Source: http://www.freepatentsonline.com/y2016/0360646.html
Timestamp: 2018-06-24 01:52:52
Document Index: 536663072

Matched Legal Cases: ['art) 7', 'art 5', 'art 7', 'art 5', 'art 7', 'arts 19', 'arts 19', 'arts 19', 'arts 19', 'arts 19', 'arts 19', 'arts 19', 'arts 11']

COOLING OF ELECTRONIC EQUIPMENT - ABB TECHNOLOGY LTD
Eriksson, Rolf (Västerås, SE)
15/101288
Download PDF 20160360646 PDF help
JP2003086979A 2003-03-20
The invention relates to cooling of electronic equipment, and in particular to an electronics module comprising a thermally conductive panel, an arrangement comprising such an electronics module, and a method for providing such an electronics module.
In general terms, input/output (I/O) modules are interface electronics where data is transferred to accomplish a function. I/O modules may be arranged to receive input data from sensors, transducers, controllers, etc. and send output data to other devices. In general terms, I/O modules comprise I/O logics (e.g., to provide data transfer between a central processing unit (CPU) and the I/O module), data lines (e.g., to provide data transfer between a system bus and the I/O module) and input/output interfaces (e.g., to control device operation). I/O modules may provide functions related to any of control and timing, processor communications, device communications, data buffering, and error detection. The I/O module may have data buffering capability to remove mismatch between speed of peripherals and CPU, and in built error detector mechanism for checking mechanical and communicational errors.
The I/O module comprises electronic equipment. The electronic equipment may comprise analog I/O modules, digital I/O modules, or any combination thereof. The digital I/O modules may have digital I/O circuits that interface to on/off sensors such as pushbuttons and limit switches and on/off actuators such as motor starters, pilot lights and actuators. The analog I/O modules may perform required analog to digital and digital to analog conversions to directly interface analog signals to data table values.
Consider the I/O module symbolized by the arrangement 1a in FIG. 1a. The arrangement 1consists mainly of a base plate 2, a number of field terminal blocks (FTBs) 3, and a corresponding number of electronics modules. The electronics modules 4 may be signal conditioning modules (SCMs). The FTBs 3 comprises screw clamps for connections of cables between remote field devices and the I/O module symbolized by the arrangement la. In the arrangement 1a of FIG. 1a there are 16 FTBs 3 and 16 electronics modules 4. Each electronics module 4 comprises a printed circuit board (PCB) assembly comprising electronic equipment for signal conditioning. The base plate 2 is a carrier of the electronics modules 4 and the FTBs 3 and likewise acts as a holder device for the I/O module symbolized by the arrangement la.
One requirement for an I/O module may be to have a compact design, for example in order to allow many electronics modules in a cabinet. One requirement for an I/O module may be to have high reliability and long life time. One requirement for an I/O module may be to have resistance to high ambient temperature. It may be a challenging to combine these requirements since the electronics equipment in the electronics modules dissipate power which generates heat. More particularly, as noted above, the electronics modules contain PCBs with electronic components. The electronic components produce an amount of heat that has to be kept as low as possible to reach high reliability and long life time for the components on the PCB, although the ambient temperature is high.
Hence there is a need for cooling of electronic equipment.
An object of embodiments herein is to provide mechanisms for cooling of electronic equipment.
According to a first aspect there is presented an electronics module. The electronics module comprises a circuit board. The circuit board comprises electronic equipment. The electronics module comprises a housing. The housing encloses the circuit board. The electronics module comprises a thermally conductive panel. The thermally conductive panel at least partly covers at least two opposite side surfaces of the housing.
Advantageously, the electronics module provides cooling of electronic equipment.
Advantageously, the electronics module is allowed to be of compact design and thus applicable when the space is limited.
Advantageously, the electronics module enables life time of the electronic equipment to be prolonged.
For example, the electronics module efficiently reduces the temperature caused by heat generating electronic equipment.
Advantageously, the electronics module is cost effective.
According to a second aspect there is presented an arrangement. The arrangement comprises a base plate. The arrangement comprises at least two field terminal blocks. The at least two field terminal blocks are adjacently stacked on the base plate. Each one of the at least two field terminal blocks comprises an electronics module according to the first aspect.
According to a third aspect there is presented a method for providing an electronics module. The method comprises providing a circuit board. The circuit board comprises electronic equipment. The method comprises enclosing the circuit board in a housing. The method comprises slipping a thermally conductive panel over the housing. The thermally conductive panel at least partly covers at least two opposite side surfaces of the housing. An electronics module is thereby provided.
