KR100662801B1 - Laminated composite panel-form loudspeaker - Google Patents

Abstract

It is a panel speaker comprising a composite laminate that generates amplification effect by driving, and a seismic device for driving the composite laminate to drive the composite laminate. The composite laminate having the loudspeaker capability has several specific fiber angles and orthogonal materials. Laminated by the fiber-reinforced composite layer provided, and on the edges around the laminate plate there are additionally formed bushing strips having different strengths, and these bushing strips are such that the sound pressure sensitivity within a specific frequency range is more uniformly distributed. To adjust the vibration mode. On the other hand, in order to improve the amplification efficiency of the composite laminate, the area of the laminate is divided into two amplification regions of high efficiency and low efficiency, and the seismic separator is fixed on a predetermined position in a high efficiency region of the laminate. . On the periphery of the composite laminate, a soft hanging system for supporting the composite laminate for the amplification is connected. In this suspension system, a noise generated on the periphery of the amplification plate is removed by a tamper.

Composites, laminates, diaphragms, panels, speakers, amplification

Description

Laminated composite panel-form loudspeaker

1 is a schematic diagram showing a composite laminate panel type speaker of the present invention.

FIG. 2 (a) is a cross-sectional view of FIG. 1 in which the hanging systems on both the left and right sides of the panel-type speaker are made using a foamed rubber strip and a liquid-containing flexible rubber cotton cloth, respectively.

FIG. 2 (b) is a locally enlarged view of FIG. 1 in which the system for suspending the expansion plate is made of cobweb-like soft plastic.

FIG. 3A is a sectional view taken along the line A-A in FIG. 1.

FIG. 3B is a cross-sectional view taken along line B-B in FIG. 1.

FIG. 4 (a) is a diagram illustrating an electromagnetic coil type diaphragm in which upward slats are generated as current flows from the top of the coil to the bottom to move the coil up.

Figure 4 (b) is a diagram showing an electronic coil type derailleur in which current flows from the bottom of the coil to the top of the coil and moves downward under the coil.

5 is a diagram showing a state in which four electromagnetic coil type diaphragms are arranged in the high-efficiency amplification area of the amplification plate.

FIG. 6 is a view showing a state in which four electromagnetic coil type diaphragms which are other embodiments are arranged in the high-efficiency amplification region of the amplification plate.

FIG. 7 is a view showing a state in which eight electromagnetic coil diaphragms which are still other embodiments are arranged in the high-efficiency amplification region of the amplification plate.

FIG. 8 is a view showing a state in which eight diaphragms as another embodiment are arranged in the high-efficiency amplification area of the amplification plate.

FIG. 9 is a view showing a state in which sixteen diaphragms which are still another embodiment are arranged in the high-efficiency amplification area of the amplification plate.

FIG. 10 is a view showing a state in which sixteen diaphragms which are another embodiment are arranged in the high-efficiency amplification area of the amplification plate.

(Explanation of symbols for the main parts of the drawing)

6: speaker 7: composite loudspeaker

10 frame 20 system

30: amplification area 40: composite laminate

50: diaphragm 52: coil

53: end cover 54c: induction magnet

55: soft support 58: permanent magnet

60: busstrip

The present invention relates to a panel speaker that can obtain a high efficiency loudspeaker function by generating an effective vibration deformation in a specific frequency range.

Traditional speakers mainly use conical film as the speaker's voice. This conical film is connected to an electromagnetic coil chamber diaphragm at a relatively small end, and the conical film vibrates back and forth by the vibration of the diaphragm and pushes air to achieve the purpose of amplification.

In general, this type of speaker requires a voice box that prevents sound waves in front of the speaker from being interfered with by reverse sound waves in the rear, but the voice box not only makes the speaker heavy, but also generates a blind spot of speech transmission. Since the conventional speaker has the above drawbacks, the development of the panel speaker is deeply noted, and in recent years, the invention of this field has appeared a lot. Watters, for example, uses a concept of synchronizing frequency, that is, the speed of the sound wave in the air and the speed of the flexible wave propagation on the plate by the synchronizing frequency is light and high By designing a sandwich plate for long amplification, a flexible wave can be transmitted, and high-directional voice can be uttered within a specific frequency range.

