JPS62269075A - Apparatus for inspecting printed circuit board - Google Patents

Abstract

PURPOSE:To inspect a printed circuit board easily at a high speed using a reduced number of wirings, by judging the quality of the printed circuit board by selection output due to a module connected through the inspection contact and connector of a substrate. CONSTITUTION:Inspection contacts 2a contacted with a large number of the contacts of a printed circuit board 6 to be inspected are provided to a substrate 4 and the corresponding contacts 2a are connected to a module substrate 30 through connectors 30a and a predetermined number of contacts are selected by the mother board 32 being the gathering of a predetermined number of the substrates 30. The selected contacts are connected to the measuring circuit 20 connected to a microcomputer 22 by an external connection wire 14 having a reduced number of wirings corresponding to the number of the selected contacts and the printed circuit board is easily inspected at a high speed using a reduced number of wirings without receiving the effect of electrostatic capacity because a selection circuit is also unnecessary.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an apparatus for inspecting continuity, short circuits, component constants, etc. of a printed circuit board before or after mounting electronic components.

[Conventional technology] FIG. 8 shows a conventional printed circuit board inspection device.

M! Inspection contacts 2a are attached to a base body 4 made of a border in a grid pattern.8 Normally, about tens of thousands of inspection contacts 2a are required. The substrate 6 to be inspected is pressurized by the pressure mechanism 8, and each measurement point thereof is brought into contact with the inspection contact 2a. From the other end of each inspection contact 2a, each wiring 10
is pulled out and connected to an external connection line 14 via a connector 12. Although only a portion is shown in FIG. 8, tens of thousands of pieces of this arrangement [10] are required. The external arrangement 1A14 is connected to the selection circuit 18 via the connector 16.

This selection circuit 18 sequentially selects each test contact 2 a and supplies it to the measurement circuit 20 . The data measured by the measuring circuit 20 is judged by the microcomputer 22 to obtain test results.

[Problem that the invention attempts to solve] However, the conventional device has the following problems.

First, it required a lot of wiring from tens of thousands of test contacts, making the connection work complicated.

For this reason, not only did wiring costs increase, but reliability also deteriorated, and repair work was extremely difficult.

Second, due to the large number of wires, the capacitance between the wires and the ground increases, resulting in a decrease in inspection speed. However, there was also a risk of errors occurring when measuring the n's capacity.

[Means for Solving the Problems] The printed circuit board inspection device according to the present invention holds a module board that carries a selection circuit almost vertically by a connector on the opposite surface of a base body on which contacts are provided. are doing.

[Operation] The selection circuit on the module board is directly connected to the contact point by a connector without using wiring. At the same time, this module board is held on the base by a connector.

[Practice N] An embodiment of the present invention is shown in FIG. 1, in which test contacts 2a are attached in a grid pattern to a base 4 made of an insulator.Normally, there are tens of thousands of test contacts 2a. In this example, 25,600 pieces (160 pieces x 160 pieces) are required.
The substrate 6 to be inspected is pressurized by the pressurizing mechanism 8, and each measurement point thereof is brought into contact with the inspection contact 2a. Each inspection contact 2a is connected to a selection circuit provided on the module board 30. This module board 3
0 is held substantially perpendicular to the upper surface of the base 4.

In this embodiment, 5 module boards 30 are provided in the horizontal direction and 160 module boards 30 are provided in the vertical direction. Outputs from each module board 30 are collected by a motherboard 32, which is an interconnection board, for 32 boards, and are connected to an external connection line 14.
connected to. Although not shown, the external connection line 1
4 is coming out from all 25 motherboards 32. The microcomputer 22 controls the selection circuit via the external connection line 14 to sequentially select the test contacts 2a. As a result, the measuring circuit 20 sequentially measures the multiple contacts 2a and provides the data to the microcomputer 22. Based on this measurement result, the microcomputer 22 performs an inspection as shown in the flowchart of FIG.

Since the output from the motherboard 32 has already been selected, the number of external connection lines 14 may be extremely small.For example, in this embodiment, only one? Zerboard 3
There are only 2 to 22 external connections 49114 coming out. There are 25 motherboards 32, but the 22 external connection lines 14 can be connected in parallel with each other! & Ultimately, only 22 external connection lines 14 are required. In the conventional device as shown in FIG. 8, at least two external connection lines 14 are required for one inspection contact 2a.

Therefore, in a device having as many as 25,600 test contacts 2a, the same number of external connections 4914 would have been required in the past. In the case of this embodiment, the external signal line 14 can be reduced to about 1/1000th of the conventional one.

Details of the module board 30 and motherboard 32 used in this embodiment are shown in FIGS. 2 and 93. As shown in FIG. 3, 32 module boards 30 are connected to one motherboard 32. Figure 2 is a front view, and Figure 3 is a front view.
The figure is a side view. A connector 30a is provided at the bottom of the module board 30, and each terminal 30b (there are 32) of this connector 30a is connected to a corresponding inspection contact 2a.
connected to. The board 30 includes an IC that constitutes a selection circuit.
30e and 30f are provided. A connector 30c is provided on the top of the board 30, and the output from the selection circuit is connected to a terminal 30d.

