DE19549536C2 - Mfg. printed circuit assembly for construction of sub-assemblies in e.g. microwave electronic equipment - Google Patents

Abstract

The circuit mfr. involves the generation of a number of circuit zones (1a,1b,1n) on a single main printed circuit board (1) where each zone contains a conductor pattern (1c). One or more sets of connecting wires (3) are attached to connection pads (1w) on the circuit board, by which the multiple circuit zones are mechanically interlinked, and after this step the main circuit board is divided into individual circuit building blocks.

Description

BACKGROUND OF THE INVENTION

The invention relates generally to electronics nikgeräte and more specifically the manufacture of such a Ge advises, comprising a method for arranging and testing a printed circuit, according to the preamble of claim 1 and also comprising a test arrangement, according to the preamble of claim 4.

Electronic devices, including those for microwaves phrases generally contain different components, such as capacitors, resistors, transistors and integrated circuits based on a common ge printed circuit board are mounted.

If such electronic devices in large numbers will be produced, a number of identical printed ones Circuit boards made in such a way that the ge printed circuit boards identical circuit patterns tra conditions and components such as capacitors, Wi resistors, transistors or integrated circuits thereon are attached, which are in contact with the corresponding  Circuit patterns are available. By also the printed Circuit boards through a melting furnace together with the components arranged thereon are caused the solder paste that is screen printed on the circuit pattern was applied, melting and the components are fixed on the corresponding circuit patterns solders. There are also connection lines printed on the circuit board are provided and are connected with different input and output electrode connection areas as well as in connection with various power electronics tread pads and ground pads. at Semiconductor circuits in which the components ten are mounted in a high mounting density, the printed circuit board also with a heat sink be allowed to the heat generated by the components derive.

To such electronic devices in large numbers and with a high throughput of production suggested the connecting lines on the printed To fix circuit boards in such a state that the connecting lines on a common Lei tion frame as an integral part of the same become. The lead frame can contain a heat sink and also as part of it.

FIGS. 1A and 1B show a conventional process for attaching the connecting lines 13 on printed circuit boards 11 a- 11 n, where n indicates 11 Fig. 1A, the upper side of the printed circuit boards 11 a, while Figure 1B, the bottom side of FIG. Thereof.

Referring to FIGS. 1A and 1B transfers each of the printed circuit boards 11 a- 11 n it, a wiring pattern 11 and w are held connection lines 13 on the Common men lead frame 14 as a part thereof. Furthermore, the lead frame 14 includes heat sinks 12 a- 12 n each corresponding to the printed circuit boards 11 a- 11 n. Although this is not explicitly illustrated, the heat sinks 12 a- 12 n with the lead frame 14 are part of the same a bridging part connected the. In the usual way, the wiring pattern 11 w are coated with a solder paste, which can be applied using a screen printing process or the like.

In the process of Figs. 1A and 1B it should be noted that the printed circuit boards 11 a- 11 n are mounted on the respective heat sinks 12 a- 12 n in alignment with the lead frame 14 such that the connection pads on the printed circuit boards 11 a- 11 n are formed, establish a contact attack with the corresponding connecting lines 13 . After the alignment as such is achieved, the lead frame 14 and the printed circuit boards 11 a- 11 n are passed thereon through a reflow furnace in order to achieve soldering of the connecting lines 13 on the corresponding connection pads of the printed circuit boards 11 a- 11 n ,

After the printed circuit boards 11 a- 11 n are firmly connected in this way on the lead frame 14 via the connec tion lines 13 , electrical and / or electronic components such as resistors, capacitors, transistors, integrated circuits and the like are on the respective parts of the semiconductor pattern 11 w of the printed circuit boards 11 a- 11 n attached, by a robot or other suitable device which carries out an automatic assembly. Since the same assembly procedure for each of the ge printed circuit boards 11 a- 11 n is repeated, the assembly process of Figs. 1A and 1B specifically cutlery are automated assembly with a high throughput.