In addition, while Heron designed the panel-type speaker using the method of natural vibration mode of the amplification plate, at the time of designing, a plate member is used at the corner of the sandwich plate by using a beehive sandwich plate as the expansion plate. It is intended to improve the efficiency of loudness by arranging an oscillator which is exhausted and generates a flexible vibration, thereby outputting a voice whose frequency is higher than the basic natural frequency and the synchronization frequency. However, since the flat plate provided by these methods has great rigidity, the loudspeaker must be vibrated using a large heavy seismic apparatus, and from the viewpoint of high power consumption, the efficiency can be said to be lower than that of a conventional speaker. .

In addition, the frequency range to which the loudness of the said loudspeaker belongs belongs is narrow for general use, and can be applied only as a trumpet for public speech. Azima similarly designed panel-type speakers using the method of natural vibration mode of an augmented amplification plate, but the seismic used in this design is placed in a specific position on the panel, and as far as possible the first twenty to twenty-five front of the plate. By avoiding polymerization with the nodal line of the natural mode, most modes of the plate are exacerbated, and air is driven to achieve the purpose of expansion.

The method of devastating this kind of loudspeaker could achieve a relatively wide voice frequency, but the facsimile effect is not ideal. Because in the flat panel, there is a possibility that there are thousands of natural frequencies and modes between 50Hz and 20KHz, and when the position of the oscillator is determined based on only the previous 20 modes, any natural mode is excessively in the medium and high frequency range. In a case where the sound pressure is suddenly increased, or the cutout and the seismic position of any other natural mode are polymerized and the sound pressure is suddenly lowered, the panel speaker designed based on the above method has a low and low frequency spectrum of sound pressure sensitivity. This affects the facsimile effect.

On the other hand, the above-mentioned design triggers all of these modes by separating the isolated position from the cutting lines of the previous 20 modes, but in the antisymmetric mode, the regions of the forward movement and the backward movement have opposite phases. The sound pressures generated by these regions interfere with each other and severely affect the magnitude of the sound pressure sensitivity. In other words, there are many drawbacks that must be improved in the panel-type speaker which is widely used at present.

In order to overcome the difficulties and limitations faced by the panel speaker, the present inventors have designed a panel speaker of a composite laminate, characterized in that sound pressure sensitivity is relatively uniformly distributed within a relatively wide frequency range. In the panel type speaker of the present invention, a plurality of amplification composite laminates and two amplification zones of high and low efficiency are partitioned on the panel, and a plurality of high-efficiency amplification zones drive the composite laminate to cause flexible vibration. Two diaphragms are provided.

In the periphery of the composite laminate, a plurality of auxiliary strips are formed to adjust the distribution of the vibration mode and the sound pressure sensitivity frequency spectrum of the composite laminate for amplification, each having a different strength. Another action of the busstrip is to suppress the high frequency standing waves that are set up on the periphery of the multilayer plate to reduce the generation of noise. The periphery of the composite laminate for amplification is separately connected to a soft hanging system for suspending the expansion plate on a frame or a fixture.

The amplification efficiency and sound quality of this panel type speaker include parameters such as the stacking method of the composite laminate, the ratio of the module to the weight density of the composite, the strength of the bus strip and the position in the high-efficiency area of the seismic insulator. Related. Therefore, in designing a panel speaker of a composite laminate, it is necessary to select an appropriate parameter that generates an appropriate sound pressure sensitivity magnitude and distribution within the voice frequency range required by the speaker.

The following object of the present invention is to match and operate the vibration mode analysis and sound pressure sensitivity frequency spectrum analysis of the composite laminate for amplification, the composite used for the expansion plate during the design process, the stacking method of the composite laminate, the surrounding pressure on the composite laminate The present invention provides a method and program for designing a panel-type speaker for determining the strength of the strip, the size, position of the high-efficiency region on the amplified laminate, and the position in the high-efficiency region of the diaphragm.

(Preferred Embodiments for Carrying Out the Invention)

1. Design method and program

Using a flat plate as a vocal source is similar to driving air in contact with a plate surface by generating a flexible vibration, and calculating the magnitude of the generated sound pressure by using a method of sexual studies and related equations. Speaking of plates that are infinitely close or plates of finite size and enclosed perimeter, the sound pressure generated at any point in the space of the plate vibration is obtained by Rayleighs's first integral, In the shift response, the instantaneous sound pressure at the point is represented by the following equation (1).

이다. 상기 식에 있어서 D(γs)는 유한소자 방법에 의하여 평판의 동태응답을 분석하여 구할 수 있다. 또한, 모드 분석에서 판의 측방향 시프트응답은 각 모드의 측방향 시프트 응답의 총합인 것이 확인되고 하기 식(2)로 나타난다.In the equation, P (r, t) is the instantaneous sound pressure at the point away from the plate, r is the distance between the measurement point and the reference coordinate origin on the plate, R is the distance between the measurement point and one oscillation point on the plate, and γs is the vibration point and coordinate Distance between origin, 90 is air density, t is time, S is plate area, w is vibration frequency of plate, D (γs) is lateral shift response of vibration point, i =

to be. In the above formula, D (? S) can be obtained by analyzing the dynamic response of the plate by the finite element method. In addition, in the mode analysis, it is confirmed that the lateral shift response of the plate is the sum of the lateral shift responses of each mode and is represented by the following equation (2).

Where n is the number of natural modes considered, Ai and Φ i are the amplitude and vibration type of the i th natural mode, respectively. In Equations (1) and (2), the stationary measurement point can be seen that relates to the magnitude of the instantaneous sound pressure, the vibration frequency of the plate and the natural mode parameters of the plate. In addition, if the area of the plate is limited, it can be seen from the equation (1) that the instantaneous sound pressure is also associated with the plate, and the plate with the larger area generates a relatively large sound pressure. The sensitivity of sound pressure defined here is expressed by the following equation.

Where Lp is the sound pressure sensitivity, Prms is the mean square of the sound pressure square root, and Pref is the reference pressure constant. Similarly in equations (1) and (3), it can be seen that the sound pressure sensitivity is related to the vibration frequency of the plate, the natural mode parameter, and the area of the plate. The sound pressure sensitivity analyzed at different vibration frequencies can obtain the sound pressure sensitivity frequency spectrum of the amplification plate, and obtaining a relatively uniform sound pressure sensitivity distribution within a relatively wide range is indispensable for the design of panel speakers with high description power. to be.

In addition, when the area of the expansion plate does not change, it is the vibration frequency and natural mode parameters of the plate that affect the distribution of the sound pressure sensitivity frequency spectrum. In addition, when the vibration frequency of the plate and the natural frequency are the same, resonance occurs, and the amplitude of the natural mode of the frequency becomes large, so that the sound pressure sensitivity at this frequency is obviously improved. Therefore, the design of the plate must take into account the distribution of its natural vibration frequency so that the generated sound pressure sensitivity does not change much within a specific frequency range. The properties of the composites used in the amplification plate and the lamination method both directly affect the parameters of the modes such as natural frequency, amplitude, and vibration of the plate, and thus affect the sound pressure sensitivity frequency spectrum distribution of the amplification plate.

In general, a plate of light weight and high bias produces a relatively suitable amplification effect. Influencing the amplitude of each of the natural modes located directly in the high-efficiency amplification region of the seismic plate, thus affecting the distribution of the sound pressure sensitivity spectrum generated in the amplifying plate, the placement point of the seismic device is the sound pressure. In addition to increasing the sensitivity, the sound pressure sensitivity should be distributed relatively uniformly over a specific frequency range. On the other hand, for the natural mode oscillation type having the opposite shift phase angle, the sound pressures generated by the forward and backward clouds are reversed in phase so that they do not interfere with each other and severely lower the sound pressure sensitivity of the vibration frequency. Such interference phenomenon of sound pressure is usually relatively evident in the middle and low frequency ranges.

If a boost strip having different strengths is formed around the expansion plate, the natural mode vibration type of the expansion plate can be adjusted by selecting an appropriate distribution of the strength of the boost strip, thereby reducing interference between sound pressures of different phase angles, It increases the sound pressure sensitivity.

The design parameters affecting the distribution of the sound pressure sensitivity frequency spectrum of the amplification plate are the material properties of the amplified composite laminate, the lamination method of the laminate, the seismic position of the earthquake separator, and the bush strip strength. The expansion plate of the present invention is made of a polymer composite material reinforced with fibers, and the fiber angle of each layer is determined by the reference coordinates of the plate. The 0 ° layer indicates that the fiber direction is coincident with the reference axis, and the 90 ° layer indicates that the fiber direction is perpendicular to the reference axis.

