RU2001413C1 - Check-up method for electrical connectors - Google Patents

Abstract

The invention relates to a measurement technique and can be used to monitor the technical condition of electrical connectors. The method includes supplying electrical signals through a communication line to the connector, monitoring the parameters of the connector during external exposure, and controlling the amplitude-frequency characteristic (AFC) of the connector in the range frequencies from 0.01 to 100 MHz, register the presence of resonant frequencies AFC by the presence of resonant frequencies judges the presence of a failure condition for the controlled connection The status of the failure at the beginning of the life of the connector is judged by the fulfillment of conditions A / A 05 in for at least one of the resonant frequencies, where A / A are the amplitudes of the input and output I / O OUT signals at the resonant frequency, and the presence of states a failure at the end of the operating life is judged by the fulfillment of the conditions f / f 125, Q / Q a 13. cp1 srg 1 where f, f are the cut-off frequencies of the frequency response at the beginning and end of CPR1 F2 at the end of the service life, Q, Q are the quality factors of the connector resonant frequency at the beginning and end of life. External action on the connector is carried out in the form of mechanical stepwise movement of the component parts of the connector relative to each other, and at each stage of movement, the presence of resonance frequencies of the frequency response of 2 sf, 4 silt is recorded.

Description

The invention relates to measuring and control equipment and may find application in control and measuring devices, communication equipment, multiprocessor computer complexes, and computers.

Closest to the technical nature of the invention is a method for monitoring electrical connectors, comprising supplying electrical signals through a communication line to a connector, externally acting on a connector, monitoring during exposure of a connector.

The disadvantage of this method is the low reliability of the connector monitoring due to the impossibility of monitoring the connectors in the intermediate (third) state or in the failure mode.

The chain of the invention is to increase the reliability of the connector control.

The goal is achieved. that the method of controlling electrical connectors, including the supply of electrical signals through the communication line to the connector, external influence on the connector, monitoring during the action of the connector parameters, further control the amplitude-frequency characteristic of the connector in the frequency range from 0.01 to 100 MHz, detect the presence of resonance frequencies of the amplitude-frequency characteristics of the connector in the frequency range from 8 to 100 MHz, according to the presence of the indicated resonant frequencies, the presence of a state of failure at the controller is judged connector to be used.

In addition, the presence of a malfunction state at the beginning of the life of the connector is judged by the fulfillment of the conditions for at least one of the resonant frequencies

Aeykh / Avkh 0,5,

where А Ных., АВХ are the amplitudes of the output and input signals at the resonant frequency, respectively, and the presence of a failure condition at the end of the operating life is judged by the fulfillment of the conditions

where f, -p 1. fcp2 - cut-off frequency values of the amplitude-frequency characteristic, respectively, at the beginning and at the end of the service life;

Ch, Q2 are the quality factors of the connector at the resonance frequency, respectively, at the beginning and at the end of the life of the connector

In addition, external impact on the connector in the form of mechanical stepwise movement of the components

parts of the connector short circuit to the state of open circuit and vice versa, at each stage of movement, the presence of resonance frequencies of the amplitude-frequency characteristic with amplitudes satisfying the relation

0.9 ABX. Avykh 0,1AVH.

Fig. 1 shows equivalent equivalent circuits of the connectors when the harmonic signal (Fig. 1a) acts on the connector input for cases of short circuit (SC), open circuit or open circuit (XX) and failure (Figs. 16, 1c and 1d, respectively). Informative

the parameters of the listed modes during the control of the connector are the electrical resistance of the connector R at short circuit and XX (Fig. 16 and 1c, respectively), RI, Li, Ci - at failure of the connector. In addition, in FIG. 1d

An electrical model of a connector is shown in a failed state.

In FIG. Figure 2 shows the qualitatively amplitude-frequency characteristics of the connector in the initial failure state.

(Fig. 2A) and the final (Fig. 26) stages of operation.

On fit. Figure 3 is a block diagram of an apparatus for implementing a connector control method. In FIG. 4 is a sequence diagram (Fig. 4a) of the movement of the component parts (ailka – socket) of the connector as a function of time and frequency (for fault areas) of the reference, i.e. without failures (Fig. 46), and checked, if there is a failure section

connector (Fig. 4c).