It is to be noted that any feature of the first, second and third aspects may be applied to any other aspect, wherever appropriate. Likewise, any advantage of the first aspect may equally apply to the second, and/or third aspect, respectively, and vice versa. Other objectives, features and advantages of the enclosed embodiments will be apparent from the following detailed disclosure, from the attached dependent claims as well as from the drawings.
FIGS. 1a, and 1b schematically illustrate arrangements according to prior art;
FIG. 2 schematically illustrates an electronics module according to prior art;
FIG. 3 schematically illustrates an electronics module according to an embodiment;
FIGS. 4a, 4b, 4c, and 4d schematically illustrate thermally conductive panels according to embodiments;
FIGS. 5 schematically illustrates an arrangement according to an embodiment;
FIG. 6 shows simulation results of power dissipation as a function of temperature rise for different electronics modules; and
FIGS. 1a, and 1b schematically illustrate known arrangements 1a, 1b for input/output (I/O) systems. The arrangements 1a, 1b comprise a base plate 2. A plurality of field terminal blocks (FTBs) 3 are stacked adjacently on the base plate 2. Each one of the FTBs comprises an electronics module 4. In the arrangement 1b of FIG. 1b one such electronics module 4 has been removed from the stack of FTBs.
FIG. 2 schematically illustrates a disassembled, known, electronics module 4. The electronics module 4 comprises a circuit board 6. The circuit board 6 comprises electronic equipment. The circuit board 6 is enclosed by a housing 5, 7 having a first part (such as an upper half) 5 and a second part (such as a bottom part) 7. The housing may be made of plastic.
The electronic equipment may be provided as a printed circuit board (PCB). The electronic equipment may be arranged to provide signal conditioning. The electronics module 4 may thus be a signal conditioning module. In general terms, signal conditioning involves manipulating an analog signal in such a way that it meets requirements of a next processing stage. One common use is in analog-to-digital converters (ADCs). In control engineering applications, it is common to have a sensing stage (which comprises at least one sensor) producing a sensor signal, a signal conditioning stage (where amplification of the sensor signal may be performed) and a processing stage (commonly performed out by an ADC and a micro-controller). Operational amplifiers (Op-Amps) are commonly employed to carry out the amplification of the sensor signal in the signal conditioning stage. Signal conditioning may include amplification, filtering, converting, range matching, isolation and any other processes required to make the sensor signal suitable for processing after conditioning. Types of devices that use signal conditioning include, but are not limited to, signal filters, instrument amplifiers, sample-and-hold amplifiers, isolation amplifiers, signal isolators, multiplexers, bridge conditioners, analog-to-digital converters, digital-to-analog converters, frequency converters or translators, voltage converters or inverters, frequency-to-voltage converters, voltage-to-frequency converters, current-to-voltage converters, current loop converters, and charge converters.
The electronic equipment produces an amount of heat that has to be kept as low as possible to reach high reliability and long life time for the components on the circuit board 6 although the ambient temperature is high. During operation of the electronics module 4 heat is thus generated by the electronic equipment of the circuit board 6.
One object of embodiments presented herein is to provide improved mechanism for cooling of electronic equipment provided in the electronics module. The present invention addresses this object by providing the electronics module with a thermally conductive panel. According to one particular aspect there is proposed to attach individual thermally conductive panels to cover the sides and the front of each electronics module.
FIG. 3 schematically illustrates an electronics module 8 according to an embodiment. The electronics module 8 comprises a circuit board 6 (as illustrated in FIG. 2; not seen in FIG. 3). The circuit board 6 comprises electronic equipment. The electronics module 8 further comprises a housing 5, 7. The housing may have a first part 5 and a second part 7. Together the first part 5 of the housing and the second part 7 of the housing enclose the circuit board 6, and hence also enclose the electronic equipment. When in use the electronic equipment of the circuit board 6 generates heat. The electronics module 8 therefore comprises a thermally conductive panel 9a. The thermally conductive panel 9a is provided to at least partly cover at least two opposite side surfaces of the housing 5, 7. The thermally conductive panel 9a thereby acts as a cooling panel for the electronics module 8. The thermally conductive panel 9a may be slipped over the housing 5, 7, as indicated by the dashed arrow 10 in FIG. 3.
In general terms, the thermally conductive panel 9a may be provided in different shapes, forms, and sizes, whilst still being arranged to at least partly cover at least two opposite side surfaces of the housing 5, 7.
