplied with an electric current.

To every optoelectronic component 103 is a failure short circuiter 110 connected in parallel. The failure short-circuiter 110 is at a voltage applied in normal operation operating voltage U _B high impedance. In the event of a faulty conductor interruption of one of the optoelectronic components 103 increases the voltage at the associated parallel shutdown short circuiter 110 up to a switching voltage U _S. Then the parallel short-circuited short-circuiter takes over 110 the operating current. Thus, the power supply of the remaining optoelectronic devices remains 103 receive.

According to embodiments, the outage shortcuts are 110 each directly into the optoelectronic component 103 incorporated in a chip unit.

As in 1B All shortage shorts are shown 110 according to embodiments as a separate device 107 connected in series. The device 107 is via current bridges so with the series connection of the plurality of optoelectronic components 103 electrically coupled, that ever a failure short circuiter 110 the majority of failure short-circuiters 110 the device 107 in parallel with one of the optoelectronic components 103 is coupled.

2 shows a supply device 106 according to an embodiment. The supply device 106 is, for example, a DC power supply with a predetermined characteristic, current and voltage limited. The supply device 106 is arranged to supply a plurality of optoelectronic components with electric current and electrical voltage.

3A shows an arrangement 100 according to one embodiment.

The order 100 has a first and a second contact 101 and 102 on. The contacts are designed for mechanical and electrical coupling with the optoelectronic component 103 and serve in operation to power the optoelectronic device 103 ,

The order 100 also includes the short-circuit short-circuiter 110 , The failure short-circuiter 110 comprises a coupling element 112 and a voltage-dependent heating resistor 111 , The heating resistor 111 is electrically parallel with the contacts 101 and 102 coupled. The heating resistor 111 according to embodiments comprises a varistor, for example doped ZnO.

The coupling element 112 has at least two different operating states. In the first operating state is the coupling element 112 high impedance. The coupling element 112 is not or almost not electrically conductive in the first operating state. In the second operating state is the coupling element 112 electrically conductive. The coupling element 112 is designed so that it can change from the first to the second operating state. The change from the first to the second operating state takes place by heating the coupling element 112 , For example, the change between the first and the second operating state takes place at a temperature of the coupling element 112 greater than 400 ° Celsius. According to further embodiments, the change between the first and the second operating state takes place at a temperature of the coupling element 112 greater than 500 degrees Celsius. According to embodiments, the coupling element 112 irreversibly trained. A change from the second and to the first operating state is not possible according to exemplary embodiments.

The heating resistor 111 is designed such that it starts at the predetermined applied voltage U _S ( 3B ) a current flow through the heating resistor 111 releases and heats up. The heating resistor 111 is arranged to heat at least to the temperature at which the coupling element 112 changes from its first to its second operating state. This is the heating resistor 111 set up, the coupling element 112 from its first operating state to its second operating state.

3B shows a current-voltage characteristic of the heating resistor 111 according to one embodiment. The voltage U _B corresponds to the voltage of the normally functioning optoelectronic component 103 operational.

The heating resistor 111 is designed so that at an applied voltage U _B no or only a very small current through the heating resistor 111 flows. Increases the applied voltage up to the predetermined value U _S , for example, in a defect of optoelectronic component 103 , an electric current I _{B flows} through the heating resistor 111 , This heats up the heating resistor 111 and thereby displaces the coupling element 112 in the second operating state. In the second operating state is the coupling element 112 electrically conductive and forms an electrical coupling of the first contact 101 with the second contact 102 out. As a result, the voltage drops at the heating resistor during operation 111 again, so that it cools down again.

For example, the heating resistor comprises 111 a varistor material, in particular a ZnO varistor material. With a suitable design of contact spacing and grain size of the varistor material, the predetermined resistance value and the predetermined threshold voltage can be adjusted simultaneously. In particular, it is possible to set the resistance value and the threshold voltage simultaneously as optimally as possible.