The control method is illustrated by the representation of the equivalent circuits of the connector in the form of a short circuit of its components (Fig. 16 on the right), which

corresponds to the on state of the connector and when it is in good condition it is controlled by the value of the active (ohmic) resistance R less than the nominal allowable

state i.e. RHOM value. In FIG. Fig. 1c shows the connector in the off state or in the open or XX state, when the ohmic resistance between its contacts is infinity, which corresponds to the opening of the connector contacts between each other (Fig. 1c to the right). In FIG. 1d, the connector is shown in the failed state when both short sections and sections XX (open) are simultaneously present in it;

Fig. 1e shows an electrical model of an equivalent circuit of a connector in a failed state as the number N of parallel-connected circuits, each of which contains series-connected elements R, L, C, (1 2N)

In FIG. 2 shows the qualitatively amplitude-frequency characteristics of a working connector (straight lines 1) and a connector in the failed state (curves 2), and in FIG. 2a shows the frequency response of the connector failure during the initial period of its operation, and FIG. 26 - to the final.

The need for such information may arise, for example, in analogous equipment, when, under operating conditions, the operating frequency range does not exceed units of megahertz. In this case, a connector having a section or a failure mode does not affect the normal operation of the equipment, and by changing the parameters of the connector in the failure mode, one can judge the approach of the boundary section when the failure mode goes into failure mode, i.e. in other words, predict the life (or failure) of the connector.

In FIG. 2, the F (MHz) frequencies are plotted along the horizontal axis without observing the scale of the harmonic signals supplied to the input of the connector. The vertical axis shows the amplitudes of the input signals (in volts), which coincide with line 1, of the connector without a fault section (reference connector) and the amplitudes of the output signals (in volts), and for the reference connector, the amplitude-frequency characteristic (AFC) is direct visible lines 1 (Fig. 2a, b), corresponding to the signal transmission coefficient from the input to the output of the connector, equal to one, and curves 2 (ibid.), representing the frequency response of the connector in the failure mode at the initial stage of the service life (Fig. 2a) and on the final (Fig. 26). The cutoff and resonance frequencies are respectively indicated by Fcp, FCp, Fpi, Fpi, FP2, Fp2 of the failed connector at the initial and final stages of operation. The quality factor of the connector at the resonant frequency Fp is defined as the ratio

° -ww

where (Fp-Д) is the decay frequency of the resonance curve at the amplitude level equal to 0.7 of the resonance amplitude. The cutoff frequency FCp refers to the frequency in megahertz when the amplitude of the frequency response decreases to the level of 0.7 frequency amplitudes in the passband (in this case, the frequency range is from 0.01 to 1.0 MHz). In FIG. Figure 2 shows, for the sake of clarity, the cases where the number of resonances in the connector failure mode is two. However, this number of resonances can be much

large, a decrease in the amplitude of the output oscillations at the resonant frequencies over time can be explained by an increase in the ohmic 5 resistance of the electrical contacts of the connector due to an increase in the number of sections in the open mode (four such sections are shown on the right in Fig. 1d), on the other hand, - reducing the length of the sections in the fault mode (ibid.). The increase in the quality factor of the connector at non resonant frequencies over time can be explained by the increase in the range of differences

15 inductances D f Li-Ln-1 j between adjacent (at face value) their values at the beginning of the service life, as well as a reduction in the total number of chains Ri, Li, Ci (number N) of the model in Fig. 1e. Cut Off Frequency

0 Fcp with an increase in the operating time can be explained, on the one hand, by a decrease in the absolute values of the inductive components Lt, and on the other hand, by an increase in the influence of transverse capacitive components

5 (not shown in FIG. 1e) due to the presence of a distributed capacitance from adjacent conductors of the coaxial cable, as well as adjacent (earth) ends of the connector.

0 in FIG. 3 is a structural diagram of a device implementing the described monitoring method. The device contains a generator of 11 harmonic (sinusoidal) signals in the frequency range from 10 to

5 100 MHz and a similar second oscillator 1-2, testable and reference connectors 2-1 and 2-2. two-channel oscilloscope 3, the communication line 4-1 - 4-4 (radio frequency cable) with a wave impedance of 50 Ohms and

0 mechanical oscillation unit 5, Mechanical communication of the unit 5 with connectors 2 in FIG. 3 is shown by a double line. .Connecting the terminals of the Instrument Grounds to each other, as well as the shielding contacts of the connector with the cable shielding of FIG. 3 are not shown.

The device implements the method as follows. Initially, the oscillators 1, the oscilloscope 3, and block 5 are turned on.

0 of generator 1-2 in the device is caused by the need to exclude the mutual influence of channels with connectors 2-1 and 2-2 with each other when connecting them to one generator through a high-frequency separator. First, the generators 1-1 and 1-2 are checked for operability, they are calibrated (i.e., the signals are set at the output of the same amplitude), the two channels of the oscilloscope 3 are set to the same sensitivity, the connection lines 41 and 4 -2 are selected with the same length s with a line 4-3, 4-4, 3, a connector of the same type as the controlled one, but having a hard (without failures) harp cpi-stick of switching from its extreme positions (short circuit and XX) to each other, is selected as a reference connector 2-2 a friend ate a long (about 100) number of exceptions-1/1. In this case, the absence of failures in the reference connector is monitored visually51 by the oscilloscope after each on-off cycle (in accordance with the sequence diagram shown in HJ of Fig. 4a). The stroke of the movements of the components of the connector is chosen equal to the norm of movement according to the technical specifications (TU) to the connector, increased by 10% to obtain a reliable state of breakage. The basic requirements for block 5, through which the parts of the plug-socket connector are mutually moved, consists in high precision displacement displacements (up to several micrometers) due to the small linear region of existence of the failure mode, Another requirement for block 5 is the time f of each discrete the point should be sufficient to remove the frequency response of the failed connection in the range of 0.010-100.0 MHz with a variable frequency step, For the case where it is necessary to EXPLOD the fault area with higher accuracy (with higher resolution), proceed as follows. Initially, the connector is installed in the short-circuit state with zero clearance between the plug and socket cases (upper part of the sequence diagram of Fig. 2h). Next, we bring the snare out of the socket with the same (except for the last) step, the value of which corresponds to the minimum discretization of block 5. At each step, the frequency response in the falling section of the sequence diagram (Fig. 4a) is taken at an interval of 1.1 DX.

where L X is the rate of movement along the TU. At the last step, we increase the discretes by the amount of the required sampling k and repeat the sequence diagram to the state of short circuit and vice versa (Fig. 4a). The last step is again increased by the value of k, and repeat the movement along the sequence diagram with the removal of the frequency response. thereby increasing the given number of times and accuracy

fixing the range of existence of the connector failure mode (if necessary. JHMO). Block 5 can be implemented on the basis of a digital servo.

If there are no areas of failure in the indicated connector when checking it according to the described procedure (Fig. 46), this connector is taken as a reference.

The control of connector 2-1 is carried out similarly to the control of the first connector

with the difference that, in order to save time, the frequency range at each step of movement can be limited to two to three frequencies (for definiteness, the cutoff frequency FCp, p is the frequency of the first

resonance Fpi and frequency of the second resonance FP2 - FIG. 2a). In addition, in accordance with the operating conditions, both the total number of sampling steps and the total number of cycles of the cyclogram can be limited

(Fig. 4a).

(56) Low voltage rectangular connectors, type RPPM 27, Technical conditions GEO 364,234 TU, 1987, l. eighteen.

Claims (1)

1. METHOD FOR CONTROL OF ELECTRICAL CONNECTIONS- Miguel, including the supply through the communication line to the connector of electrical signals, external action on the connector, monitoring during the action of the parameters of the connector, characterized in that. what with In order to increase the reliability of the control, the amplitude-frequency characteristic of the connector is monitored in the frequency range 0.01-100 0 MHz, the presence of resonance frequencies of the amplitude-frequency characteristic of the connector in the frequency range 8-100.0 MHz is recorded. by the presence of the indicated resonant frequencies, the presence of the Failed state of the controlled connector is judged with 0 5 2, The method according to claim 1, characterized in that the presence of a Failure condition at the beginning of the life of the connector is judged by fulfilling the conditions for at least one of the resonant frequencies AVIH / AVH. where ABC and Avx are the amplitudes of the output and input signals at the resonant frequency, respectively, and the presence of a Fault condition at the end of the connector's life is judged by the fulfillment of the conditions fcpl / fcp2 .25.Q2 / Ql g 1.3. where fcpi, fcp2 are the cutoff frequencies of the amplitude-frequency characteristics of the connector, respectively, at the beginning and at the end of the life of the connector; Qi. Q2 are the values of the quality factor of the connector at the resonant frequency, respectively, at the beginning and at the end of the life of the connector. 3. The method according to claim 1, characterized in that. that the external impact on the connector is carried out in the form of mechanical stepwise movement of the components of the connector one relative to another in 7 //////////// / /////// // ///, fi-ri NP1N / Ш ///// ШМШЯ ///////////// Jl, „/ ff / Ј ... ,, I. ,, ZJ //////////////////////////////////////. 7 & ////////////////////////////////////// 7 / i) % V oci V & f tot, Z in the range from the state of the connector Short circuit to the Open state, and vice versa, at each stage of movement, the presence of resonance frequencies of the amplitude-frequency characteristic with amplitudes satisfying the O.AeR Avykh 0.1 Avkh ratio is recorded H ////// KsXXS C 7 &  c //////// toe, 0 Ј (rv)