For example, the thermally conductive panel may be designed as a U-shaped cover which may be threaded over the housing 5, 7 from the front side of the housing 5, 7 (i.e., the side of the housing 5, 7 facing away from the FTB 3 when coupled thereto). The top part of Fig 3 illustrates such a thermally conductive panel 9a. Hence, according to an embodiment the thermally conductive panel 9a comprises two parallel long side walls 11, 12 and one short side wall 13. The two parallel long side walls 11, 12 extend transversely from the short side wall 13. Each one of the two parallel long side walls 11, 12 at least partly covers a respective one of the at least two opposite side surfaces of the housing 5, 7.
FIGS. 4a, 4b, 4c, and 4d schematically illustrate thermally conductive panels 9b, 9c, 9d, and 9e, respectively, according to further embodiments.
For example, the thermally conductive panel may be provided with side walls, top walls, gable wall, and an open bottom part. The thermally conductive panel may then be slipped on to the housing 5, 7 from the front side of the housing 5, 7. FIG. 4a illustrates such a thermally conductive panel 9b. Hence, according to an embodiment the thermally conductive panel 9a comprises two parallel long side walls 11, 12, one short side wall 13, and two parallel gable walls 17, 18. The two parallel long side walls 11, 12 extend transversely from the short side wall 13. The two parallel gable walls 17, 18 extend from the short side wall 13 between the two parallel long side walls 11, 12.
For example, the thermally conductive panel may be provided as two covers slipped on to the housing 5, 7 from the gables of the housing 5, 7. Each cover may be provided with a short side wall and a gable wall. FIG. 4a illustrates such a thermally conductive panel 9b. Thus, in relation to the thermally conductive panel 9b of FIG. 4a the thermally conductive panel 9c of FIG. 4b may be regarded as divided into two parts 19, 20. Hence, according to an embodiment the thermally conductive panel 9c is divided into two parts 19, 20 along a cut through the short side wall 13 and the two parallel long side walls 11, 12. The two parts 19, 20 may be fastened to each other. Hence, the thermally conductive panel 9c may be provided with engaging means 21, 22. Particularly, according to an embodiment each one of the two parts 19, 20 comprises engaging means 21, 22 for engaging with the other of the two parts 19, 20. Alternatively the two parts 19, 20 are provided to fit tightly over the housing 5, 7. The tight fit may thus prevent the two parts 19, 20 from unintentionally slipping off the housing 5, 7.
For example, the thermally conductive panel may be provided as two L-formed side plates which are attached to the sides of the housing 5, 7. FIG. 4c illustrates such a thermally conductive panel 9d. Hence, according to an embodiment the thermally conductive panel 9d comprises two parallel L-shaped walls 11, 12. Each one of the two parallel L-shaped walls 11, 12 at least partly covers a respective one of the at least two opposite side surfaces of the housing 5, 7 and thereby at least partly covers a short side of the housing 5, 7. The two parallel L-shaped walls 11, 12 may allow a gap 15 to be formed between the respective short sides of the two parallel L-shaped walls 11, 12 when attached to the housing 5, 7.
For example, the thermally conductive panel may be provided with handles. FIG. 4d illustrates such a thermally conductive panel 9e. For example, the thermally conductive panel 9e may be of a U-shaped cover comprising side parts 11, 12 and where the bottom of the U (i.e., the short side wall 13) is formed as handles usable for retracting the electronics module 8 from the FTB 3. Hence, according to an embodiment the thermally conductive panel 9e comprises gripping means 14 for engaging with the housing 5, 7. The gripping means 14 may be provided on at least one gable side of the thermally conductive panel 9e. Although the thermally conductive panel 9e has a U-shape, any of the thermally conductive panels 9a, 9b, 9c, and 9d may comprise gripping means 14.
Further features of the above disclosed electronics module 8, and particularly the above disclosed thermally conductive panel 9a 9b, 9c, 9d, 9e will now be disclosed.
The thermally conductive panel 9a 9b, 9c, 9d, 9e may be made of a metal. For example, the thermally conductive panel 9a 9b, 9c, 9d, 9e may be made of a metal which has good thermal conductivity such as aluminium or copper. Thus, according to one embodiment the thermally conductive panel 9a 9b, 9c, 9d, 9e is made from metal.