The process of Figs. 1A and 1B is disadvantageous in that the alignment between the printed circuit boards 11 a- 11 n and the connecting lines 13 on the lead frame 14 can be lost at the time of reflow of the solder alloy, as in Fig. 2 is shown.

It should be noted in connection with FIG. 2 that the printed circuit board 11 a is rotated with respect to the lead frame 14 and thus the connecting lines 13 are rotated, while the printed circuit boards 11 b and 11 n are laid in parallel with respect to the lead frame 14 , While in such a case the electrical connection between the connecting lines 13 and the corresponding connection terminal surfaces on the printed circuit boards 11 a- 11 n can be maintained, the attachment of the electrical and / or electronic components on the printed circuit boards in exact alignment with the wiring patterns 11 w difficult on it. It should be noted that the printed circuit boards 11 a- 11 n carry very fine conductor patterns for the wiring patterns 11 w in order to increase the mounting density of the components thereon. If the amount of displacement or third of the printed circuit boards 11 a- 11 n becomes excessively large, even the electrical connection between the connecting lines 13 and the corresponding pads can no longer be maintained.

It was therefore conventionally necessary to accurately measure the deviation of each of the printed circuit boards 11 a- 11 n by a sensor provided on the robot and to correct the deviation in such a manner that the electronic components were correctly applied to the ver set printed circuit boards were assembled. However, such a process of detecting and correcting the deviation takes time even when a fully automated assembly device is used, and the throughput of the production of the electronic devices is inevitably deteriorated.

Alternatively, one can first mount the components on each of the printed circuit boards 11 a- 11 n with high precision, followed by mounting each of the printed circuit boards 11 a- 11 n on the lead frame 14 . It is expected that the error between the components and the wiring patterns on the printed circuit board is kept to a minimum, even if the relative positioning between the connecting lines 13 and thus the lead frame 14 and the printed circuit boards 11 a- 11 n, such as in the case of Fig. 2, ver deteriorates.

On the other hand, such a conventional process suffers from the disadvantage that the solder alloy on the ge printed circuit board melting at the time of BEFE stigung of the connection lines 13 on the printed TIC plates 11 a- 11 n caused and that the ten ready to be print circuit boards components that are soldered in exact alignment experience an undesirable drift as a result. If such drift occurs, the alignment between the components and the corresponding wiring patterns 11 w on the printed circuit board may be lost.

To such a drift of the components on the printed scarf to avoid the use of a plate, it is necessary to use a different one To use solder alloy composition that is lower Has melting temperature for the second time of the soldering process and it is necessary to carry out the second soldering process at a lower temperature lead, but the use of such an additional soldering alloy or a lower temperature oven for the melting process inevitably increases manufacturing costs.

From US 3,780,431 is a process for the production of printed Circuit boards are known in which a main circuit board too next a variety of such printed circuit boards points, which then isolated after the assembly and soldering process become. The provision of a shield during testing is based on this Citation does not emerge. From US 4,329,642 are a carrier and a socket for an integrated circuit is known.

It is therefore the object of the present invention a method and an arrangement for producing an electrical nikgerätes to create, in which the previously described Pro blemishes are removed, to make a device with a ge to be able to produce printed circuit boards with high throughput.

This task is accomplished with the method of the claim or the arrangement according to claim 4 solved. The subclaims give execution types of the invention.  

