AT397740B - Device for shielding an electromagnetic radiation from a printed circuit board having electronic components - Google Patents

Abstract

A shielding housing 6 is fastened on a printed circuit board 1 having electronic components 5 by means of a latching connection, so that an electromagnetic radiation is shielded. A special mechanical and electrical connection is achieved by pressing parts 81 and supporting parts 83 of shielding bodies 7, 8 of the shielding housing 6. <IMAGE>

Description

AT 397 740 B

The invention relates to a device for shielding electromagnetic radiation from a printed circuit board having electronic components.

For example, in the case of a power supply module, it may be necessary for it to have protection against electromagnetic interference by mechanical measures, that is to say by attaching shielding parts. It is conceivable, for example, that a sheet metal plate is screwed onto the assembly for a shielding effect from a neighboring flat assembly. Such tapping points, which can be connected to the printed circuit board by means of screws, rivets and soldering, require complex work processes during production, which are consequently associated with high costs. A compromise is conceivable, in which simply shaped parts. thus in particular sheet metal plates 10 are attached to the printed circuit board and soldered to it, so that the shielding effect is not optimal, but the manufacturing costs are reduced.

It is an object of the invention to provide a device for shielding electromagnetic radiation from a printed circuit board having electronic components, so that an optimal shielding effect can be achieved with tolerable manufacturing costs 16. This object is achieved in a device for shielding electromagnetic radiation from a printed circuit board having electronic components which is provided with a scraper housing for the components, which has two scraper bodies, - in which a joining part of one of the shielding bodies is provided for penetrating such a hole in the printed circuit board, - in which a snap-in connection of the joining part is provided for snap-in connection of both shielding bodies when assembling of the shield housing.

The invention is based on the idea that a shielding housing, which ensures optimum shielding effect in all spatial directions, can be divided into two shielding bodies, i.e. one of the 25 shielding bodies on each side of the printed circuit board, the shielding housing should be assembled in such a way that a joining part of one of the shielding bodies penetrates a hole in the printed circuit board, and a latching connection of the joining element causes a latching connection of the two shielding bodies. With this snap-in connection, the printed circuit board should be clamped between the two shielding bodies in such a way that a mechanical and electrical connection can be achieved by this snap-in connection alone. so. In an advantageous manner, a particularly stable connection can be achieved, that is, both mechanically and electrically. The shielding housing combined in this way can be designed such that an optimal shielding effect can be achieved in all spatial directions. Such a locking bond of the shielding body is easy to manufacture during manufacture and is therefore inexpensive. It can also be provided that only a partial area of the printed circuit board is shielded with such a shield housing 35. For the electronic components provided in the shielding housing, a shielding effect can be given in the sense that an electromagnetic interference radiation generated by these electronic components is sealed to the outside by the shielding housing. Otherwise it can also be provided that the electronic components provided in the shielding housing are sealed against electromagnetic interference from the outside by the shielding housing. It can be provided that a plurality of release housings are arranged side by side on the printed circuit board. It can also be provided that a further or more further shielding housings are provided within a shielding housing.

A device for shielding an electromagnetic radiation can be carried out, in which a support surface is provided on a first of the shielding bodies, to which the circuit board can be pressed at the latching connection. This advantageously enables a stable mechanical and electrical connection between the shielding body and the PCB achievable.

A device for shielding disgusting electromagnetic radiation can be carried out, in which a pressing part on the second shielding body is provided, by means of which the circuit board can be pressed onto the contact surface during the snap-in connection. In an advantageous manner, a stable mechanical and electrical connection between the pressing part and the plate is thereby achieved Letter board achievable.

A device for shielding electromagnetic radiation can be implemented, in which a latching edge is provided on the first shielding body, on which a latching surface of the second shielding body can be latched during the latching connection. In an advantageous manner, a stable mechanical and electrical connection between the latching edge and the latching surface, that is to say between the first shielding body and the second shielding body, can thereby be achieved.