4A shows an arrangement 100 according to further embodiments. In contrast to the embodiment of 3A includes the voltage variable heating resistor 111 an ohmic resistance 119 and a non-linear component 120 , The ohmic resistance 119 and the non-linear component 120 are electrically connected in series. The non-linear component comprises, for example, a subdimensional Zener diode arrangement or avalanche diode arrangement which safely breaks through when the operating current is taken over. The heating resistor has, according to embodiments, a current-voltage characteristic as in FIG 4B shown on.

In the event of a failure of the optoelectronic component and a voltage increase above the predetermined value U _S , a current transfer occurs due to the ohmic resistance 119 in series with the non-linear component 120 , This is followed by the breakthrough of the non-linear component 120 and the full voltage drop across the ohmic resistor 119 , causing it to heat up. This is how the coupling element becomes 112 heated so that this one electrical coupling of the two contacts 101 . 102 manufactures.

The current-voltage characteristics according to the illustrated embodiments of 3B respectively 4B are voltage limiting in both polarities. Thus, the default short-circuiter acts 110 also as ESD protection against current pulses contrary to the operating current direction.

5 shows an arrangement of a plurality of optoelectronic components 103 and failure short-circuiters 110 according to one embodiment. The optoelectronic components 103 are on a carrier 108 electrically connected in series. Each optoelectronic device is a failure short circuiter 110 assigned.

As in 6 shown in detail, is in the area of the failure short circuiter 110 reduces the cross section of the power line to the optoelectronic device. Thus, a small space for the short-circuit short-circuiter 110 possible. The smaller the installation space of the short-circuit short-circuiter 110 So the smaller its volume, the faster the coupling element 112 through the heating resistor 111 heatable.

For example, below a voltage of U _S = 4 V by the short-circuit short circuiter 110 essentially no electricity flowing. In case of failure of the optoelectronic device 103 the voltage on the short-circuit shorts increases 110 on at least U _S with an almost constant current flow of, for example, I _B = 0.1 A via the short-circuit short-circuiter 110 , Now, this power P = I _B × U _S over a time T _S of less than 1 sec and thus a loss heat energy input W = P × T _S melt a mass M _K melt. The effect of typical soldering temperatures of, for example, about 330 ° Celsius over a period of a few seconds, the coupling element 112 do not put in the second operating state. It follows that the temperature T _K at which the coupling element 112 is placed in the second operating state, must be above the soldering temperature, for example, about 500 ° Celsius. It follows that the heat-affected mass M _{K is} not greater than M _K = W _K : dT _K × C _K = 0.4 W _S : (550 K × 0.5 W _S : G _K ) = 0.0015 g. This corresponds at usual densities of about 4 g / cm ^{3 to} a limiting heating volume of 0.36 mm ³ .

6 shows a view of a short-circuit shorts 110 according to one embodiment. In 7 a corresponding sectional view is shown.

In embodiments according to 6 and 7 includes the coupling element 112 a contact material 113 that with the first and the second contact 101 and 102 is coupled. The coupling takes place in each case by means of a flux layer 117 in the first operating state, the contact material 113 and the contacts 101 and 102 each electrically isolated. The heating resistor 111 is electrically connected to the first and second contacts 101 and 102 coupled. The heating resistor 111 is like that with the contact material 113 and the flux 117 coupled that heat well from the heating resistor 111 on the contact material 113 and the flux 117 is transferable.

On one of the contacts 101 and 102 opposite side of the heating resistor 111 and the contact material 113 is optional thermal insulation 118 arranged. The thermal insulation 118 reduces heat transfer from the shortage shortseat 110 on the carrier 108 , By the heat insulation 118 the volume to be heated is limited.

In operation is an intact coupled optoelectronic device 103 the electrical resistance of the flux 117 and the contact material 113 larger than that of the optoelectronic component. Therefore, no or only a very small electric current flows through the flux 117 and the contact material 113 , In the event of a failure of the optoelectronic component, the electrical voltage which rises across the heating resistor increases 111 is applied. This heats up and heats the flux 117 and the contact material 113 on. As a result, electrically conductive paths through the flux and the contact material 113 educated. Thus, a good ohmic contact between the contacts 101 and 102 by means of the failure short-circuiter 110 educated. For example, the electrically conductive paths are formed on the basis of a capillary effect.