Other advantages of the Er invention result from the following detailed description description with reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1A and 1B are diagrams showing a conventional process of manufacturing electronic devices which include a printed circuit board;

Fig. 2 is a diagram showing the problems that arise in the conventional manufacturing process;

Figs. 3A and 3B are diagrams showing a first type of half-product;

Fig. 4 is a flowchart illustrating the manufacturing process according to the first embodiment;

Fig. 5 is a diagram showing a groove formed in a main printed circuit board to simplify the cutting process thereof;

FIGS. 6A and 6B are diagrams illustrating a second type of half-product;

FIGS. 7A and 7B are diagrams gen zei the final product, which was obtained by either of the first or second type of half-product;

Fig. 8 is a diagram showing a semi-product of a circuit ready for testing;

Fig. 9 is a flow chart illustrating the process of testing;

Fig. 10 is a diagram showing the construction of a test assembly used to test the device in the state of the semi-product; and

Fig. 11 is a diagram showing the construction of a test device used to test the device in the state of the semi-product.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIGS. 3A and 3B show a first type of electronic device in the state of a half-product, wherein Fig. 3A shows the upper surface of semi-product in a perspective view, while Fig. 3B, the Bo also denseite of the half product in a perspektivi rule view shows , It should be noted that the illustrated process generates a semiconductor package as the electronic device.

Referring to FIG. 3A, the semi-product comprises a printed main circuit board 1, printed on which a number of circuit regions 1 a-1 n are fixed, it being pointed out that each of the printed circuit zones 1 a-1 n a wiring pattern 1 w and electronic components 1 c contains, which may consist of a resistor, a capacitor, a transistor or an integrated circuit. As can also be seen from Fig. 3B, Heizesen ke-plates 2 a, 2 b and 2 n are provided on the bottom side of the main printed circuit board 1 in each case in correspondence to the zen 1 a- 1 n, the heat sink Plates 2 a, 2 b and 2 n are formed as a unitary, integral body of the lead frame 4 .

The lead frame 4, in turn, includes a plurality of lead frames zones 4 a- 4 n, where the zone 4 corresponds to a zone 1 a, b the Zone 4 Zone 1 b corresponds to the Zone 4 and Zone n of 1 corresponds to n. In each of the zones 4 a - 4 n one or more connecting conductors 3 are provided so that they extend away from the lead frame 4 as a unitary integral part thereof. In the semifinished product of FIG. 3A and 3B, each of the connecting lines is soldered to a corresponding electrode pad 1 wc 3, on the bottom side of the printed main circuit board 1 in electrical communication with the wiring pattern 1 w in each of the zones 1 a- 1 n is formed.

Fig. 4 shows the process for producing the semi-product of FIGS . 3A and 3B.

According to Fig. 4, a solder paste is applied to the wiring pattern 1 w in each of the zones 1 a-1 n of the printed circuit main board 1 in a step S1 with the aid of a screen printing process or any other suitable Pro zesses applied.

After step S1, the printed main circuit board 1 thus provided with the solder paste is aligned with respect to the lead frame 4 at step S2, so that the circuit board 1 is supported on the heat sink boards 2 a- 2 n and such that each of the Verbindungsleitun gene 3 of the lead frame 4 forms a contact with a corresponding electrode pad 1 wc.

Next, while maintaining the direction between the main printed circuit board 1 and the lead frame 4, the electronic components 1 c are placed on the main printed circuit board 1 at the respective predetermined positions with high precision at a step S3. Such placement of the electronic components 1 c can be performed by a robot or other suitable automated assembly equipment.

After the step S3, the printed main circuit board 1 carrying the electronic components 1 c and the lead frame 4, passed through a reflow furnace at a step S4, to cause melting of the solder paste on the wiring pattern 1 c on the main printed - Circuit board 1 was applied. At the same time, the heat sink boards 2 a- 2 n are soldered onto the main printed circuit board 1 .

Furthermore, in a step S5, the lead frame 4 is cut in such a way that the connecting leads 3 are separated from one another and then the individual printed circuits produced in such a manner are tested in the state in which they are still on the main printed main Have circuit board 1 . After testing, each of the printed circuit zones 1 a- 1 n is provided with an electromagnetic shielding cap.

Finally, in step S6, the main printed circuit board 1 is divided into individual printed circuit boards corresponding to zones 1 a- 1 n. At the step S6 may be an electromagnetic shielding cap on each of the printed circuit zones 1 a-1 n before see, during a state in which the ge printed circuit regions 1 a-1 n still on the main printed circuit board 1 are connected to each other are.