The configuration of the selection circuit is shown in FIG.

The explanation will proceed with reference to this figure and FIG. 2.

The connector 30c has a terminal for a 5-bit address signal (
5 terminals), module selection signal terminal (1 terminal), analog signal terminal (2 (Ilil)), data signal/reset signal terminal (2 terminals), ground/power supply terminal (2 terminals) A total of 12 terminals are provided.The address signal has 5 bits so that 32 terminals 30b can be selected.The module selection signal indicates that the module board 30 has been selected. This shows that.

Two analog signal lines supply voltage etc. to each measurement point,
It is for making measurements. Further, the data signal/reset signal is used to switch whether to connect an analog signal line for voltage supply or an analog signal line for measurement to each measurement point.

A 15-bit address signal line from the microcomputer is input to the 17-server board 32.

The upper 10 bits of these are decoded by the IC 32c and given to each module board 30 as a module selection signal. Each signal of the module board 30, except for this module selection signal, is connected in parallel by a connector 32a of the motherboard 32. therefore,
Thirty-two connectors 32a are provided on the bottom surface of the motherboard 32. Furthermore, a connector 32b is provided on the top surface of the motherboard 32. This connector 32b is provided with terminals for each signal connected in parallel by the connector 32a and terminals for the upper 10 bits of the address. That is, there are 22 terminals.

Next, a description will be given of how the inspection contacts 2a are connected to the measurement points on the substrate 6 to be inspected. In Figure 5,
Details of the vicinity of the inspection contact 2a are shown.

The pressure mechanism 8 applies pressure in the direction of arrow A. On the other hand, the base body 4 is fixed. Therefore, the measurement point 6a of the substrate 6 to be inspected
is brought into contact with the test contact 2a of the probe 2. The probe 2 is held within the hole 4a of the base 4. A connection contact 2b is provided on the top of the probe 2, into which the connector 30a of the module board 30 described earlier is inserted.

As a result, the module board is not only electrically connected to the measurement point 6a, but also mechanically held.

FIG. 6 shows details of the vicinity of the inspection contact 2a according to another embodiment. In this embodiment, a pressure-sensitive conductive rubber 7 with vertical anisotropic conductivity is placed on the substrate 6 to be inspected. When the probe 2 is pressed against the pressure-sensitive conductive rubber 7, the test contact 2a is brought into contact with the measurement point 6a via the internal wire 7a.

Note that other pressure-sensitive conductive rubbers having vertical anisotropic conductivity can also be used.

In the above embodiment, the substrate 4 to be inspected is fixed and the substrate 4 to be inspected is pressed, but the substrate 4 to be inspected may be fixed and the substrate 4 to be inspected is pressed. It is also possible to press the test contact 2a from both sides. Furthermore, in the above embodiment, the inspection contact 2 is
Although a is pressed, it may be pressed from the bottom or side.

[Effects of the Invention] The printed circuit board inspection apparatus according to the present invention holds a module board having a selection circuit almost vertically on a base body by a connector. Therefore, the number of external connection lines can be significantly reduced.

In other words, not only the work of connecting external connection lines is simplified, but also a highly reliable printed circuit board inspection apparatus can be obtained. Furthermore, since the number of external connection lines is small, the capacitance between wires and the ground is small, and inspection speed is quick. Furthermore, the BIA difference is small even when measuring capacitance.

[Brief explanation of the drawing]

PIS 1 is a diagram showing an embodiment of the present invention, Figures 2 and 3 are diagrams showing details of the module board and motherboard,
Figure 4 is a diagram showing details of the selection circuit, Figure 5 is a diagram showing details around the probe, Figure 6 is a diagram showing details around the probe according to Ike's embodiment, and Figure 7 is an inspection using this embodiment. FIG. 8 is a flowchart showing the testing process of the device, and is a diagram showing a conventional printed circuit board testing device. 2a...Inspection contact 4...Base 20...Measuring circuit 30...Module board 30a...Connector 32...Motherboard Note that the same symbols in each figure indicate the same or A considerable portion is shown. Agent Patent Attorney Takaharu Tsukashima Figure 7

Claims (2)

[Claims] (1) Base; Test contacts protruding from one surface of the base and arranged in a grid pattern to correspond to measurement points on the board to be tested; electrically connected to the test contacts; A module board that has a connecting contact provided on the surface of the substrate, a selection circuit electrically connected to the connecting contact by a connector, is held almost perpendicularly to the other surface of the base by the connector, and is arranged in multiple pieces side by side. A printed circuit board inspection device comprising: a determination circuit that determines the quality of a board to be inspected based on the output of the selection circuit. (2) An interconnection board is connected to the side opposite to the base of the module board by a second connector, and interconnects the same outputs of the selection circuits of the plurality of module boards lined up. A printed circuit board inspection device according to claim 1, characterized in that: