JPS6318920Y2 - - Google Patents

Description

[Detailed description of the invention] The present invention is an ultrasonic covered wire measuring device that measures the degree of deterioration of an installed plastic wire by measuring the propagation time of ultrasonic waves through the outer covering. Regarding.

Conventional methods for calculating the degree of deterioration of the outer covering of plastic electric wires, etc. are: (a) At the time of installation, colored rings, etc. are attached to calculate the age.

(b) Visually inspect the outer covering to discover any external abnormalities such as cracks.

Methods such as the following are known. However, with method (a) above, it becomes difficult to visually determine the color of the rings due to long-term environmental changes. Furthermore, in method (b), it is difficult to make an appropriate visual judgment because the electric wire is several meters off the ground.

By the way, as plastics generally age,
It is known that chemical changes can harden the outer coating. It is also known that when an ultrasound signal propagates through a material, the propagation speed depends on the hardness of the material. One possible method is to utilize these characteristics to measure the time it takes for the ultrasonic waves to propagate through the sheath of a plastic wire, thereby measuring the degree of deterioration of the sheath. However, in the conventional method for measuring ultrasonic propagation time, a single ultrasonic pulse is used. In the case of substances other than air, it is difficult to measure the propagation time because the propagation time between measurement points is shorter than the time width of the ultrasonic pulse.

In view of the above circumstances, the present invention uses ultrasonic waves to measure the degree of deterioration of the outer covering of plastic electric wires, etc., and also continuously transmits ultrasonic pulses to facilitate the measurement of propagation time. The present invention provides an ultrasonic coated wire measuring instrument that employs a method of
In this case, the measurement tool used is one that uses sound insulating material to prevent malfunctions due to ultrasonic waves leaking into the air during measurement, and is small and lightweight so that measurement can be easily performed from the ground.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit diagram showing the configuration of an embodiment of the present invention. Note that in the following description, binary logic levels "1" and "0" are used. In this figure, A is a time measurement circuit. 1 is a switch operated when starting measurement. This switch 1 is an automatic return type switch, and the common contact C is grounded. The NO contact and NC contact of switch 1 are connected to pull-up resistors _R1 and _R2 , respectively, and an SR type flip-flop (hereinafter referred to as SRFF) formed by two 2-input NAND gates is connected to pull-up resistors R1 and R2, respectively.
(abbreviated as ) are connected to a set input terminal S and a reset input terminal R, respectively. That is, SRFF2 is normally in a reset state and is set only while switch 1 is turned on. The set output terminal Q of SRFF2 is connected to 3 D-type flip-flops (hereinafter referred to as
(abbreviated as DFF) is connected to the clock terminal C of the
Further, a reset output terminal Q of the SRFF2 is connected to a reset terminal R of a counter 9, which will be described later.
The D terminal of DFF3 is connected to Vcc and is always set at the rising edge of clock terminal C. and
The set output terminal Q of DFF is the buffer amplifier 4
Connected to the enable terminal of the This buffer amplifier 4 is such that the input is sent to the output only when the signal at the enable terminal is "0". Also,
A reset terminal Q of DFF3 is connected to an input terminal of inverter 5. The output terminal of inverter 5 is
It is connected to the input terminal b of the two-input NAND gate 6 and the gate of a gate turn-off thyristor (GTO) 7. That is, when DFF3 is in the set state,
The buffer amplifier 4 is in the disabled state, the input terminal b of the gate 6 is "1", and the gate of the GTO 7 is "1". When in the reset state, the buffer amplifier 4 is in the enabled state, and the input terminal of the gate 6 and the gate of the GTO 7 are "0". become. 8 is an oscillator,
A clock generation circuit consisting of a frequency dividing circuit, etc.
It outputs a Hz clock signal and supplies it to the input terminal a of the gate 6. The gate 6 inverts the clock signal supplied from the clock generation circuit 8 only while the input terminal b is "1" and supplies it to the input terminal C of the counter 9. Counter 9 is “0” at reset terminal R
is applied, it is reset, and when the reset terminal R is "1", a count is performed every time a clock signal is applied to the input terminal C, and when the count value reaches "10", the output terminal Q is It becomes “1”.
10 is a monostable multivibrator (hereinafter abbreviated as monostable multi), and when the clock input terminal C, that is, the output terminal Q of the counter 9 changes from "0" to "1", the output terminal Q is "0" for a certain time width.
Outputs a pulse signal. This “0” pulse signal is then supplied to the reset terminal R of DFF3.
It is designed to reset DFF3. G.T.O.
Reference numeral 7 is for connecting or cutting off the power to the ultrasonic transmitter (hereinafter referred to as transmitter) 11. When "1" is applied to the gate, it turns on and powers the transmitter 11.
Vcc is supplied, and when "0" is applied, it is turned off and power supply Vcc is not supplied. The output of the transmitter 11 is connected to an ultrasonic wave transmitter (hereinafter referred to as a wave transmitter), and when the transmitter 11 is supplied with power Vcc, the wave transmitter 12 emits ultrasonic waves. Reference numeral 13 indicates a plastic wire as the object to be measured. Reference numeral 14 denotes an ultrasonic receiver (hereinafter abbreviated as a receiver) connected to an ultrasonic receiver (hereinafter abbreviated as a receiver) 15 .
Receiver 15 amplifies the ultrasonic signal received by receiver 14 and sends it to amplifier 16 . The amplifier 16 further amplifies the signal supplied from the receiver 15 and supplies it to a clock terminal C of a retrigger type multivibrator 17 (hereinafter referred to as a retrigger multivibrator). Here, the pulse width generated by the retrigger type multi 17 is set to be slightly longer than the period of the ultrasonic wave. Therefore, while the receiver 14 is receiving ultrasonic waves, the output terminal Q of the re-trigger multiplier 17 outputs "0", and becomes "1" after a certain period of time after the reception ends. And re-trigger multi 17
The signal at the output terminal Q of is inverted by the inverter 18 and supplied to the enable terminal E of the four-digit counter 21. 19 is a crystal oscillator which generates a 10MHz clock signal. This clock signal is then supplied to a frequency dividing counter 20. The counter 20 is a counter that divides the frequency by "1/10", and a 1MHz clock signal is obtained at the output terminal. 2
1 is a four-digit counter, which counts the clock signal input to the clock terminal C only when the signal at the enable terminal E is "1". Then, the count results are four sets of output code signals S ₀ , S ₁ , S ₂ , corresponding to the “10 ⁰ ”, “10 ¹ ”, “10 ² ”, and “10 ³ ” digits, respectively.
It is output as S ₃ and supplied to the 4-digit display device 22. The display device 22 receives the input code signal S ₀ ,
Based on S ₁ , S ₂ , and S ₃ , the LED segments of each digit are made to emit light to display numerical values.

The operation of the circuit configured as above will be explained with reference to the time chart of FIG.

First, it is assumed that the power supply Vcc is on, and that the four-digit counter 21 and DFF3 have been reset by a circuit not shown. At this time, the clock generating circuit 8 generates a 1 Hz clock signal, and the counter 20 outputs a 1 MHz clock signal. In addition, the signal supplied to the enable terminal E of the 4-digit counter 21 is “0”.
and the count is disabled. Now, when the operator turns on switch 1 for a moment, SRFF2 is set during that time. As a result
A pulse signal of "1" is applied to the cross terminal C of the DFF3, the DFF3 is set, and at the same time, the counter 9 is reset (a, b, c in Fig. 2).
reference). Then, the set output of this DFF3 is “1”
Since the buffer amplifier 4 is disabled, the clock signal (1 MHz) of the counter 20 is no longer supplied to the four-digit counter 21. on the other hand,
The reset output "0" of the DFF 3 is inverted by the inverter 5 to become "1" and is supplied to the input terminal b of the NAND gate 6 and the gate of the GTO 7. As a result, the counter 9 starts counting the 1 Hz clock signal, and the GTO 7 is turned on to supply power Vcc to the transmitter 11. As a result, transmitter 1
2 starts emitting ultrasonic waves, which propagate through the sheath of the plastic wire 13 and reach the receiver 1.
4 (see f and g in Figure 2). Further, the ultrasonic signal received by the receiver 14 is amplified by the receiver 15 and the amplifier 16, and is supplied to the clock terminal C of the retrigger multi 17. As a result, the retrigger multi outputs “0”, and this output is output to the inverter 1.
It is inverted at 8 and becomes “1”, and the 4-digit counter 21
is supplied to the enable terminal E of. In this way, the four-digit counter 21 is enabled, but since the buffer amplifier 4 is disabled as described above, counting is not yet performed. Then, when 10 seconds have passed since the DFF3 was set, the count value of the counter 9 becomes "10" and the output of the counter 9 becomes "1" (this time is defined as _t1 ). As a result, the monostable multi 10 outputs a pulse signal of "0" and resets the DFF3. As a result, the GTO 7 is turned off, the power to the transmitter 11 is cut off, and the ultrasonic emission from the transmitter 12 is stopped (see b, d, e, f in FIG. 2).
On the other hand, since the buffer amplifier 4 is enabled from this time _t1 , the 4-digit counter 21 is 1MHz
Start counting the clock signal. This counting continues as long as there is an ultrasonic signal received by the receiver 14. And time t ₂
When the received signal disappears, the output of the re-trigger multi 17 becomes "1" because the clock input disappears, and as a result, the signal at the enable terminal E of the 4-digit counter 21 becomes "0" and counting is stopped (the (See fg and h in Figure 2). That is, 4
The digit counter 21 counts the time from time t ₁ when ultrasound transmission is stopped to time t ₂ when the received signal disappears. This time (t ₂ -t ₁ ) is the time required for the ultrasonic wave to propagate in the sheath of the plastic wire 13 between the transmitter 12 and the receiver 14. Further, the propagation time measured as described above is displayed on the display device 22. (See i in Figure 2.) Next, Figure 3 shows the transmitter 1 used in this embodiment.
2 and a wave receiver 14, in which A is a side view and B is a cross-sectional view of a portion of a wave transmitter 12.

In the figure, 30 is a channel-shaped casing with an open top surface, 31 is a support rod vertically attached to the center of the bottom surface of the casing 30, and 32 is a sound insulating material filled in the casing 30. A groove 33 having a width slightly wider than the outer diameter of the plastic wire 13 is formed in the length direction of the housing 30. The sound insulating material 32 has the transmitter 12 and the receiver 14 spaced apart from each other by a predetermined distance, and the transmitter 12 is arranged such that its ultrasonic radiation surface 34 faces the groove 33, and the receiver 14 is similarly buried so that the ultrasonic wave receiving surface faces the groove 33. 35 is a signal cable of the wave transmitter 12, which is connected to the transmitter 11 through a hole provided on the lower surface of the housing 30. Further, 36 is a signal cable of the receiver 14, which is similarly connected to the receiver 15 through a hole provided on the lower surface of the housing.

In the above configuration, the measurer holds the support rod 31, brings the housing 30 close to the installed plastic wire 13, and inserts the plastic wire 13 into the groove 33.
is introduced into the waveguide and brought into contact with the wave transmitter 12 and the wave receiver 14. Then, the operator performs measurement in this state. In this case, all of the ultrasonic waves radiated from the transmitter 12 except those transmitted to the plastic wire 13 are absorbed by the sound insulating material 32, so that they do not leak into the air.

As explained above, according to this invention, by utilizing the fact that the propagation time of ultrasonic waves in the outer sheath of plastic electric wires, etc. depends on the degree of deterioration, The propagation time is determined by determining the time from the time when the transmission of the continuously transmitted ultrasonic signal stops to the time when the ultrasonic signal ends being received by the ultrasonic receiver, and from this the degree of deterioration of the outer sheath is calculated. This makes it possible to calculate the degree of deterioration more accurately than conventional methods such as color-coded rings and visual inspection.

In addition, the measuring device in this invention has a structure that prevents ultrasonic waves from leaking during measurement by having a sound insulating material in the contact area with the plastic wire etc. on which the ultrasonic transmitter and ultrasonic receiver are installed. Furthermore, since a support rod is attached to the channel-shaped housing housing the contact portion, the degree of deterioration of the installed plastic electric wires, etc. can be accurately and easily measured from the ground.

The ultrasonic coated wire measuring device based on this invention is
Of course, it can also be used to measure the degree of deterioration of installed plastic electric wires, etc. on the ground.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram showing the configuration of an embodiment of the present invention, Fig. 2 is a time chart for explaining the operation of the embodiment, and A in Fig. 3 is a side view showing the measuring instrument of the embodiment. , B of FIG. 3 is a cross-sectional view of the measuring tool. 11... Ultrasonic transmitter, 12... Ultrasonic transmitter, 14... Ultrasonic receiver, 15... Ultrasonic receiver, 30... Housing, 31... Support rod, 32... Sound insulation Material, 33...Groove, A...Time measurement circuit.

Claims (1)

[Claims for Utility Model Registration] A measuring instrument having an ultrasonic transmitter and an ultrasonic receiver arranged at a predetermined distance apart, a transmitting section that drives the ultrasonic transmitter, and the ultrasonic wave receiver. comprising a receiving section that receives the output of the sonic wave receiver and a time measurement circuit,
An ultrasonic coated wire measuring instrument that measures the time from a time when transmission of an ultrasonic signal in the ultrasonic transmitter stops to a time when reception of the ultrasonic signal ends in the receiver, wherein the measuring tool is located at the center of the lower surface thereof. The sound insulating material has a channel-shaped casing in which a support rod is vertically disposed, and a sound insulating material disposed inside the casing in which a groove opening upward in the length direction is formed. The ultrasonic transmitter and the ultrasonic receiver are disposed inside the housing at a predetermined distance in the length direction of the housing and facing the groove. Sonic coated wire measuring device.