阅读说明：本技术 一种水雷探测系统 (Mine detection system ) 是由 张恒 许杰 付继伟 杨振宇 陈韶华 曹振宇 于 2020-12-07 设计创作，主要内容包括：本公开的水雷探测系统,通过包括多个环形子阵、消声橡胶板和水雷圆柱雷体；其中,所述多个环形子阵套嵌在所述水雷圆柱雷体上,所述消声橡胶板贴附在所述水雷圆柱雷体表面上,所述环形子阵之间贴覆有所述消声橡胶板。能够使环形子阵达到与水雷圆柱雷体共形的效果,避免产生突起部位引入流噪声,同时降低水雷圆柱雷体反射带来的障板效应,解决由单个换能器构成舷侧线列阵带来的等效声中心不在水雷圆柱雷体中心轴线上、水平指向性不严谨的全向接收、输出阻抗较高等问题。(The mine detection system comprises a plurality of annular sub-arrays, a noise elimination rubber plate and a mine cylindrical mine body; the plurality of annular sub-arrays are sleeved on the cylindrical mine body, the silencing rubber plates are attached to the surface of the cylindrical mine body, and the silencing rubber plates are attached between the annular sub-arrays. The toroids can achieve the effect of conforming to the torpedo cylindrical mine, the flow noise introduced by the raised part is avoided, the baffle effect brought by the reflection of the torpedo cylindrical mine is reduced, and the problems that the equivalent sound center brought by the broadside line array formed by a single transducer is not on the central axis of the torpedo cylindrical mine, the horizontal directivity is not strict, the omnidirectional receiving is realized, the output impedance is higher and the like are solved.)

1. A mine detection system, the system comprising: a plurality of annular sub-arrays, a silencing rubber plate and a torpedo cylindrical detonator body; the plurality of annular sub-arrays are sleeved on the cylindrical mine body, the silencing rubber plates are attached to the surface of the cylindrical mine body, and the silencing rubber plates are attached between the annular sub-arrays.

2. The system of claim 1, wherein the annular sub-array is formed by uniformly arranging and splicing a plurality of sheet-shaped piezoelectric transducers.

3. The system of claim 2, wherein the plurality of sheet-form piezoelectric transducers are connected in parallel to form a virtual array element, and an equivalent acoustic center of the virtual array element coincides with a central axis of the annular sub-array.

4. The system of claim 2, wherein the outer diameter of the annular sub-array is less than or equal to one twentieth of the wavelength of the acoustic signals received by the system.

5. The system of claim 1, wherein the distance between two adjacent annular sub-arrays is one-half of the wavelength of the lower operating frequency of the system.

6. The mine detection system of claim 1, wherein the sound dampening rubber plate is made of sound absorbing rubber and is arcuate in cross-section.

7. The system of claim 1, wherein the annular subarray and the noise damping rubber plate form a cylindrical conformal acoustic array that conforms to the cylindrical mine.

8. The system of claim 1, wherein the plurality of annular sub-arrays are uniformly nested on the cylindrical mine along a central axis of the cylindrical mine to form an array of virtual lines.

Technical Field

The disclosure belongs to the technical field of mine detection, and particularly relates to a mine detection system.

Background

In order to meet the detection function requirement of the underwater target, the detection system of the water mine weapon usually adopts a method that a plurality of acoustic transducers form a sensor array. According to the basic principle of water acoustics, the more the number of transducers forming the array is, the higher the gain of array signal processing is, and the better the detection effect on the targets in water is. In the past, the mine weapon detection system usually requires a series of single transducers to be arranged on a corresponding hole seat arranged on one side of a mine shell to form a linear hydrophone array, which is also called a broadside array.

The gunwale linear array is arranged on one side of the mine body and is not overlapped with the central axis of the mine body, so that a distance error of the radius of the mine body exists, and the reference origin of the system for positioning the target by the mine target detection, navigation control and the like takes the central axis of the mine body as the vertical axial direction of a coordinate system, so that when the anchoring system mine weapon platform is put into water to work, the phenomena of rotation, roll and the like are generated under the influence of ocean currents, and the change of the roll angle of the mine target detection system introduces the change of the relative position of the target and the gunwale array, so that the detection result is influenced; in addition, when the performance of the detection system is debugged and calibrated under the near-field condition in the anechoic pool, the influence of position errors caused by the rotation of the detonator is more serious. Meanwhile, due to the action of the baffle effect of the lightning body, the linear array broadside array arranged on one side of the lightning body generates non-uniform change on receiving directivity in the horizontal direction, and the influence is more obvious as the frequency is higher.

