KR101469626B1 - Manufacturing Method of Signal Conditioning Plate with Variable Standoff Distance - Google Patents

Abstract

Provided is a method for manufacturing a signal adjusting plate and adjusting a standoff distance using the same. The method includes the steps of: installing a fixing casing to a fixing unit and fitting a hydrophone into the fixing casing to be fixed; forming a hydrophone hole to allow the hydrophone to penetrate in a vertical moving unit and locating the vertical moving unit to be placed apart from the fixing unit at a predetermined interval in the upper part of the fixing unit; installing a height adjusting unit between the fixing unit and the vertical moving unit to structurally connect the fixing unit and the vertical moving unit; and vertically moving the vertical moving unit through a self-expansion or self-contraction operation of the height adjusting unit to adjust a distance between the fixing unit and the vertical moving unit, so a standoff distance between the hydrophone and the vertical moving unit can be adjusted. According to the present invention, an area unable to be measured by the hydrophone is avoided by suitably adjusting the standoff distance for a frequency band of a noise to be measured during underwater noise measurement, and the fixing state of the hydrophone is not disassembled by firmly fixing the hydrophone to the signal adjusting plate even though the hydrophone receives external force while being exposed to the underwater environment, thereby preventing signals from being unavailable to use due to the immeasurable area generated in a certain frequency band during underwater noise measurement or preventing reliability of measurement results from being reduced.

Description

Technical Field [0001] The present invention relates to a method of adjusting a standoff distance,

The present invention relates to a signal control panel capable of adjusting a standoff distance in accordance with a frequency band of a noise to be measured at the time of measurement of underwater noise, and capable of firmly fixing the hydrophone.

The underwater hydrophone 40 measures the noise in the water, and a plurality of hydrophones 40 are arranged in order to increase the degree of measurement (FIG. 1). A plate that fixes the hydrophone 40 for the arrangement of the plurality of hydrophones 40 is called a signal conditioning plate 50. The purpose of the signal regulating plate 50 is to fix the individual hydrophone 40 to a specific position and to control the magnitude of the signal.

At this time, the principle of controlling the size of the signal by the signal regulating plate 50 is as follows. 2, the incident wave Pi directly transmitted to the hydrophone 40 in the water and the reflected wave Pr from the signal regulating plate 50 are transmitted to the hydrophone 40 fixed by the signal regulating plate 50 Simultaneously. The reflection angle r of the reflected wave Pr at this time is the same as the incident angle i of the incident wave Pi when the signal control plate 50 is a flat plate. The signal measured by the hydrophone 40 can be expressed by the following equation.

P = Pi + Pr = (1 + ^{Re2ikdcos (r)} ) Pi [Expression 1]

In Equation 1, R is a reflection coefficient, and in general, when the signal regulating plate 50 is an iron plate, the acoustic impedance difference with water is large and approaches 1. k is the wave number and d is the standoff distance which is the distance between the upper end of the hydrophone 40 and the surface of the signal control plate 50. [ At this time, there is a phase difference of 2 kdcos (r) between the incident wave and the reflected wave. Interference between the incident wave and the reflected wave occurs by this phase difference, and the magnitude of the signal is determined accordingly.

When the distance between the upper end of the hydrophone 40 and the surface of the signal regulating plate 50 is 0, that is, when the standoff distance is 0, there is no phase difference between the incident wave and the reflected wave. Therefore, Occurs. Therefore, when the standoff distance is 0 as shown in FIG. 3, the signal control board 50 can obtain a signal gain (SR) of about 6 dB. In this case, the signal gain is defined by the following equation (2).

SR = 20log10 [(Pi + Pr) / Pi] (dB) [Equation 2]

However, as described above, when the standoff distance is 0, it is very difficult to actually implement the system. Most of the hydrophone units 40, which are commercially available, are mounted on the upper portion of the hydrophone 40 It should be fixed in such a manner that its end protrudes above the surface of the signal regulating plate 50. Therefore, the standoff distance d can not be zero, and the standoff distance depends on each hydrophone 40.

If the standoff distance is not 0, there is a phase difference between the incident wave and the reflected wave according to the standoff distance, and the characteristic according to the frequency is exhibited. 4 is a graph illustrating a result of calculating a signal gain according to an incident angle in the hydrophone 40 having a standoff distance of 1 cm in a conventional signal control plate 50 made of a steel plate having a thickness of 1 cm. In FIG. 4, the frequency domain in which the signal gain is positive is the domain in which the constructive interference occurs, and the frequency domain in which the signal gain is negative is the domain in which destructive interference occurs. The destructive interference is a phenomenon inevitably caused by the phase difference due to the standoff distance.

However, when destructive interference occurs due to the phase difference due to the standoff distance, a strong signal loss occurs in a specific frequency band (40 kHz, 45 kHz, and 75 kHz in FIG. 4) There is a problem that the reliability of the measurement result is deteriorated as a whole. Normally, the frequency band where the signal gain is -6 dB or less is referred to as an unmeasurable region. This unmeasurable region varies depending on the standoff distance.

In addition, in the case of the hydrophone 40, there is another important factor that decreases the reliability of the measurement result in addition to the phase difference due to the standoff distance. That is, the hydrophone 40 is exposed to the underwater environment to be. In water, there is always a flow of water such as waves or currents, and the hydrophone 40 is subjected to an external force accordingly. In this case, if the external force applied to the hydrophone 40 exceeds a specific size, the hydrophone 40 may be shaken, tilted, or severed from the signal control plate 50. If the magnitude of the signal measured by the hydrophone 40 is not constant and changes randomly, or if the signal is too severe, the measurement of the signal becomes impossible and the reliability of the measurement result is deteriorated as a whole. Therefore, it is necessary to solve the above problems.

Microfluidic flow sensor and hydrophone using the same (Patent Application No. 10-2009-0000651)

Disclosure of the Invention The present invention has been proposed in order to solve the above problems. It is an object of the present invention to provide a signal control panel capable of adjusting a standoff distance suitable for a frequency band of a noise to be measured during underwater noise measurement, The purpose is to provide.

According to an aspect of the present invention, there is provided a method of manufacturing a portable terminal, comprising: fixing a fixed casing to a fixed portion and fixing a hydrophone to the fixed casing; (EN) A sound hole is formed in an eastern part of a room to allow the hydrophone to penetrate through the sound hole, and the upper and lower parts are spaced apart from the fixing part by a predetermined distance. A step of providing a height adjusting part between the fixing part and the elevating part to structurally connect the fixing part and the elevating part; And adjusting the standoff distance between the hydrophone and the up / down moving part by adjusting the distance between the fixed part and the up / down moving part by vertically moving the up / down moving part through the action of the height adjusting part itself expanding or contracting And a method of controlling the standoff distance through the manufacture of the signal control board.

In the present invention, a plurality of the fixed casings are provided in the fixed portion so that a plurality of the hydrophones may be arranged.

In the present invention, the fixed casing serves also as an adapter.

In the present invention, the fixing portion is formed in a flat plate shape whose surface is not uneven so that the hydrophone can be fixed in a state of standing upright with respect to the fixed portion.

In the present invention, the fixing portion is formed of a steel plate having rigidity for firmly fixing the hydrophone.

In the present invention, the up and down moving parts are formed in a flat plate shape so as to prevent irregular reflection.

In the present invention, the upper and lower parts are formed of a steel plate having rigidity.

In the present invention, the height adjusting unit may include an actuator.

According to the present invention, by adjusting the standoff distance in accordance with the frequency band of the noise to be measured in the measurement of underwater noise, it is possible to avoid the impossibility of measuring the hydrophone, and the hydrophone is securely fixed to the signal- Even if the hearing instrument is exposed to the underwater environment and receives an external force, the fixed state is not disassembled. Therefore, there is no problem that the signal can not be utilized due to the unmeasurable region occurring in a specific frequency band when the underwater noise measurement is performed or the reliability of the measurement result is low.

Figure 1 is an example of a conventional signal control panel for hydrophone and hydrophone arrangement.
Fig. 2 is an explanatory view of a principle of controlling a signal size with a signal control board. Fig.
3 shows the signal gain calculation result of the signal control panel when the standoff distance is zero.
4 shows the signal gain calculation result of the signal control panel when the standoff distance is 1 cm.
5 shows a configuration of a signal control board according to the present invention.
Figure 6 is a working principle of a signal control panel according to the present invention.
7 is a signal gain comparison of the present invention utilizing two standoff distances.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

5 shows a configuration of a signal control board according to the present invention. And FIG. 6 shows the operation principle of the signal control panel according to the present invention.

The object of the present invention is to provide a signal control panel capable of adjusting a standoff distance in accordance with a frequency band of a noise to be measured at the time of measurement of underwater noise and securely fixing the hydrophone (40) The manufacture of the signal control panel according to the invention and the adjustment of the standoff distance therefrom are carried out according to the following procedure.

First, the fixed casing 11 is installed in the fixing part 10 and the hydrophone 40 is fixed to the fixed casing 11. Next, a sound hole (21) through which the hydrophone (40) can penetrate can be formed in the upper and lower parts (20), and the upper and lower movable parts (20) Position. A height adjusting portion 30 is provided between the fixing portion 10 and the upper moving portion 20 to structurally connect the fixing portion 10 and the upper moving portion 20 with each other. Next, the height adjusting part 30 self-expands or contracts to move the vertical moving part 20 up and down to adjust the distance between the fixed part 10 and the vertical moving part 20, And adjusts the standoff distance between the upper and lower shrouds (20).

Therefore, the signal control board according to the present invention includes the fixing part 10, the upper and lower movable parts 20 and the height adjusting part 30. Hereinafter, the configuration and operation principle of the signal control panel according to the present invention will be described in detail.

As shown in FIG. 5, the fixing unit 10 is a lower structure of the signal control panel according to the present invention. The fixing unit 10 includes a fixed casing 11 capable of fixing the hydrophone 40 (FIG. 6). Therefore, when the hydrophone 40 is inserted into the fixed casing 11 at the time of measurement of the underwater noise, the hydrophone 40 is fixed to the fixing part 10.

In this case, in order to increase the degree of measurement, it is general that a plurality of hydrophones 40 are arranged and used. Therefore, it is preferable that the fixing unit 10 further includes a plurality of fixed casing 11. In this case, since the fixed casing 11 plays the role of the adapter at the same time, when the signal line 12 is connected to the fixed casing 11, the hydrophone 40 can receive the measured signal (FIG. 6).

It is preferable that the fixing part 10 is formed in a flat plate shape whose surface is not uneven so that the hydrophone 40 can be fixed upright with respect to the fixing part 10 and the fixing of the hydrophone 40 In this case, the fixing portion 10 serves as a basic structural member that allows each hydrophone 40 to be accurately and firmly attached to the designed position.

As shown in FIGS. 5 and 6, the upper and lower portions 20 are spaced apart from the fixing portion 10 by a predetermined distance on the upper portion of the fixing portion 10. And a height adjusting portion 30 is provided between the upper and lower shank portions 20 and the fixing portion 10. Therefore, in the signal control panel according to the present invention, the fixing portion 10, the upper and lower movable portions 20, and the height adjusting portion 30 are combined to form an integral body.

5). In this case, the sound hole 21 penetrates through the up / down moving part 20 in the up and down direction (see FIG. 5) (Fig. 6). At this time, if the air hole 21 is formed in advance in the upper and lower movable portions 20 in the number corresponding to the size of the hydrophone 40 and the number of the respective hydrophone devices 40 corresponding to the designed position precisely (FIG. 5) The installation work of the hydrophone set 40 for measurement and the signal control panel according to the present invention can be performed much more quickly and easily.

The height adjusting portion 30 is structured to connect the up and down moving portion 20 and the fixing portion 10 and to adjust the distance between the up and down moving portion 20 and the fixing portion 10 through an action of self- . In this case, the height regulating portion 30 can be any shape as long as it has a rigidity enough to support the up-and-down moving portion 20 and can act to inflate or shrink at the same time. Typically, Actuators that operate by means of these may be applicable.

The height adjusting portion 30 adjusts the distance between the upper and lower movable portions 20 and 10 so that the standoff distance d, which is the distance between the upper end of the hydrophone 40 and the surface of the movable upper portion 20, (Fig. 6). Hereinafter, the operation and effect of the elevation portion 20 and the height adjusting portion 30 will be described in detail.

6, an incident wave transmitted directly to the hydrophone 40 in water and a reflected wave from the up-and-down moving unit 20 are simultaneously measured in the hydrophone 40 at the time of measuring underwater noise. At this time, the upper and lower shrouds 20 are preferably formed in a flat plate shape to prevent irregular reflection, and it is preferable that the upper and lower shrouds 20 are made of an iron plate having rigidity for rigid fixing of the hydrophone 40.

The reflection angle of the reflected wave transmitted to the hydrophone 40 is equal to the incident angle of the incident wave when the up / down moving part 20 is a flat plate. At this time, there is a phase difference between the incident wave and the reflected wave. This phase difference causes interference between the incident wave and the reflected wave, and thus the magnitude of the signal is determined. 6, the upper end of the hydrophone 40 is fixed on the surface of the upper movable part 20, as shown in FIG. Therefore, the standoff distance d between the hydrophone 40 and the up-and-down moving unit 20 can not be zero, and the standoff distance depends on the hydrophone 40.

However, when the destructive interference occurs due to the phase difference due to the standoff distance, a strong signal loss occurs in a specific frequency band in severe cases, so that the signal in the frequency band can not be utilized and the reliability of the measurement result is deteriorated have. Normally, the frequency band where the signal gain is -6 dB or less is referred to as an unmeasurable region. This unmeasurable region varies depending on the standoff distance.

The present invention utilizes the fact that the unmeasurable area varies depending on the standoff distance as described above. Rather, by adjusting the standoff distance, the unmeasurable area deviates from the frequency range of noise to be measured. Therefore, even if the unmeasurable area still appears, the present invention does not appear in the frequency band of the noise to be measured, so that the hydrophone 40 can normally measure the desired noise regardless of the unmeasurable area .