According to the process of Fig. 4, the alignment among the components are 1 e and the corresponding Wire the processing pattern 1 w on the main printed circuit board 1 in a simple manner maintained at the time of melting in the step S4, wherein the reflow process in the state is carried out in which the printed circuit zones 1 a- 1 n are rigidly connected to one another. For example, the main printed circuit board 1 and the lead frame 4 can be clamped together at two or three locations by means of a clamp.

At step S5 of Fig. 4, the main printed circuit board 1 can be cut up by a diamond dicing saw or a Lasersäge. Alternatively, it is possible to form a V-shaped groove along the boundary between the zones 1 a- 1 n, as shown in Fig. 5, and then break the main printed circuit board 1 on the V-shaped groove, the V-shaped groove corresponds to the broken line shown in Fig. 3A.

It should be noted that the lead frame 4 , the connecting leads 3 and the heat sink plates 2a-2n have the same common composition and are made of an Fe-Ni-Co alloy ("Corvar"), Fe-Ni alloy ("42 Alloy ") or an Fe alloy. The lead frame 4 may have a thickness of 0.1-0.5 mm through the connection lines 13 and the Wärmesenke- plates 2 a- 2 n have away. Since by forming the lead frame 4 , the connecting lines 3 and the heat sink plates 2 a- 2 n have a common flat surface, and the automated assembly of the printed circuit board and thus the electronic device on such a flat surface is thereby considerably simplified. Thus, the assembly process of the present invention is particularly suitable for the manufacture of electronic substrates with improved heat dissipation.

In the foregoing description, the printed circuit board 1 also includes a printed circuit board having a ceramic substrate. When a ceramic substrate is used, the printed circuit board 1 may have a thickness of 0.2-0.8 mm.

FIGS. 6A and 6B show a second type of half-product, wherein Fig. 6A shows the upper side of the semi-product in a perspective view, while Fig. 6B shows the bottom side of the half-product also in a perspective view.

. Referring to Figures 6A and 6B is now the printed main circuit board 1 with the printed circuit regions 1 a ₁ - 1 n ₁ and 1 a ₂ - 1 n ₂ defined, wherein the zones 1 a ₁ - 1 n ₁ and 1 a ₂ - 1 n ₂ are arranged in two rows.

On the side of the row which contains the zones 1 a ₁ - 1 n ₁ , a first lead frame construction 4 _{1 is introduced} , the lead frame construction 4 ₁ Leitrah menzonen ( 4 ₁ ) a- ( 4 ₁ ) n, each of which Zones 1 a ₁ - 1 n ₁ correspond. Each of the leadframe zones ( 4 ₁ ) a- ( 4 ₁ ) n in turn contains a plurality of connecting lines 3 ₁ and the lead frame 4 ₁ is electrical and mechanical by soldering each of the connecting lines 3 ₁ to a corresponding electrode pad 1 wc, which on the Bottom side of the main printed circuit board 1 is formed from, connected to the main printed circuit board 1 . In Fig. 6A, the representation of the wiring pattern as well as the electronic components is omitted from the drawing for the sake of simplicity.

Similarly, another lead frame 4 ₂ contains the lead frame zones (4 ₂₎ a- (4 ₂₎ n and is both elec tric and mechanical with the printed TIC zones 1 a ₂ - 1 n ₂ connected to a different row on the main printed circuit board 1 form. It should be noted is on, that each of the lead frame zones (4 ₂₎ a- (4 ₂₎ n connecting lines 3 ₂ includes, radiating from a portion of the lead frame 4 _2, wherein the compound of the lead frame 4 ₂ on the main printed circuit board 1 is achieved by soldering the connecting leads 3 ₂ to the corresponding electrode pads 1 wc, which are formed on the bottom side of the printed main circuit board 1 in correspondence to the zones 1 a ₂ - 1 n ₂ .

