Patent Application
20110222567
The invention relates to optical fiber transceiver modules that are implemented as transistor outline (TO)-can header assemblies. More particularly, the invention relates to a TO-can header assembly that has improved heat dissipation characteristics and reduced thermal resistance.
Optical transceiver modules that are implemented as TO-can header assemblies typically include a cylindrical base, known as a header, four or five conductive leads having ends that pass through the header, a laser diode mounted on a mounting surface of the header and connected to the ends of two of the conductive leads, a photodiode mounted on the mounting surface of the header and connected to the ends of two of the other conductive leads, and a cap that is sealed to the header. The cap encases and protects the laser diode, photodiode and other electrical devices (e.g., resistors, capacitors, etc.) mounted on the mounting surface of the header. One or more transparent windows exist in the cap to allow light to be coupled between ends of transmit and receive optical fibers and the laser diode and photodiode, respectively.
An optics system is often also mounted on the mounting surface of the header to direct light between the ends of the transmit optical fiber and the receive optical fiber and the laser diode and photodiode, respectively. The TO-can header assembly is typically mounted on a printed circuit board (PCB) on which other electrical devices are also mounted, such as a transmitter integrated circuit (IC), a receiver IC and a controller IC. The ends of the leads opposite the ends that pass through the header are electrically connected to contacts on the PCB to enable the ICs to communicate with one or more of the active devices (i.e., the laser diode and photodiode) mounted on the mounting surface of the header.
One of the major concerns with TO-can header assemblies is that they have inadequate heat dissipation and thermal resistance characteristics. The laser diode generates a significant amount of heat. If the heat generated by the laser diode is not adequately dissipated, the heat can adversely affect the operations of the laser diode. Therefore, TO-can header assemblies are provided with heat dissipation pathways by which heat generated by the laser diode is moved away from the laser diode. These pathways have a thermal resistance that tends to impede the movement of thermal energy along the pathways. For these reasons, steps are taken to reduce the thermal resistance along these pathways in order to improve the heat dissipation characteristics of the TO-can header assembly.
The header 3 has an upper mounting surface 3a, a generally cylindrical side wall 3b and a lower surface 3c. The generally cylindrical side wall 3b has notches 3d, 3d′ and 3d″ formed therein for mating with complimentarily-shaped mating features (not shown) formed on a chassis (not shown) on which the TO-can header assembly 2 will ultimately be mounted. Heat generated by the laser diode 7 is transferred into the ceramic carrier 6. From the ceramic carrier 6, the heat is transferred into the stem 5. From the stem 5, the heat is transferred into the header 3 where it is spread over the mounting surface 3a of the header 3. The heat that is spread over the mounting surface 3a of the header 3 is then removed through natural convection and/or through thermal conduction into the chassis (not shown) on which the TO-can header assembly 2 is mounted.
One of the disadvantages of the TO-can header assembly 2 and others like it is that the thermal dissipation pathways (from the laser diode 7 through the ceramic carrier 6, from the carrier 6 into the stem 5, and through the stem 5 into the mounting surface 3a of the header 3) are relatively great in length. The relatively great lengths of these pathways cause the header 3 to have a relatively high thermal resistance. The relatively high thermal resistance of the header 3 can adversely affect the performance of the laser diode 7, particularly when it is operating at high operating temperatures and high electrical currents. While a variety of TO-can header assemblies are configured to improve heat dissipation and thermal resistance characteristics, the current designs are inadequate at dissipating heat and/or are not economical in terms of costs. For example, one way to improve the heat dissipation characteristics of the TO-can header assembly shown in
Accordingly, a need exists for a TO-can header assembly that is effective at dissipating heat and that is economical in terms of costs.
The invention is directed to a TO-can header assembly having improved heat dissipation and thermal resistance and a method for dissipating heat in a TO-can header assembly. In accordance with one embodiment, the TO-can header assembly comprises a header, a plurality of electrically conductive leads, a ceramic heat dissipation block, an electrical ground contact pad, an electrical bias contact pad, and a laser diode. The header has an upper mounting surface, a lower surface, and a generally cylindrical side wall that interconnects the upper mounting surface and the lower surface. Each of the electrically conductive leads extends through the header and has a first end and a second end. The ceramic heat dissipation block has at least an upper surface, a lower surface, and at least one mounting surface. The lower surface of the ceramic heat dissipation block is thermally coupled with the upper mounting surface of the header. The electrical ground contact pad is mounted on the mounting surface of the ceramic heat dissipation block and is in abutment with the second end of a first of the electrically conductive leads. The electrical bias contact pad is mounted on the mounting surface of the ceramic heat dissipation block and is in abutment with a second end of a second of the electrically conductive leads. The laser diode is mounted on the mounting surface of the ceramic heat dissipation block. The laser diode has an anode that is electrically coupled to one of the contact pads and a cathode that is electrically coupled to the other of the contact pads. At least a portion of the heat produced by the laser diode during operation of the laser diode passes into the ceramic heat dissipation block and then passes from the ceramic heat dissipation block into the header. The heat that passes into the header spreads through at least a portion of the header.