According to further embodiments, the arrangement of the heating resistor 111 and the contact material 113 with the flux 117 compared to the arrangement as in 7 shown reversed. Accordingly, the heating resistor 111 arranged outside and surrounds the contact material 113 ,

8A and 8B show a failure short circuiter 110 according to a further embodiment.

8A shows the failure short-circuiter 110 in the first operating state of the coupling element 112 that in the embodiment shown a thermoplastic material 115 includes. The thermoplastic material 115 is fixed up to a first predetermined temperature and above the predetermined temperature deformable. According to embodiments, the thermoplastic material comprises 115 a fusible metal. A fusible metal allows a fast phase transition at a defined temperature.

The failure short-circuiter 110 includes an electrical conductor 114 , The electrical conductor 114 is in particular an elongated conductor wire. The electrical conductor 114 is with the first contact 101 electrically coupled. The leader 114 is in its initial state spaced from the second contact 102 arranged and has no common contact surface with the contact 102 on. The leader 114 is not electric with the contact 102 coupled. The leader 114 is so with the contact 101 and the carrier 108 coupled, that he has a mechanical bias in the direction of contact 102 having. On the ladder 114 a force acts in the direction of the contact 102 ,

The thermoplastic material 115 is like that with the electrical conductor 114 coupled that the conductor 114 spaced to the contact 102 is arranged. The thermoplastic material 115 acts against the spring force of the conductor 114 , The thermoplastic material 115 is also with the heating resistor 114 coupled so that heat is good from the heating resistor 114 on the thermoplastic material 115 is transferable. The heating resistor 111 is electrical with the contacts 101 and 102 coupled.

8B shows the failure short-circuiter 110 out 8A After having an electrical connection between the contacts 101 and 102 by the failure short-circuiter 110 was produced.

Due to the increased applied voltage U _S to the heating resistor 111 became the thermoplastic material 115 deformable, so that there is no sufficient counterforce against the spring force of the conductor 114 can exercise. This will cause the leader 114 due to the bias in mechanical and electrical contact with the contact 102 , allowing a current flow from the contact 101 over the ladder 114 to the contact 102 is possible. Thus, a mechanical failure short-circuiter is formed.

9 shows a further embodiment of the arrangement 100 , According to the embodiment of the 9 are four contacts each 101 . 102 and 104 . 105 for coupling with two optoelectronic devices with a single common short circuit shorts 110 coupled. The failure short-circuiter 110 allows an electrical coupling of the contact 101 with the contact 105 if one of the two optoelectronic devices, so either the optoelectronic device, with the contacts 101 and 102 is coupled, or the optoelectronic device with the contacts 104 and 105 is coupled, is defective. Accordingly, according to further embodiments, a single failure short circuiter 110 for each three or more than three, for example four, optoelectronic components arranged. Thus, a cost-effective series connection of several components is realized with short-circuit shorts.

The failure short-circuiter 110 works without relay winding and without complicated mechanics. The failure short-circuiter 110 is suitable for the operating currents to be switched by microstructuring feasible, for example as an SMD component or directly on the carrier 108 , The failure short-circuiter 110 includes the heating resistor 111 and the coupling element 112 , If only one heating resistor were provided in order to limit the voltage across the defective optoelectronic component and to maintain the current flow of the series connection, this heating resistor would have to be designed for significantly higher powers in continuous operation than the power loss of the optoelectronic component to be protected. The voltage drop at operating current is higher than the operating voltage of the optoelectronic device to be protected and the power output by light emission is eliminated in the heating resistor.

Due to the fact that according to the invention also the coupling element 112 is provided, the heating resistor 111 only trigger the short circuit of the thermally coupled coupling element. The heating resistor burns in accordance with embodiments for a short time, so that the current flow is interrupted for a short time, wherein the coupling element 112 sufficiently fast, for example <0.1 seconds, responds and changes its operating state, so that the coupling element 112 takes over the operating current. As the voltage drop, for example, << 0.1V, on the coupling element 112 orders of magnitude smaller than the typical operating voltage, even with a small dimensioning hardly dissipates power loss, except in the short moment of irreversible short-circuiting. However, this leads through the associated additional heating positively feedback to accelerate the short circuit process.

Claims (14)

Arrangement for an optoelectronic component, comprising: - a first ( 101 ) and a second ( 102 ) Contact for electrical contacting of the optoelectronic component ( 103 ), - a short-circuit short-circuiter ( 110 ), which is electrically parallel with the first ( 101 ) and the second ( 102 ) Contact, wherein the short-circuit short circuiter ( 110 ) a voltage variable heating resistor ( 111 ) and a coupling element ( 112 ), wherein the coupling element ( 112 ) has a higher electrical resistance in a first operating state than the electrical resistance of the optoelectronic component ( 103 ), and in a second operating state has a lower electrical resistance than in the first operating state, and wherein the coupling element ( 112 ) by the heating resistor ( 111 ) is displaceable by introducing heat from the first to the second operating state. Arrangement according to Claim 1, in which the heating resistor ( 111 ) has a current-voltage characteristic, so that at a predetermined electrical voltage (U _B ) no electric current flows through the heating resistor and from a further predetermined electrical voltage (U _S ) an electric current flow of at least one predetermined electric current through the heating resistor ( 111 ) is released, wherein the further predetermined electrical voltage (U _S ) is greater than the predetermined electrical voltage (U _B ). Arrangement according to Claim 1 or 2, in which the coupling element ( 112 ) comprises: - a contact material ( 113 ) which is not electrically conductive in the first operating state and can be displaced by heating into the second operating state in which the contact material ( 113 ) is electrically conductive, wherein the contact material ( 113 ) each with the first ( 101 ) and the second ( 102 ) Contact is coupled. Arrangement according to Claim 3, in which the contact material ( 113 ) comprises a mixture of a metal and a flux or a mixture of a metal alloy and a flux. Arrangement according to claim 3 or 4, wherein the heating resistor ( 111 ) is porous and the coupling element ( 112 ) at least partially within the heating resistor ( 111 ) is arranged. Arrangement according to Claim 1 or 2, in which the coupling element ( 112 ) comprises: - a mechanically biased electrical conductor ( 114 ), the first contact ( 101 ) is electrically coupled, - a thermoplastic material ( 115 ), each with the heating resistor ( 111 ) and with the prestressed electrical conductor ( 114 ), so that the biased electrical conductor ( 114 ) in the first operating state electrically isolated from the second contact ( 102 ) and in the second operating state with the second contact ( 102 ) is electrically coupled, wherein the thermoplastic material ( 115 ) so with the heating resistor ( 111 ) that the thermoplastic material ( 115 ) by radiating heat of the heating resistor ( 111 ) is deformable, and the electrical conductor ( 114 ) by deformation of the thermoplastic material ( 115 ) is displaceable from the first to the second operating state. Arrangement according to Claim 6, in which the thermoplastic material ( 115 ) comprises a fusible metal or a fusible metal alloy. Arrangement according to one of Claims 1 to 7, in which the heating resistor ( 111 ) a varistor ceramic ( 116 ). Arrangement according to one of claims 1 to 8, wherein the heating resistor ( 111 ) a resistor ( 119 ) and a nonlinear component ( 120 ) electrically connected in series. Arrangement according to one of claims 1 to 9, comprising - at least two further contacts ( 104 . 105 ) for a further optoelectronic component ( 103 ) electrically connected in series with the first ( 101 ) and the second ( 102 ) Are arranged in contact with each other and electrically in parallel with the short-circuit 110 ) are coupled. Arrangement according to one of Claims 1 to 10, in which the short-circuiting short-circuiter ( 110 ) is designed as an SMD component. Arrangement according to one of claims 1 to 11, wherein the coupling element ( 112 ) is designed so that it changes at a temperature of greater than 500 ° C from the first to the second operating state. Arrangement according to one of Claims 1 to 12, in which the short-circuiting short-circuiter ( 110 ) has a volume of less than 0.4 square millimeters. Arrangement with an optoelectronic component, comprising: an arrangement according to one of Claims 1 to 13, an optoelectronic component ( 103 ), that with the first ( 101 ) and the second ( 102 ) Contact is coupled.

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