After the semi-product shown in FIGS. 6A and 6B is obtained, the main printed circuit board 1 is terzogen a dicing along the V-shaped grooves un are the ge in Fig. 6A by a broken line shows. Alternatively, the cutting can also be achieved using a laser sawing machine.

According to the construction of FIGS. 6A and 6B, the production efficiency is significantly increased compared to the case of the first embodiment.

FIGS. 7A and 7B show the construction of a Elek tronikgerätes which is out of the semi-finished product of FIG. 6A and 6B, obtained by using the printed main circuit board 1 is divided and is by men of Leitungsrah cut such that the connecting lines 3, or 3 ₁ , 3 _{2 are separated} from the lead frame 4 , 4 ₁ or 4 ₂ .

According to the drawings, the illustrated electronic device consists of the one formed on a printed circuit board corresponding to the zone 1 a ₁ , and the printed circuit board of the illustrated device is obtained by dividing the main printed circuit board 1 . Furthermore, the printed circuit board 1 a ₁ carries the heat sink plate 2 a ₁ on the bottom side thereof and a conductive cap 5 on the top such that the cap 5 has an electrical connection with the heat sink plate 2 a ₁ on the bottom side of the printed circuit board Circuit board 1 a ₁ via a Kontaktboh tion (not shown), which is formed in the printed circuit board 1 a ₁ , reached. As a result, the electronic components on the printed circuit board 1 a _{1 are} shielded from electromagnetic interference.

A description will next be given of step S6 of the flowchart of FIG. 4 to test the electronic devices. The test is carried out on a test arrangement which is designed to test the individual devices in the stage of the semi-product, which was described with reference to the first or second type of semi-product.

Fig. 8 the semi-product is ready for testing in the test arrangement, it being noted that the connection lines are separated Ver 3 of the lead frame 4. On the other hand, the printed circuit zones 1 a- 1 n are still in the state in which they are connected to each other, in the form of the main printed circuit board 1 .

In the semi-product of Fig. 8, the circuits in zones 1 a- 1 n function in principle independently of one another, while the operation of the circuits tends to be influenced by the electromagnetic interference. Such electromagnetic interference at the time of the test process is particularly serious in the construction of Fig. 8, in which the individual NEN circuits are arranged side by side with minimal separation. Thus, the test assembly includes a removable electromagnetic shield that selectively covers the circuit that is being tested.

It should be noted that such an electroma magnetic shield for testing the microwave directions and circuits is essential in which the Operating characteristics tend between the state in which an electromagnetic shield is provided and the state where no such electromagnetic Shielding is intended to change.  

Thus, the test arrangement leads the test process in the State by where the circuit by a dummy Shielded metal cap, which is the same size like the metal cap that comes with the actual device is used for electromagnetic shielding.

Fig. 9 is a flowchart illustrating the procedure of the test procedure according to the present embodiment of the invention. It should be noted that the test process of FIG. 9 corresponds to step S5 of FIG. 4.

According to FIG. 9, the sequence of steps starts with a step S11 in order to load the semi-product from FIG. 8 onto the test arrangement.

Next, at step S12, an electromagnetic shield is put on a selected printed circuit on the main printed circuit board 1 , and a test is performed on the shielded printed circuit at step S13. After testing in step S13, the electromagnetic shield is removed in step S14 and the electromagnetic shield is provided on another printed circuit on the board 1 by returning to step S12. In this case, steps S12 and S13 are repeated until all the printed circuits on the main printed circuit board 1 are tested one by one.

Alternatively, the shield the printed circuits 1 can a- 1 at step S12 for all n ge on the printed circuit board 1 are provided. In this case, the test operation in step S13 can be carried out simultaneously.

After the test process is completed, the electromagnetic shield of the test assembly is removed and the printed circuits on the main printed circuit board 1 are provided with a permanent electromagnetic shield, such as a housing 5 shown in Fig. 7A, as in step S15 is indicated.