In accordance with another embodiment, the TO-can header assembly comprises a header, a plurality of electrically conductive leads, a ceramic heat dissipation block, an electrical ground contact pad, an electrical bias contact pad, a laser diode, and an external heat sink block. The header has an upper mounting surface, a lower surface, and a generally cylindrical side wall that interconnects the upper mounting surface and the lower surface. Each of the electrically conductive leads extends through the header and has a first end and a second end. The ceramic heat dissipation block has at least an upper surface, a lower surface, and at least one mounting surface. The lower surface of the ceramic heat dissipation block is thermally coupled with the upper mounting surface of the header. The electrical ground contact pad is mounted on the mounting surface of the ceramic heat dissipation block. The electrical ground contact pad is electrically coupled to a second end of a first one of the electrically conductive leads. The laser diode is mounted on the mounting surface of the ceramic heat dissipation block and has an anode that is electrically coupled to one of the contact pads and a cathode that is electrically coupled to the other of the contact pads. At least a portion of heat produced by the laser diode passes into the ceramic heat dissipation block and then passes from the ceramic heat dissipation block into the header and spreads through at least a portion of the header. The external heat sink device has a heat transfer surface that is in contact with at least a portion of the cylindrical side wall of the header. The heat transfer surface has a shape that is complimentary to the shape of the portion of the cylindrical side wall that is in contact with the heat transfer surface. At least a portion of the heat that passes from the ceramic heat dissipation block into the header and from the header into the external heat sink device where the heat is dissipated.
The method comprises providing a TO-can header assembly having one of the configurations described above and providing a voltage differential between at least the first and second electrically conductive leads to cause the laser diode to be modulated. As the laser diode is modulated, heat is produced by the laser diode. At least a portion of the heat produced by the laser diode passes into the ceramic heat dissipation block and then is passed from the ceramic heat dissipation block into the header.
These and other features and advantages of the invention will become apparent from the following description, drawings and claims.
In accordance with the invention, a TO-can header assembly is provided that has improved heat dissipation and thermal resistance characteristics. The TO-can header assembly includes a relatively large ceramic heat dissipation block that functions as both a carrier for the laser diode and as a heat dissipation device. A relatively large surface area of the ceramic heat dissipation block is in contact with the upper mounting surface of the header, which allows a relatively large amount of heat to quickly pass from the laser diode through the ceramic heat dissipation block and into the upper mounting surface of the header. The heat then quickly spreads through the mounting surface of the header and is at least partially dissipated.
In addition, the cylindrical side wall of the header is smooth, rather than being notched (elimination of notches 3d, 3d′ and 3d″ in
Thus, the large ceramic heat dissipation block mounted on the header, the smooth cylindrical side wall of the header, and the external heat sink device in contacted with the header cooperate with one another to rapidly dissipate heat generated by the laser diode. This rapid dissipation of heat reduces the thermal resistance of the header and ensures that the header is maintained at a temperature that is substantially equal to the temperature of the chassis on which the TO-can header assembly is mounted or the housing in which the TO-can header assembly is housed. Consequently, the laser diode has a longer lifetime and a wider range of operating temperatures than laser diodes that are used in other TO-can header assemblies, such as that shown in
The ceramic heat dissipation block 40 has an electrical ground contact pad 45a and an electrical bias contact pad 45b positioned on the mounting surface 40c thereof. The laser diode 21 is mounted on the mounting surface 40c of the ceramic heat dissipation block 40 such that an anode (not shown) on a bottom portion of the laser diode 21 is in contact with the electrical ground contact pad 45a. A bond wire 22 electrically connects a cathode (not shown) located on a top portion of the laser diode 21 with the electrical bias contact pad 45b. The electrical ground contact pad 45a and the electrical bias contact pad 45b are in abutment with two of the leads 25a and 25e, respectively, to allow a bias voltage differential to be created between the cathode and the anode of the laser diode 21 and varied to electrically modulate the laser diode 21. If the TO-can header assembly 10 is implemented as a transceiver, the assembly 10 may also include a photodiode 23 that is mounted on the header 20. The photodiode 23 has an anode (not shown) and a cathode (not shown) that are connected via bond wires 24 and 26 to leads 25b and 25d, respectively.