The operation and effect of the present invention as described above will be described in more detail with reference to FIGS. 6 and 7. FIG. 6 shows a case where the standoff distance d is 5 or 10 when the height adjusting portion 30 is operated. In the embodiment of FIG. 7, the signal gain (solid line) when the standoff distance is 5 and the signal gain (dotted line) when the standoff distance is 10 are shown. In Fig. 7, in the case where the standoff distance is 5, the measurement impossible area is 65 to 90 kHz, and in the case of 10, the measurement impossible area is about 35 to 45 kHz.

Therefore, in the case of the present invention, if the frequency band of the noise to be measured is concentrated in the vicinity of 35 to 45 kHz, the standoff distance is adjusted to 5 by using the height adjuster 30 (of course, It is noted that the standoff distance should be avoided to 10, and it is also possible to adjust the standoff distance to a length other than 5, as long as the unmeasurable region can be prevented from appearing in the vicinity of 35 to 45 kHz) If the frequency band of the noise to be measured is concentrated in the vicinity of 65 to 90 kHz, the standoff distance is adjusted to 10 using the height adjuster 30, so that the noise can be normally measured regardless of the unmeasurable region.

As described above, the upper and lower hoist ropes 20 serve to move the frequency band of the noise to be measured out of the measurement impossible area according to the operation of the height adjuster 30. In addition, the hydroengineer 40 surrounds the hydrophone 40 ) Is fixed firmly so as not to be shaken.

That is, as shown in FIG. 6, when the up / down moving part 20 is mounted on the upper part of the fixing part 10 and surrounded by the hydrophone 40, the hydrophone 40 is exposed to the underwater environment (The upper and lower shrouds 20 serve to block the external force applied to the hydrophone 40 or the fixing unit 10 in a primary way), and therefore an external force due to the flow of water such as waves or currents It is possible to prevent the water hammer 40 from being totally applied. Therefore, in this case, when the hydrophone 40 is shaken, tilted or severely tilted due to external force, there is no possibility that the hydrophone 40 will be detached from the fixing part 10. If the hydrophone 40 is maintained in a firmly fixed state despite the external force, the magnitude of the signal measured by the hydrophone 40 can be kept constant, The problem that the signal can not be measured does not occur.

As described above, according to the present invention, it is possible to avoid the unmeasurable area of the hydrophone 40 by adjusting the standoff distance in accordance with the frequency band of the noise to be measured in the measurement of underwater noise, The hydrophone 40 is firmly fixed and the hydrophone 40 is exposed to the underwater environment and receives the external force, so that the fixed state is not disassembled. Therefore, there is no problem that the signal can not be utilized due to the unmeasurable region occurring in a specific frequency band when the underwater noise measurement is performed or the reliability of the measurement result is low.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and accompanying drawings. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: fixing part 11: fixed casing
12: Signal line 20: Shanghai east
21: sound hole 30: height adjusting portion
40: hydrophone 50: signal control panel

Claims (8)

Fixing the fixed casing (11) to the fixed casing (10) and fixing the hydrophone (40) to the fixed casing (11);
A sound hole (21) through which the hydrophone (40) can penetrate is formed in the upper and lower shrouds (20), and the upper and lower movable parts (20) As shown in Fig.
A height adjusting unit 30 is provided between the fixing unit 10 and the elevating moving unit 20 to structurally connect the fixing unit 10 and the elevating moving unit 20;
The height adjusting unit 30 may be moved up and down through the self expanding or contracting action to adjust the distance between the fixing unit 10 and the elevating moving unit 20 so that the hydrophone 40 ) And the up-and-down moving part (20);
And adjusting a standoff distance therefrom. The method according to claim 1,
Wherein a plurality of the fixed casings (11) are installed in the fixing part (10) so that a plurality of the hydrophones (40) can be arranged in the fixing part (10). The method according to claim 1,
Characterized in that the fixed casing (11) also acts as an adapter. The method according to claim 1,
Wherein the fixing part (10) has a flat plate shape whose surface is not uneven so that the hydrophone (40) can be fixed upright with respect to the fixing part (10). To adjust the standoff distance. The method according to claim 1,
Wherein the fixing part (10) is made of a rigid steel plate for rigid fixing of the hydrophone (40), and a method for adjusting a standoff distance therefrom. The method according to claim 1,
Wherein the upper and lower movable parts (20) are formed in a flat plate shape to prevent irregular reflection, and a method of adjusting a standoff distance therefrom. The method according to claim 1,
Wherein the upper and lower movable parts (20) are made of a steel plate having rigidity, and a method of adjusting a standoff distance therefrom. The method according to claim 1,
Wherein the height adjusting part (30) is formed of an actuator, and a method of adjusting the standoff distance through the manufacturing of the signal adjusting plate.

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