Step S16, which corresponds to step S6 of FIG. 4, is then carried out and the main printed circuit board 1 is divided into a plurality of printed circuit boards, each of which carries a printed circuit which has already been tested ,

As mentioned earlier, it is desirable to provide an electromagnetic shielding of the test arrangement which is put on at step S12 and which is the same size as the size of the permanent electromagnetic shielding device 5 to ensure that this Test result for the current devices that are sent to the consumer is valid.

FIG. 10 shows the construction of a test arrangement 20 , which contains an object stage 21 , on which the semifinished product shown in FIG. 8 is mounted during the test.

Referring to FIG. 10, the printed circuit board 1, which forms the semifinished product and the different Components th 1 c and conductor pattern 1 w thereon at different be print th circuit zones 1 a- 1 carries n, via the stage 21, with the aid of a non- Förderme mechanism shown, as indicated by an arrow.

The object stage 21 in turn carries a conductor pattern 21 a for attacking the connecting lines 3 which are formed on the printed circuit board 1 , and the semifinished product, which has been formed in this way as a printed circuit board 11 , is conveyed to the test arrangement 20 in such a way that that the printed circuit zones 1 a- 1 n come one after the other into engagement with the object table 21 .

To each of the circuits w to zones 1 a- 1 shield during the test procedure, containing the test arrangement 20, a dummy metal cap 22 Stalt with a size and Ge, which are identical to a shield case, wel ches is actually provided on each product, after the printed circuit zones 1 a- 1 n have been divided into separate circuits. In order to ensure a correct position or attack of the connecting lines 3 with the corresponding conductor pattern 21 a, the tall cap 22 is equipped with pins 22 a, which are pressed by respective coil springs to connect the connecting lines 3 against the corresponding conductor pattern 21 a to press on the stage 21 . By using the metal cap 22 , it is possible to test the device in a state which is identical to the state in which the device is used as a product after being shipped.

FIG. 11 shows the construction of another test arrangement 30 , which contains an object stage 31 , on which the semifinished product shown in FIGS . 6A and 6B is mounted.

Referring to FIG. 11, the printed circuit board 1, which forms the semi-product and various components 1 c and conductor pattern 1 w thereon various zones 1 a ₁₁ n ₁ and 1 a ₂ - 1 n ₂ carries, on the object table 31 by means a conveyor mechanism, which is not shown, as indicated by an arrow.

It should be noted that the printed circuit board 1 carries the frame 4 ₁ and 4 ₂ on both side edges thereof, while the connecting lines 3 ₁ and 3 _{2 are separated} from the respective frame 4 ₁ and 4 ₂ for the purpose of testing. Furthermore, each of the frames 4 ₁ and 4 _{2 contains} perforations 4 x for engagement with a sprocket of the conveyor mechanism, which is not illustrated. As a result, the lead frame 4 ₁ and 4 ₂ and thus the printed circuit board 1 are supported in the stable direction indicated by an arrow.

The object table 31 in turn contains object table zones 31 A and 31 B, the conductor patterns 31 a and 31 b in each case for attacking with the connecting lines 3 ₁ and 3 ₂ , which are formed on a printed circuit zone on the printed circuit board 1 , for example zone 1 n and the printed circuit regions 1 a ₁ - 1 n ₁ gene gelan one by one sequentially in engagement with the object table 31 B. Similarly, the printed circuit areas 1 a ₂ pass - 1 n ₂ one after another in succession in engagement with the stage 31 A.

In order to shield each of the circuits in zones 1 a ₁ - 1 n ₁ and 1 a ₂ - 1 n ₂ during the test process, the test arrangement 30 contains a dummy metal cap 32 which is attached to a first part 32 A and a second part 32 B is formed, each of the first and second parts 32 A and 32 B having a size and shape identical to a shield case which is actually provided on each of the products after the printed circuit zones 1 a ₁ - 1 n ₁ and 1 a ₂ - 1 n _{2 divided} into separate circuits which are. In order to also ensure a correct attack of the connecting lines 3 ₁ and 3 ₂ with the corresponding conductor pattern 31 a and 31 b, the metal cap parts 32 A and 32 B are equipped with pins 32 a and 32 b, which are pressed on by respective coil springs, to press the connecting lines 3 ₁ and 3 ₂ on the corresponding Lei termuster 31 a and 31 b on the stage 31 .