In addition, the broadside linear array formed by single transducers, the single piezoelectric transducer forming each array element has a relatively high output impedance due to the limitation of scale and relatively small static capacitance, so that the sensitivity loss of the front end of the detection system is reduced, the integrity of signal acquisition is improved, the input impedance of a signal conditioning circuit matched with the piezoelectric transducer is higher in order, a high-input impedance type circuit needs a high-resistance matching resistor, and the high-resistance matching resistor has the characteristics of self thermal noise and relatively high current-voltage noise, so that relatively high self noise can be caused, and the problem of easy interference is caused.

Disclosure of Invention

In view of the above, the present disclosure provides a mine detection system, which can make an annular sub-array achieve an effect conformal to a mine cylindrical mine body, avoid generation of flow noise introduced from a protruding portion, reduce a baffle effect caused by reflection of the mine cylindrical mine body, and solve the problems of an equivalent acoustic center caused by a broadside line array formed by a single transducer not being on a central axis of the mine cylindrical mine body, omnidirectional reception with an imprecise horizontal directivity, high output impedance, and the like.

According to an aspect of the present disclosure, the present disclosure proposes a mine detection system, the system comprising: a plurality of annular sub-arrays, a silencing rubber plate and a torpedo cylindrical detonator body; the plurality of annular sub-arrays are sleeved on the cylindrical mine body, the silencing rubber plates are attached to the surface of the cylindrical mine body, and the silencing rubber plates are attached between the annular sub-arrays.

In a possible implementation manner, the annular sub-array is formed by uniformly arranging and splicing a plurality of sheet-shaped piezoelectric transducers.

In one possible implementation manner, the plurality of sheet-shaped piezoelectric transducers are connected in parallel to form a virtual array element, and an equivalent acoustic center of the virtual array element is coincident with a central axis of the annular sub-array.

In one possible implementation, the outer diameter of the annular sub-array is less than or equal to one twentieth of the wavelength of the sound wave signal received by the mine detection system.

In one possible implementation, the distance between two adjacent annular sub-arrays is one half of the wavelength of the lower limit operating frequency of the mine detection system.

In one possible implementation, the sound-deadening rubber plate is made of sound-deadening rubber, and has an arc-shaped cross section.

In a possible implementation manner, the annular subarray and the noise elimination rubber plate form a cylindrical conformal acoustic array conformal with the torpedo cylindrical detonator.

In one possible implementation, the plurality of annular sub-arrays are uniformly nested on the torpedo cylindrical mine body along the central axis of the torpedo cylindrical mine body to form a virtual line array.

The mine detection system comprises a plurality of annular sub-arrays, a noise elimination rubber plate and a mine cylindrical mine body; the plurality of annular sub-arrays are sleeved on the cylindrical mine body, the silencing rubber plates are attached to the surface of the cylindrical mine body, and the silencing rubber plates are attached between the annular sub-arrays. The annular subarray can achieve the effect of conforming to the torpedo cylindrical lightning body, flow noise caused by the fact that protruding parts are generated is avoided, and meanwhile the baffle effect caused by reflection of the torpedo cylindrical lightning body is reduced.

Other features and aspects of the present disclosure will become apparent from the following detailed description of exemplary embodiments, which proceeds with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments, features, and aspects of the disclosure and, together with the description, serve to explain the principles of the disclosure.

FIG. 1 shows a schematic structural diagram of a mine detection system according to an embodiment of the present disclosure;

FIG. 2 shows a schematic structural diagram of an annular subarray of a mine detection system according to an embodiment of the present disclosure;

FIG. 3 illustrates a schematic connection diagram of a sheet-shaped piezoelectric transducer of an annular sub-array of a mine detection system according to an embodiment of the present disclosure;

FIG. 4 shows a schematic diagram of the output equivalent impedance of a single sheet-shaped piezoelectric transducer of an annular sub-array of a mine detection system according to an embodiment of the present disclosure.

Detailed Description

Various exemplary embodiments, features and aspects of the present disclosure will be described in detail below with reference to the accompanying drawings. In the drawings, like reference numbers can indicate functionally identical or similar elements. While the various aspects of the embodiments are presented in drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

The word "exemplary" is used exclusively herein to mean "serving as an example, embodiment, or illustration. Any embodiment described herein as "exemplary" is not necessarily to be construed as preferred or advantageous over other embodiments.

Furthermore, in the following detailed description, numerous specific details are set forth in order to provide a better understanding of the present disclosure. It will be understood by those skilled in the art that the present disclosure may be practiced without some of these specific details. In some instances, methods, means, elements and circuits that are well known to those skilled in the art have not been described in detail so as not to obscure the present disclosure.

