HU192083B - Testing probe for testing printed wiring and printed circuit panels - Google Patents

Abstract

The test probe is provided with a contact head (1), a leg (2) and an end (3) for supplying power, which are arranged in a needle bearing (5) used as holder and consisting of a guiding part (5a) and a support/stop part (5b). The essence of the invention consists in that the contact head (1), the leg (2) and the end (3) for supplying power are constructed as a single needle element, preferably with respect to the board, a spring element (4) being attached to this needle element. The spring element (4) consists of a holding/guiding part (4a) and an elastic part (4b), the holding/guiding part (4a) being arranged in the opening of the guiding part (5a) of the needle bearing (5) and the elastic part (4b) being arranged between the guiding part (5a) and the support/stop part (5b) of the needle bearing (5). To limit the axial movement of the needle element, the test probe is provided with a limiting element (6). <IMAGE>

Description

FIELD OF THE INVENTION The present invention relates to printed circuit and printed wiring. probe for examining sheets.

The most widely used building block in the electronics industry is the printed wiring system. Printed Circuit Board (hereinafter Printed Circuit Board). Their reliability and flawlessness are essential for the finished electronic product, so it is essential that errors can be accurately detected. Printed sheets should be examined both before and after implantation.

Several methods have been developed for examining printed pages according to the parameters to be examined. Most testers use a so-called electronic central unit to process the measurements and connect the measuring points of the printed sheet to be tested. needle-bearing connection fields are used, as they provide the connection of a very large number of measuring points with acceptable safety. The needle beds form an interface between the measuring apparatus and the printed sheet to be tested, the most important element of which is the reliability of which is the contact needle itself.

The best known solution to the design of the pins is that the movable cylindrical portion of the pin is guided loosely in a cylindrical tube, and a reset spring is located beneath the movable portion. This unit can be separately housed in a receptacle provided with an end suitable for connecting an electrical measuring line.

This receiving sleeve is inserted tightly into a hole made of insulating material according to the position of the points to be tested.

Such solutions consist of several units. The first and most important such unit is the needle head and stem, which can only be made with a special, high-precision machine fleet. The shape of the needle head is determined jointly by the shape of the point to be tested and the contact of the pin. For better contact, the needle heads are formed with edges to cut through the oxide film, which can easily form on printed pages. The shank, in almost all cases, has more than one shoulder and is subject to stringent specifications for its roll and surface quality because it is precisely fitted into the second larger unit. The simplest version of the second unit is a cylindrical tube, which has worked precisely and finely in both its bore and its mantle so that the stem can be loosely fitted in its bore with good current flow.

As a general rule, this cylindrical tube also includes stop flanges and shoulders. The periphery of the cylindrical tube fits snugly into the third unit, which is the end of a receiving sleeve that provides a power connection. Its design is determined by the way it is applied to the current (soldering, pressing, wire-wound, etc.). These three units, or at least the last two, are coated with precious metal to improve the conductivity of the current.

The needle bed, as a clamping and positioning element, shows a great variety in the shape, dimensions and the requirements of the test spring.

The above-described solutions have several disadvantages.

First, the cylindrical and shouldered inflatable sleeve, fitting tube, needle shaft and needle head must be machined to Yes diameters and with high precision.

This requires special machines. The needle is made up of several pieces and the mating surfaces must be interchangeable. Excellent surface quality is a prerequisite for the perimeter and bore of cylindrical parts or pipes. This disadvantageous construct also has another disadvantage. It can be seen from the foregoing that in such structures the current path is divided into two parts. In the first such section, the measuring price passes through a needle head and needle stem forming a movable integral part, and then divides into two parts. One current path leads through the mating but movable cylindrical inner surfaces to the sleeve forming the spring housing, and from there through the transient resistor to the also cylindrical receiving sleeve, from which part of the current flows to the connection point of the measuring line. The other current path is formed by a compression spring disposed between the stationary and movable parts of the needle structure in a mechanically prestressed state, from where the current flows from the needle stem to the spring through a temporary resistor and then through a temporary resistor into the fitting tube. The dimensions and material of the compression spring are thus determined by two conditions. The first condition is the given spring force and spring properties on the contact pin head. The second condition is that the material of the spring be conductive. Of these two conditions electrical properties of the springs into the background _r necessarily need, but not negligible. Due to their transient resistances and moving frictional fitting cylindrical parts, the surfaces are coated with precious metal. Thus, a new technological step for conducting the current needs to be incorporated into the manufacturing process.

In such structures it is to be anticipated that the current is conducted through surfaces which are subject to wear due to moving surfaces. A further disadvantage, therefore, is the abrasion of very thin surfaces and, in most cases, the accumulation of oxides.

As described above, the electrical conductivity of the full contact pin is determined jointly by the values of the dwelling transient resistors, the continuously variable transient resistances, and the electrical data of the spring, which circumstance results in a high dispersion of the resulting values and resulting in a desirable increase and a decrease in the reliability of the whole measurement process.

Other known inventions have sought to solve the problem in other directions. These are characterized by efforts to eliminate contact insecurity by breaking away from the cylindrical configuration, by extending the length of the contact surface or by means of a spring-loaded internal contact or an external flexible bypass, but have only been able to alleviate the design problems. An example of the above is U.S. Patent No. 3,753,103 Also, by mounting a piston-like friction member at the end of the pin of the contact needle, which is permanently attached radially to the stationary sleeve wall for improved electrical contact. The purpose of the solution was to bypass the spring as a conductive path. However, it was not able to eliminate the uneven current flow through the moving-friction surfaces, or to prevent it from moving. perfect circumvention of the spring.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome the disadvantages of the present invention by providing a probe which, while improving tactile, contact, and current conducting conditions, provides a simple, low-cost, non-transient, implantable contact needle replacement.

The object of the present invention has been achieved by a probe having a contact head, a spring element, a stem and a power supply end. These elements are located in a needle bed consisting of a guide portion and a support-stop portion. According to the invention, the contact head, the stem and the power supply end are formed as a single needle element, preferably in the form of a plate. A spring element is attached to the needle element. The spring element comprises a grip-guide portion and a spring portion. The grip guide portion is disposed between the needle bed guide portion and the support stop portion. The probe is provided with a limiting element to limit the axial movement of the needle element. It is a further advantageous feature of the invention that the spring member is formed of a single helical spring having a grip-guiding portion having a smaller pitch than the spring portion of the spring portion and a spring member on either a wet contact head or a stem is fixed.

The probe of the present invention will now be described in more detail with reference to the drawings in connection with embodiments. Figure 1 is a plan view and a sectional view of an embodiment of the probe of the present invention.

Figure 2 is a plan view and a sectional view of another embodiment of the probe of the present invention. As shown in FIG. 1, the probe contact end 1, the tip 2 of which is provided with a current supply 3, is formed as a single plate-like needle element. On the neck part 7 formed between the contact head 1 and the stem 2, a spring element 4 is arranged surrounding the needle element.

The spring element 4 is preferably a one-piece spiral spring having two thread pitches. The spring element 4 thus comprises a suitably tightly wound gripping guide portion 4a and a spring portion 4b wound with a higher pitch.

The contact pin has a rectangular cross-section on the neck portion 7 which fits snugly into the gripping guide portion 4a, while the outer diameter of the gripping guide portion 4a, as a loosely fitted sleeve, guides and centers the rectangular contacting pin 5, preferably cylindrical. The spring portion 4b of the spring member 4, formed with a higher pitch, rests on the support stop 5b of the needle bed 5. In the support-abutment portion 5b, the diameter of the bore including the stem 2 of the probe is smaller than the diameter of the helical spring, so that the support can be easily solved. The limiting element 6 ensures that the measuring probe is raised to the same level by means of a spring element 4, by means of a pinching on the stem 2 of the probe, so that it strikes the support-stop part 5b of the needle 5. __

In the embodiment of Fig. 2, the stop required to raise the probe to a constant level is provided by a stop plate 6 with an opening corresponding to the profile of the contact head 1 placed on the guide 5a of the needle bed as the final phase of assembly.

In addition to the known embodiments, other embodiments are possible within the scope of the invention.

The present invention provides a probe; which is extremely easy and cheap to manufacture due to its high simplicity, as there are several low-cost methods for producing a plate-like component, and the needle is made up of very few elements, thus greatly simplifying assembly. contact uncertainty within the probe (since the current passes from the probe head to the power supply through a single material, eliminating dormant transitions and moving-friction transients), thus eliminating the precious metal variation for improving the transient resistors, or Am. 1 and 2, the probe moves without friction in the needle bed and is thus considered to be a floating needle for conducting current.

Furthermore, when a given force is reached, the probe head sinks in the rigid needle bed and thus protects against possible injury.

In the construction of the contact pins so far, the tactile pressure spring element necessarily always supplies current. In this case, the spring element has no function other than to provide tactile pressure.

Due to its design, the probe is suitable for implantation into a receiving sleeve and is therefore well suited for use as a stand-alone unit, old contact place or other application.

Claims (6)

An inspection probe for testing printed wired and printed circuit boards having a contact head, a spring member, a stem and a power supply end, which are located in a needle bed comprising a guide portion and a support-and-stop portion for receiving, 1), the stem (2) and the power supply end (3) are formed as a single needle element, preferably in the form of a plate, on which the spring element (4) is fastened, from the gripping guide part (4a) and spring part of the spring element (4) (4b) comprising the gripping guide portion (4a) in the opening of the guide portion (5a) of the needle bed (5) and the springing portion (4b) leading portion (5a) of the needle bed (5) and the support stop (5b). ) and is provided with a limiting element (6) to limit the axial movement of the needle element. Test probe according to claim 1, characterized in that the spring element (4) is formed of a single helical spring, the gripping guide part (4a) of which has a smaller pitch than the pitch of the spring part (4b). Test probe according to Claim I or 2, characterized in that the spring element (4) is formed on the contact head (1) or stem (2) of the needle element or between the contact head (1) and the stem (2). secured to the neck (7). 4. Test probe according to any one of claims 1 to 3, characterized in that the limiting member (6) is a locking washer located in the pinch of the stem. 5. Water according to any one of claims 1 to 4 »· Sleeve probe 192.083, characterized in that the stop member (6) is an abutment plate provided with strain (s) fixed to the guide (5a) of the needle bed (5). 6. Test probe according to any one of claims 1 to 3, characterized in that it is housed as a single unit in a receiving sleeve,