By using the test arrangement of FIG. 11, the test of the device can be achieved efficiently in the same state in which the device is used after a product has been shipped.

Claims (6)

1. A method for arranging and testing a printed circuit, the circuit board main is formed on a printed, the main printed circuit board includes a plurality of such printed circuit boards to jewei time printed circuit zones, characterized onto a common main printed circuit board, through the following steps:
Placing an electromagnetic shield on the main printed circuit board ( 1 ) to cover the printed circuit ( 1 a- 1 n) thereon to be tested, and
Perform a test on the printed circuit ( 1 a- 1 n), which is equipped with the electromagnetic shielding. 2. The method according to claim 1, characterized in that the step of providing the electromagnetic shielding is carried out on all the printed circuits ( 1 a- 1 n) on the main printed circuit board ( 1 ). 3. The method according to claim 1 or 2, characterized in that the method further comprises the following steps:
Removing the electromagnetic shield from the printed circuit ( 1 a- 1 n) after the step of testing,
Providing permanent electromagnetic shielding ( 5 ) on the printed circuit, and
Dividing the main printed circuit board ( 1 ) into a plurality of printed circuit boards ( 1 a- 1 n), each of which carries a printed circuit board ( 1 w) thereon,
wherein the electromagnetic shield in the test has the same size as the permanent electromagnetic shield ( 5 ). 4. Test arrangement for testing a printed circuit board, characterized by
an object table ( 31 ) for holding a main printed circuit board ( 1 ) thereon, the main printed circuit board ( 1 ) consisting of a plurality of printed circuit zones ( 1 a- 1 n), each of which has a conductor pattern ( 1 w) and corresponding components ( 1 c) and wherein the main printed circuit board ( 1 ) further carries a plurality of connecting lines ( 3 ) on each of the printed circuit zones ( 1 a- 1 n) to each of the printed circuit zones ( 1 a - 1 n) to test
a on the stage ( 21 ) provided conductor pattern ( 21 a) in correspondence with the connecting lines ( 3 ) ner printed circuit zone ( 1 a- 1 n), which is present on the printed main circuit board ( 1 ), and
a shield housing ( 22 ) with a size and a shape, the same size and shape as the shield housing, which is provided after the test by the test equipment on the printed circuit zone ( 1 a- 1 n). 5. Test arrangement according to claim 4, characterized in that the shield housing ( 22 ) contains a plurality of pins ( 22 a) which lines are provided in correspondence with the connecting lines ( 3 ), the pins ( 22 a) being pressed by respective springs are and the connecting lines ( 3 ) to the conductor pattern ( 21 a) on the stage ( 21 ) are pressed. 6. Test arrangement according to claim 4 or 5, characterized in that the conductor pattern on the stage ( 31 ) comprises a first and a second conductor pattern ( 31 a, 31 b), the connecting lines ( 3 ) of a pair of mutually adjacent printed circuit zones ( 1 a ₁ - 1 n ₁ , 1a ₂ - 1 n ₂ ), the shield housing containing a first part ( 32 A) to cover a printed circuit zone which is in engagement with the first conductor pattern ( 31 a), and comprises a second part ( 32 B) to cover a neighboring printed circuit zone which is in engagement with the second conductor pattern ( 31 b) when the printed main circuit board ( 1 ) is mounted on the stage ( 31 ), wherein each of the first and second parts ( 32 A, 32 B) of the shield case have a size and shape of a shield case which is provided on the printed circuit zones after being tested by the test equipment.