A device for shielding an electromagnetic radiation can be implemented, in which a supporting part is provided on the second shielding body, by means of which the second shielding body can be deposited on the first inner hole surface of the hole in the printed circuit board during the snap connection, for example 2

AT 397 740 B in the case of an electrically conductive inner surface of the hole, which is in particular electrically conductively connected to electrically conductive surfaces of the printed circuit board by means of a perforation. a stable mechanical and electrical connection between the safety devices and the circuit board can thereby be achieved in an advantageous catfish. 5 A device for shielding electromagnetic radiation can be implemented, in which a support surface is provided on the first shielding body, on which the first shielding body can be supported on the snap connection on a second hole inner surface of the hole in the printed circuit board, for example in the case of an electrically conductive hole inner surface, which in particular by means of a By connecting the hole in the circuit board to the electrically conductive surfaces of the circuit board, a stable mechanical and electrical connection between the support surface and the circuit board can be achieved in an advantageous manner.

A device 2 for shielding against electromagnetic radiation can be implemented, in which the first and the second inner surface of the hole are provided opposite one another. sodaS during the latching connection of the support cable to the first inner hole surface and the supporting surface to the second inner hole surface can be pressed in an advantageous manner. On the opposite inner hole surfaces, pressing forces can be compensated, by means of which the supporting part and the supporting surface are pressed, this is an advantageous way a stable mechanical and electrical connection can be achieved for the support surface, that is to say for the first shielding body, and for the support SI, that is to say for the second shielding body, and for the printed circuit board. A device for shielding electromagnetic radiation is feasible, in which, in the case of the residual connection, a pressing force provided on the pressing part and a supporting force provided on the supporting part can be compensated for by a counterforce between the latching edge and the latching surface, in which such an inclination of the latching surface is provided in such a way that the Counterforce acts parallel to a surface normal of the rasp surface, a particularly stable mechanical and electrical connection can be achieved. The pressing part, that is to say the second shielding body, is in particular electrically connected to the printed circuit board by means of the pressing force. By means of a counterforce to this pressing force, the printed circuit board is pressed onto the support surface, that is to say onto the first shielding body. An electrical connection between the first shielding body and the printed circuit board can thereby be achieved. By means of the supporting force, the supporting part, that is to say the second shielding body, is pressed against the first inner surface of the hole, that is to say against the printed circuit board. As a result, an electrical connection of the second sealing body to the printed circuit board can be achieved. Counteracting the supporting force, the supporting surface, that is to say the first shielding body, is pressed against the opposite second inner surface of the hole. This makes it possible to achieve an electrical connection between the first shielding body and the printed circuit board. By means of the compensating counterforce to the pressing force and the supporting force, an electrical connection can be achieved between the latching edge and the hasting surface, that is to say between the first shielding body and the second shielding body. By means of these force effects, a stable mechanical connection can be achieved in an advantageous manner between the printed circuit board and the first and second shielding bodies. In this case, a stable electrical connection can be achieved in an advantageous manner at the individual points of contact.

A device for shielding an electromagnetic radiation can be erased, in which the shielding bodies are formed from sheet metal, and an advantageous orphan can achieve electrical conductivity in connection with a mechanical strength for the shielding bodies. Individual parts of the shielding body, in particular the pressing part. and the support part. can be made resilient in an advantageous manner.

From a variety of possible embodiments of the invention, preferred embodiment examples are explained in more detail with reference to figures

1 shows a side view of two shielding bodies from a shielding housing.

2 shows a part of a section through a shielding body.

Fig. 3 shows a part of a section through a shielded housing assembled on a printed circuit board. The following reference symbol table is used in connection with the figures and the description

Numbers of reference symbols gb 1 circuit board 2 hole of the circuit board 3 first hole inner surface of the hole of the circuit board 4 second hole inner surface of the hole of the circuit board 3 AT 387 740 8 5 electrical component β shielding housing 7 first shielding body of the shielding housing 8 second shielding body of the shielding housing 9 joining part! from one of the shielding bodies 10 locking connection part of the joining part 71 contact surface of the first shielding body 72 locking edge of the first shielding body 73 abutment surface of the first shielding body 81 pressing part of the second shielding body 82 locking surface of the second shielding body 83 AbstQizteii of the second shielding body F81 pressing force F83 supporting force 6 counterforce