Fig. 1 shows a schematic structural diagram of a mine detection system according to an embodiment of the present disclosure. As shown in fig. 1, the detection system may include: a plurality of annular sub-arrays such as an annular sub-array 1#, annular sub-arrays 2#, …, an annular sub-array n #, a silencing rubber plate 1 and a torpedo cylindrical lightning body 2. A plurality of annular sub-arrays such as an annular sub-array 1#, an annular sub-array 2#, … and an annular sub-array n # are nested on the torpedo cylindrical lightning body 2, a silencing rubber plate 1 is attached to the surface of the torpedo cylindrical lightning body 2, and silencing rubber plates 1 are also attached among the annular sub-array 1#, the annular sub-array 2#, … and the annular sub-array n #.

The mine detection system comprises a plurality of annular sub-arrays, a noise elimination rubber plate and a mine cylindrical mine body; the plurality of annular sub-arrays are sleeved on the cylindrical mine body, the silencing rubber plates are attached to the surface of the cylindrical mine body, and the silencing rubber plates are attached between the annular sub-arrays. The annular subarray can achieve the effect of conforming to the torpedo cylindrical lightning body, flow noise caused by the fact that protruding parts are generated is avoided, and meanwhile the baffle effect caused by reflection of the torpedo cylindrical lightning body is reduced.

Fig. 2 shows a schematic structural diagram of an annular sub-array of a mine detection system according to an embodiment of the present disclosure.

In one possible implementation, as shown in fig. 2, the annular sub-array may be formed by uniformly arranging and splicing a plurality of sheet-shaped piezoelectric transducers. For example, a plurality of sheet-shaped piezoelectric transducers can be uniformly distributed, spliced and integrally encapsulated to form an annular sub-array, the plurality of annular sub-arrays are sleeved on the cylindrical mine shell and are attached to the outer surface of the mine cylindrical mine shell to form a conformal array.

In one possible implementation mode, a plurality of sheet-shaped piezoelectric transducers are connected in parallel to form a virtual array element, and the equivalent acoustic center of the virtual array element is coincided with the central axis of the annular sub-array.

Each sheet-shaped piezoelectric transducer is provided with a support structure and a lead wire which are independent, and all the sheet-shaped piezoelectric transducers in the annular sub-array can be connected in parallel through the lead wires to form a virtual array element. As shown in fig. 1, a plurality of sheet-shaped piezoelectric transducers are uniformly distributed, the geometric center (on the central axis) of the equivalent acoustic center annular sub-array thereof is also said to be on the central axis inside the torpedo cylindrical mine, and the reception directivity in the horizontal direction is omnidirectional.

FIG. 3 shows a schematic connection diagram of a sheet-shaped piezoelectric transducer of an annular sub-array of a mine detection system according to an embodiment of the present disclosure. FIG. 4 shows a schematic diagram of the output equivalent impedance of a single sheet-shaped piezoelectric transducer of an annular sub-array of a mine detection system according to an embodiment of the present disclosure.

As shown in fig. 3, the patch piezoelectric transducer T1, the patch piezoelectric transducer T2, the patch piezoelectric transducer T3, the patch piezoelectric transducer T4 and the patch piezoelectric transducer T5 form an annular sub-array in a parallel connection manner, that is, the positive and negative plate leads of the patch piezoelectric ceramic plates are respectively connected in parallel, so as to reduce the output impedance of the annular sub-array patch transducer.

As shown in fig. 4, the output equivalent impedance of a single sheet-shaped piezoelectric transducer of an annular sub-array is:wherein R is_GIs the impedance of the piezoelectric transducer and,is capacitive reactance of piezoelectric transducer.

Then, the equivalent output complex impedance of the 5 sheet-shaped piezoelectric transducers of the annular sub-array shown in fig. 3 when connected in parallel is:i.e. having n sheet-shaped piezoelectric transducers in an annular sub-arrayIts output impedance is n times smaller than that of the single chip piezoelectric transducer.

Through parallelly connected with the inside slice piezoelectric transducer of annular subarray, can improve the static electric capacity of virtual array element, reduce the output impedance of sensor to reduced the design requirement to mine detection system matching circuit, increased the receiving area of single virtual array element simultaneously, improved the sensitivity of single virtual array element.

In one possible implementation, a plurality of annular sub-arrays may be uniformly nested on a torpedo cylinder along a central axis of the torpedo cylinder to form a virtual line array.

As shown in fig. 1, a plurality of annular sub-arrays (a plurality of annular virtual array elements) such as an annular sub-array 1#, an annular sub-array 2#, …, an annular sub-array n #, and the like are uniformly arranged along the central axis of the cylindrical mine cylinder, the equivalent acoustic centers of the virtual array elements fall on the central axis of the cylindrical mine cylinder, and a linear array is equivalently formed.