The ceramic heat dissipation block 40 is significantly larger than the ceramic carrier 6 shown in
In addition, the heat dissipation characteristics of the TO-can header assembly 10 are further improved by incorporation of the external heat sink device 30 into the assembly 10. At least at the interface where the cylindrical side wall 20b of the header 20 is in contact with the surface 30a of the external heat sink device 30, the cylindrical side wall 20b is smooth rather than notched. The external heat sink device 30 has a surface 30a that is complimentary in shape to the shape of the smooth cylindrical side wall 20b of the header 20. Because of the complimentary shapes of these surfaces, and because of the relatively large area over which these surfaces are in continuous contact with one another, the heat that flows from the ceramic heat dissipation block 40 into the header 20 is rapidly transferred into the external heat sink device 30 where it is dissipated. Some of the heat that flows into the header 20 may be dissipated through convection before it has an opportunity to flow from the header 20 into the external heat sink device 30.
The result of all these components cooperating to dissipate heat is that the header 20 is generally maintained at a temperature that is about the same as the temperature of the chassis or housing (not shown) in which the TO-can header assembly 10 is mounted. Consequently, the laser diode 21 has a longer lifetime and is able to operate over a wider range of operating temperatures than laser diodes that are used in other TO-can header assembly designs, such as that shown in
The embodiments of the invention described above utilize a passive heat dissipation configuration and method.
Like numerals in
During operations, electrical power is provided to the laser diode 21 and the laser diode 21 can be modulated by changing the voltage potential difference between leads 25a and 25e to cause the laser diode 21 to produce a modulated optical signal. During operations, heat produced by the laser diode 21 is transferred via the ceramic heat dissipation block 40 into the header 20. As heat is transferred from the laser diode 21 into the header 20, the temperature of the thermistor 110 increases. If the temperature of the thermistor 110 increases to a particular threshold temperature, the increase in temperature will cause the Peltier heat pump 120 to be activated. When the Peltier heat pump 120 is activated, it pumps heat from the ceramic heat dissipation block 140 into the header 20.
As the Peltier heat pump 120 pumps heat from the ceramic heat dissipation block 140 into the header 20, the thermistor 110 begins to cool. Once the temperature of the thermistor 110 has cooled to a temperature that is below the threshold temperature, the Peltier heat pump 120 is deactivated. As the laser diode 21 continues to operate, the heat it produces causes the temperature of the thermistor 110 to again increase. Once the temperature of the thermistor 110 has reached the threshold temperature, the Peltier heat pump 120 turns on again causing heat to be pumped from the ceramic heat dissipation block 40 into the header 20. This causes the thermistor 110 to cool again until its temperature drops below the threshold temperature.
The foregoing process of the Peltier heat pump 120 being activated and deactivated based on the temperature of the thermistor 110 ensures that the header 20 is maintained at a substantially constant temperature that is approximately equal to the chassis (not shown) to which the assembly 100 is mounted or the housing (not shown) in which the assembly 100 is housed. This, in turn, ensures that the laser diode 21 will have a long lifetime and can operate over a wider range of operating temperatures than that which is possible for laser diodes used in other TO-can header assembly designs, such as that shown in
Another advantage of the TO-can header assemblies 10 and 100 shown in
It should be noted that the invention has been described with reference to a few illustrative, or exemplary, embodiments for the purposes of demonstrating the principles and concepts of the invention. Those of ordinary skill in the art will understand that the invention is not limited to these embodiments. For example, although the ceramic heat dissipation block 40 and the external heat sink device 30 have been described above as having particular shapes and comprising particular materials, other shapes and materials may be used for these components. As another example, the TO-can header assemblies 10 and 100 are not limited to having any particular number of leads and are not limited with respect to the manner in which the leads are electrically coupled to components of the assemblies. As yet another example, although the header 20 is shown as having a smooth cylindrical side wall 20b, the side wall 20b need not be strictly cylindrical in shape or smooth over its entire surface. Rather, the shape of the side wall 20b is generally cylindrical in that there may be variations in its shape (e.g., flanges, tapers, etc.). The surface of the side wall 20b need only be smooth and in continuous contact with the heat transfer surface 30a of the external heat sink device 30 at the interface between the side wall 20b and the heat transfer surface 30a. If these surfaces are not smooth and in continuous contact with each other, then the ability of heat to be adequately transferred between these surfaces may be less than adequate.
As will be understood by persons of ordinary skill in the art, these and other modifications may be made to the embodiments described above with reference to