Like the Flg. 1 shows, a shielding housing 6 consists, for example, of a first shielding body 7 and a second shielding body 8. The two shielding bodies 7, 8 are formed, for example, from sheet metal

The first shielding body 7 is, for example, box-shaped. Provided on an end face by a side surface and support surfaces 71 with an electrically conductive surface in the region of the support. A printed circuit board 1 can be placed on the contact surfaces 71. which is drawn in dashed lines in the figure. On the printed circuit board 1, slot-like holes are provided which are penetrated by screening flaps when the printed circuit board 1 is placed, on which a support surface 73 of the first shielding body 7 is provided. Openings are punched into the side surface of the first shielding body 7 under consideration on which a locking edge 72 of the first shielding body 7 is provided

The second shielding body 8 is shaped, for example, similar to a box cover. The shielding housing 6 can be assembled by placing the second shielding body 8 like a box cover on the first shielding body 7, so that the assembled scraper housing Θ encloses a cuboid-shaped space, for example the prayed shielding body 7,8 the circuit board i is clamped between them. Holes are provided in the printed circuit board 1, which are penetrated by parts of the side surfaces of the shielding bodies 7, 8 when they are joined together. A joining part Θ is provided on one side surface of the shielding body 8 and penetrates a hole in the printed circuit board 1 when the shielding housing 6 is joined together. A latching connection part 10 is arranged on the joining part 9. The latching connection part 10 is used for the latching connection of both shielding bodies 7, 8 when the shielding housing 8 is joined together A latching surface 82 is provided on the latching connection part 10 of the joining side 9. It is envisaged that when the shield housing 6 is joined together, the latching edge 72 of the first shielding body 7 mates on the latching surface 82 of the second shielding body 8 Snap connection of both shielding bodies 7 &amp;. On the second shielding body 8, a plurality of pressing parts 81 are provided, from which the printed circuit board 1 is pressed onto the electrically conductive contact surfaces 71 during the snap-in connection. Protective parts 83 are provided on the joining part 9, which penetrates a hole bi of the circuit board 1 during the latching connection, and should lie on the inner surface of the hole in the circuit board 1 during the latching connection, that is to say in particular are supported. Opposite this inner hole surface, a further inner hole surface of the hole in the printed circuit board 1 is provided, against which the abutment surface 73 of the first shielding body 7 is to rest, ie in particular is to be supported. In the latching connection by means of the latching edge 72 and the latching surface 82, the support parts 83 are to be pressed against the inside of a hole with a certain supporting force, while the support surface 73 is pressed against the opposite inside of the hole. At the same time, in the snap-in connection, the pressing means 81 should act on the printed circuit board 1 with a certain pressing force, so that it is pressed against the contact surfaces 71. For a better explanation of the latching connection, in particular the forces acting in the process, a representation based on a section Α, Β should be considered.

Like the Flg. 2 shows, in a partial view of section A-B, a part of the second shielding body 8 is shown. This has a joining part 8 for penetrating a hole in the printed circuit board. A locking connection part 10 is arranged on the rig part 9 as a resilient sheet metal tab. A latching lug is provided on the latching connection part 10, on which a latching surface 82 is adjacent. When the shielding housing is joined together, the latching lug resiliently slides along the inside of a side surface of the first shielding body 7 (not shown in this figure) until the latching edge on which the fourth

AT 397 740 B

Locking surface 82 snaps into the locking connection On the joining part 9, a support part 83 of the second shielding body 8 is arranged, for example in the form of a resilient sheet metal tab. This slides on a hole inside the hole of the printed circuit board, not shown in this figure, resiliently, while when the shield housing 9 is joined together, this hole of the printed circuit board penetrates it. It is a pressing part 81 arranged on the second shielding body 8, for example in the form of a resilient sheet metal tab. During the snap-in connection, this presses resiliently onto a surface of the printed circuit board, not shown in this figure.

This partial view of section A.B shown in this figure is considered in more detail when the shielding housing is assembled. 10 As shown in FIG. 3, part of the assembled shielding housing 6 is shown in a partial view of section A-B. The shielding housing 8 has a first shielding body 7 and a second shielding body 8. The first shielding body 7 has an opening. in which a locking edge © 72 is provided. The first shielding body 7 has its support surface 71, which is shown in dashed lines in this figure. A printed circuit board 1 rests on the support surface 71, for example with its component surface. The circuit board 1 has in the area of the support surface 71 a conductor track which is provided for the application of an electrical release potential.