In one possible implementation, the outer diameter of the annular sub-array is less than or equal to one twentieth of the wavelength of the sound wave signal received by the mine detection system.

As can be seen from the basic principles of hydroacoustics, the upper limit of the operating frequency of the circular sub-array should be limited to satisfy horizontal omnidirectional reception. The outer diameter of the annular sub-array (the annular virtual array element) is smaller than the wavelength of the sound wave received by the mine detection system, for example, 1/20 (one twentieth) of the wavelength of the sound wave can be taken in engineering design, and the wavelength of the sound wave signal received by the mine detection system is larger than 20 times of the outer diameter D of the annular sub-array, that is, the outer diameter D of the annular sub-array (the annular virtual array element) is larger than thatUpper limit operating frequency of annular sub-arrayWherein the sound velocity in water is taken to be approximately 1500 m/s.

Similarly, the upper limit working frequency of the annular sub-array can be limited, so that the horizontal receiving directivity of the annular sub-array can meet the omnidirectional requirement. For example, the outer part of the annular sub-arrayDiameter of a pipeWherein, c₀The sound velocity in water is taken as approximate value 1500m/s, if the outer diameter D of the annular sub-array is taken as 0.5m, the upper limit working frequency of the annular sub-array isBy defining the outer diameter of the annular subarray or the upper limit operating frequency of the annular subarray, the reception directivity of the annular subarray in the horizontal direction can be made omnidirectional.

In one possible implementation, the distance between two adjacent annular sub-arrays is one half of the wavelength of the lower limit operating frequency of the mine detection system.

For example, the spacing between the annular sub-arrays (virtual array elements) may be 1/2 of the lower operating frequency wavelength of the mine detection system, i.e.: annular subarray (virtual array element) spacing:wherein lambda is the wavelength of the lower limit working frequency of the mine detection system.

As shown in fig. 1, if 4 annular sub-arrays, that is, the annular sub-array 1#, the annular sub-array 2#, the annular sub-array 3#, and the annular sub-array 4# are uniformly arranged from top to bottom along the central axis of the torpedo cylinder, and are nested and installed on the torpedo cylinder 2, the silencing rubber plate 1 is attached between the annular sub-arrays, and the distance d between the annular sub-arrays satisfies:and lambda is the lower limit working frequency wavelength of the mine detection system. For example, the wavelength λ when the lower limit operating frequency of the mine detection system takes 150Hz is:the distance d between the annular sub-arrays is:i.e. the spacing between the subarrays is 5m, 4The annular sub-arrays are uniformly arranged and distributed according to the interval of 5 meters to form a virtual linear array with the length of 20 meters. By setting the upper limit of the working frequency of the virtual array elements and the distance between the annular sub-arrays, a plurality of annular sub-arrays (virtual array elements) form a virtual linear array and are arranged along the axis of the torpedo cylindrical lightning body, so that the equivalent acoustic center of each virtual array element is on the central axis of the lightning body.

In one possible implementation, the sound-deadening rubber sheet may be made of sound-deadening rubber having an arc-shaped cross section. And the annular subarrays and the silencing rubber plates form a cylindrical conformal acoustic array conformal with the torpedo cylindrical detonator body.

As shown in fig. 1, after the chip-shaped piezoelectric transducer unit sub-array is installed on the surface of the shell of the cylindrical mine body (instrument cabin section) of the mine detection system, although the chip-shaped piezoelectric transducer unit module adopts a chip-shaped sensitive structure, the overall thickness is greatly reduced compared with that of the conventional annular transducer, the chip-shaped piezoelectric transducer unit module still protrudes out of the surface of the shell of the instrument cabin section. The acoustic matrix is not only easily damaged by collision, scraping and other mechanical damages, but also can bring adverse consequences such as increase of underwater self-noise, reduction of underwater mooring stability and the like, therefore, the blank part between the annular sub-array units of the sheet-shaped piezoelectric transducer at the instrument cabin section is filled with the noise elimination rubber plate 1, the noise elimination rubber plate 1 can be a flow guide device which is made of sound absorption rubber and has an arc-shaped cross section, can be attached to the surface of a shell of the cylindrical mine body (instrument cabin section) section, and forms a complete cylindrical surface together with the module of the sheet-shaped piezoelectric transducer unit to form a cylindrical co-shaped acoustic matrix conformal with the cylindrical mine body (instrument cabin section). Through the sound absorption and flow guide effects of the noise elimination rubber plate 1, the underwater noise can be restrained, and meanwhile, the phenomenon that underwater incident sound waves are reflected on the surface of a shell of a cylindrical mine body (instrument cabin section) section to generate surrounding waves is avoided.

Having described embodiments of the present disclosure, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen in order to best explain the principles of the embodiments, the practical application, or improvements made to the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.