The thermal properties of the thermally conductive panel 9a 9b, 9c, 9d, 9e may be improved by providing a surface treatment of the thermally conductive panel 9a 9b, 9c, 9d, 9e. For example, a black anodic oxide film may be provided on the thermally conductive panel 9a 9b, 9c, 9d, 9e. Thus, according to an embodiment the thermally conductive panel 9a 9b, 9c, 9d, 9e on its surfaces facing away from the housing 5, 7 is provided with a black anodic oxide film.
The thermally conductive panel 9a 9b, 9c, 9d, 9e may be of metal as well as being provided with a black anodic oxide film.
The electronics module 8 may be a signal conditioning module (SCM).
FIG. 5 schematically illustrates an arrangement is according to an embodiment. The arrangement is may be an I/O module. The arrangement is comprises a base plate 2. The arrangement is further comprises at least two field terminal blocks 3. The at least two field terminal blocks 3 are stacked adjacently on the base plate 2. Each one of the at least two field terminal blocks 3 comprises an electronics module 8 comprises a thermally conductive panel 9a, 9b, 9c, 9d, 9e as disclosed herein. The herein disclosed thermally conductive panel 9a 9b, 9c, 9d, 9e may thus be suitable for providing heat distribution and cooling when a group of electronics modules 8 are mounted close together, such as on adjacently stacked terminal blocks 3.
FIG. 7 is a flowchart of methods for providing an electronics module 8 according to embodiments. The method comprises, in a step S102, providing a circuit board 6. The circuit board 6 comprises electronic equipment. The method comprises, in a step S104, enclosing the circuit board 6 in a housing 5, 7. The method comprises, in a step S106, slipping a thermally conductive panel 9a 9b, 9c, 9d, 9e over the housing 5, 7 and thereby provide the electronics module 8. The thermally conductive panel 9a 9b, 9c, 9d, 9e at least partly covers at least two opposite side surfaces of the housing 5, 7.
According to an embodiment the method further comprises, in an optional step S108, providing a base plate 2. According to an embodiment the method further comprises, in an optional step S110, adjacently stacking at least two field terminal blocks 3 on the base plate 2. Each one of the at least two field terminal blocks 3 comprises an electronics module 9a 9b, 9c, 9d, 9e as provided in steps S102, S104, and S106.
Measurements indicate that the disclosed thermally conductive panel 9a yields significant reduction of the temperature inside the electronics module 8. Measurements were performed with 16 electronics modules 8 placed vertically in a stack of FTBs 3 on a base plate 2 as shown in FIG. 5. All of the electronics modules 8 were first provided with individual thermally conductive panel 9a. The thermally conductive panel 9a was made of a black anodized aluminium plate with a thickness of 0.5 mm. The measurements were repeated for electronics modules 4 without any thermally conductive panel 9a. During the measurements temperature sensors were placed inside all of the electronics modules 4, 8. The temperature sensors were placed close to heat-producing electronic equipment of the circuit boards 6. Temperature sensors were also place outside the stack of the electronics modules 4, 8 in order for the ambient temperature to be measured.
Before the measurements started all of the electronics modules 4, 8 were powered equally until all temperatures were stable. Measurements were made with thermally conductive panels 9a respectively without thermally conductive panels 9a and with power dissipations from about 200 mW to about 800 mW in each electronics module 4, 8.
Measurements made without any thermally conductive panels 9a and about 800 mW per electronics module 4 gave a difference of about 51° C. between ambient temperature and the temperature inside the warmest electronics module 4 in the stack.
Measurements made with thermally conductive panels 9a and about 800 mW per electronics module 8 gave a difference of about 40° C. between ambient temperature and the temperature inside the warmest electronics module 8 in the stack.
Hence, the disclosed thermally conductive panel 9a reduces the temperature of about 11° C. with 800 mW power dissipation. Results of the measurements are provided in FIG. 6 which compares the power dissipation per electronics module 4, 8 as function of temperature rise for electronics modules 8 with thermally conductive panels 9a and electronics modules 4 without thermally conductive panels 9a respectively.
For example, although the herein disclosed electronics module 8 has been described in the context of an I/O module, the electronics module 8 may be used for other types of electronic modules than I/O modules. In general terms, the herein disclosed electronics module 8 is suitable for all types of tightly packed devices containing electronics for different purposes.
Thermally conductive panels 9a 9b, 9c, 9d, 9e are mounted on each of the devices and lower the temperature inside the devices for increased life time of the electronics and improved availability of the electronics. The herein disclosed thermally conductive panels 9a 9b, 9c, 9d, 9e thus enable a passive and cost effective cooling facility.
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