The attachment of components 5 is provided on the component surface of the printed circuit board 1. With their fastening straps, these can penetrate the printed circuit board at fastening holes, and can be fastened to the opposite soldering type © surface of the printed circuit board 1 by means of L5tv connections. The circuit board 1 has a hole 2, for example in the form of an elongated slot, with a first inner surface 9 and a second inner surface 4, which are arranged opposite one another. For example by means of soldering, a solder connection is provided on the hole inner surfaces 3, 4. This solder connection should be connected to the conductor tracks for the intended shielding potential.

It is envisaged that a part of the first shielding body 7 penetrates the hole 2 of the printed circuit board 1 26. A supporting surface 73 of the first shielding body 7 is provided on this part, which abuts the second inner surface 4 of the hole, i.e. with a part of the outer surface of the surface shown in this figure illustrated part of a side face of the first shielding body 7.

In this illustrated arrangement of the first shielding body 7 and the circuit board 1 soH for the confluence of the shielding housing 6, the second shielding body 8 with its joining »! 9 hole 2 30 of the printed circuit board 1 in the direction from the solder side surface of the printed circuit board 1 to the components · surface of the printed circuit board 1. A snap connection part 10 of the FQ part 9 slides resiliently along an inside of the illustrated side surface of the first shielding body 7. A latching lug is provided on the latching connection part 10, to which a latching surface 82 adjoins. A support part 83 of the second shielding body 8 is arranged on the joining part 9. While the latching connection part 10 resiliently slides along the inside of the side surface of the first shielding body 7 shown, the supporting silve 83 resiliently slides along the inner surface 3 of the hole. This takes place until the rasp comes into the vicinity of the latching edge 72. From this point in time, a pressing part 81 of the second shielding body 8 rests on the surface of the circuit board 1 on the LB side. In this area of the solder side surface of the circuit board 1, conductor tracks are arranged for the shielding potential. The 40 assembly part) 9 is pressed into the hole 2 of the printed circuit board 1 against the spring pressure of the resilient pressing surface 81. This takes place until the latching lug on the latching connection part 10 reaches the latching edge 72, and subsequently until the latching surface 82 is latched on the latching edge 72 ©. The latching connection is established .

With this latching connection of the first shielding body 7 with the second shielding body 8, the printed circuit board 1 is clamped in. The pressed-on 81 presses with a pressing force F81 on the printed circuit board <s 1, which is also pressed against the bearing surface 71, by means of the latching connection between the Locking edge 72 and the locking surface 82 of the first shielding body 7 is pressed against the printed circuit board 1 on the support surface 71. The support part 83 presses with a support force F83 against the first hole inner surface 3, the support surface 73 also being pressed against the second hole inner surface 4 by means of the latching connection between the latching edge 72 and the latching surface 82. At the locking edge so 72 in particular, the pressing force FBI and the supporting force F83 add up and are compensated by means of a counterforce G. as locking forces in the locking connection. This is shown in a force diagram in this figure.

With the aid of this latching connection, a particularly stable mechanical connection of the first shielding body 7 to the second shielding body 8 can thus be achieved by advantageously clamping the printed circuit board 1 ss. Mechanical contact takes place in a number of ways on the basis of pressure forces. These can be specified as follows: - The first shielding body 7 presses with its support surface 71 against the component surfaces of the printed circuit board 1.5

Claims (6)

AT 397 740 8 - The first shielding body 7 presses with its support surface 73 against the second inner hole surface 4 of the hole 2 of the printed circuit board 1. - The first shielding body 7 presses with its locking edge 72 onto the locking surface 82 of the second shielding body 8. - The second shielding body 8 presses with its pressing part 81 onto the soldered surface of the printed circuit board 1. - The second shielding body 8 presses with its supporting part 83 against the first inner hole surface 3 of the hole 2 of the printed circuit board 1. In particular, these compressive forces can be adapted depending on the respective application. This applies in particular to a spring action for the support part 83 and a spring action for the pressing part 81. Depending on the manufacturing tolerances provided, for example a curved shape can also be provided for the latching surface 82. For example, a support force F63 which is comparatively very large in relation to the pressing force F81 can be provided, so that the joining part 9 is pressed against the inside of the first shielding body 7. In this case, it can be provided that the latching edge 72 rests on an inner curvature of the latching surface 82 during the latching connection . For example, for better heat transport, it can be provided that the shielding housing 6 has ventilation openings. Such rectangular ventilation openings, for example, are stiffened on the first shielding body 7, for example in ed. 1. Due to its mechanical stability, the shielding housing 6 can also be used for a mechanical shielding effect, for example. For example, in order to achieve a shielding effect against a magnetic field, the shielding housing 6 can be made of a material which can preferably shield magnetic fields in particular. For example, to shield heat radiation, the shield housing 6 can, for example, also be made of a material that is suitable for shielding against heat radiation. For example, to shield electromagnetic alternating fields, the shield housing 8 can be made of an electrically conductive material, so that, like bet a Faraday-KSfig A shielding effect can be achieved. In this application in particular, the mechanical contacts can be used to also use the pressure forces to make electrical connections. In this context, it is particularly advantageous that special soldered connections are not required between the shielding casing 9 and the printed circuit board 1. These mechanical contacts of this type, on which electrical connections can also be produced by means of pressure forces, can be specified, for example, in the snap connection shown in FIG. 3: Connection of the first shielding body 7 to the second shielding body 8 by means of the remaining edge 72 and the locking surface 82. - Connection of the first shielding body 7 to the circuit board 1 by means of the support surface 71 on the one hand and on the other hand by means of the support surface 73. - Connection of the second shielding body 8 to the circuit board 1 by means of the pressure plate 81 on the one hand and on the other hand by means of the support part 83. Thus, an electronic component having circuit board an Absohirmgehäuse attached by means of snap connection, so that an electromagnetic radiation is shielded. A special mechanical and electrical connection is achieved by pressing parts and supporting parts of shielding bodies of the shielding housing. 1. Device for shimming off electromagnetic radiation from an electronic component (5} having a printed circuit board (1) - in which a shielding housing (6) for the components (5) is provided, which has two shielding bodies (7, 8), - in which a joining part (9) of one of the shielding bodies (7, 8) is provided for penetrating a hole {2} in the printed circuit board (1), - in which a latching connection part (10) of the joining part (9) is provided for latching connection of two shielding bodies (7,8) when joining the shielding housing (6). 2. Device according to claim 1, in which a support surface (71) on a first of the shielding body (7) is provided, to which the circuit board (1) can be pressed during the latching connection. 6 ÄT 387 740 B 3. Device according to claim 2, in which a pressing part (81) is provided on the second of the shielding body (8), through which the printed circuit board (1) can be moved to the mounting surface (ή) during the detenting 4. The device according to claim 3, in which a locking edge (72) is provided on the first shielding body (7) on which a locking surface (82) of the second shielding body (8) can be locked in the locking connection 6 Supporting part (83) on the second shielding body (8) is provided, by means of which the second shielding body (8) can be supported on a first perforated surface (3) of the hole (2) in the printed circuit board (1) during the snap-in connection. 6. The device according to claim 5, wherein a support surface (73) on the first ») shielding body (7) is provided on the softer the first shielding body (7) in the snap connection on a second inner hole surface (4) dos holes (2) of the circuit board (1) can be supported 7. The device according to claim 6, wherein the first (3) and the second (4) inner hole surface are provided opposite one another, so that in the latching connection of the support surface (83) to the first inner hole surface (3) and the support surface (73) to the The second hole inner surface (4) can be pressed on. The device according to claim 7, in which, in the snap connection, a pressing force (F81) provided on the pressing part (81) and a supporting force (F83) provided on the support part (83) by a counterforce (G &gt; between the locking edge) (72) and latching surface (82) can be compensated for, in which the shielding bodies (7, 8) are formed from sheet metal, for which 3 sheets of drawings 30 35 40 4B BO SS 7