The material properties of the composite layer are represented by E1 / ρ and E2 / ρ, which are ratios of elastic modules and densities. Among them, E1 and E2 are the Young's modulus perpendicular to the fiber direction and the fiber direction, respectively, and p is the density of the material. The ratio of the elastic module and the density has a significant influence on both the natural mode parameter of the plate and the magnitude and distribution of the sound pressure sensitivity. In general, a composite laminate having a relatively small elastic modulus and a ratio of density mainly produces a sound pressure of a relatively low frequency (50 Hz to 500 Hz). On the other hand, a composite laminate having a ratio of a relatively large elastic module and a density generates a sound pressure sensitivity suitable within a range of medium and high frequency coefficients (500 Hz to 20 KHz).

In the distribution of sound pressure sensitivity of one series, when a suitable high pressure sensitivity frequency spectrum is generated within an acoustic frequency range (50 Hz to 20 KHz), the ratio of the elasticity module of the composite and the density is represented by the following formula (4). It turns out that it is limited in the range.

The composite laminate for amplification of the present invention can be, for example, rectangular. In the length a, width b, and thickness h, the value of b is between a / 4 and a. The stacking method of the composite laminate has a significant influence on natural mode parameters such as natural frequency, amplitude and vibration type, and thus directly affects the amplification effect of the composite laminate.

The parameters considered in the lamination method are the number of laminations and the fiber angle of each layer, and the optimum lamination method is, for example, [0 ° / 90 ° / 0 ° /.... ] s orthogonal lamination and for example [θ ° / -θ ° / θ ° /. ] s diagonal interlaced lamination method, etc., and the indication "s" outside parentheses indicates symmetrical lamination, and θ is an angle interposed between 0 ° and 90 °.

The number of layers in the stack is determined by the size of the expansion plate, and in general, when the length a is smaller than or equal to 30 cm, the number of layers is 1 to 3 layers, and when the length a is larger than 30 cm and smaller than 50 cm, the number of layers is 4 When the layer and the length a are greater than or equal to 50 cm, the number of layers is five or more layers. Usually, when length a is larger than 50 cm, it is preferable to manufacture a laminated plate by the sandwich method, and the sandwich material of the sandwich type laminated plate can be manufactured using a lightweight foam material or a non-hybrid core material. have.

The bush strip added to the periphery of the expansion plate may be integrally formed with the flat plate or attached to the edge of the flat plate by an adhesive. The cross section of the bush strip is rectangular, but the strength of the bush strip can be adjusted by changing its cross-sectional area. For this rectangular loudspeaker, the vibration mode parameter of the loudspeaker can be adjusted using four different intensity bush strips, and by studying the set position of the ascender, the loudspeaker can be adapted to the appropriate sound pressure within a specific frequency range. A sensitivity spectrum can be generated.

In the analysis of the sound pressure sensitivity, in order to accelerate the convergence of the analysis, an upper limit is set for the strength of the bush strip, and this limitation is achieved by controlling the cross-sectional area and the Young's modulus of the bush strip. In general, the thickness of the bush strip is smaller than three times the thickness of the plate, the width is smaller than one tenth the width of the plate, and the Young's modulus should be set to be equal to or smaller than the Young's modulus in the fiber direction. In the sound pressure sensitivity frequency spectrum analysis, when the strength of the bushing strip is zero on any side of the plate, the side is not biased.

The diaphragm which drives a loudspeaker plate and generate | occur | produces a negative pressure is similarly divided into two types, an electromagnetic coil type and a piezoelectric type | mold attached to the surface of a loudspeaker plate by the adhesion method. Since the position on the amplification plate of the isolator has a significant influence on both the amplitude of each natural mode of the plate and the sound pressure sensitivity of the plate, different sound pressure sensitivitys occur when the amplification plate is blown at different position points. Usually, the surface of a loudspeaker plate is partitioned into the high-efficiency and low-efficiency high-efficiency area | regions, and the position on these amplification boards of both area | regions is determined by analysis of a sound pressure sensitivity frequency spectrum.

In the analysis process, the strength of the bush strips around the amplification plate is zero, and one specific point is considered, and some specific points on both diagonals or horizontal and vertical lines passing through the plate center point are selected as the isolated point. In addition, the high-sensitivity spectra obtained at these specific points are analyzed, and the size and position of the high-efficiency amplification region are determined by the inner vehicle method. In the case of the rectangular plates of length and width, respectively, a and b, the high-efficiency amplification region is also a rectangular region and is located in the middle of the plate. The length and width of this region are a / 4 and b / 4, respectively.

Usually, the average sound pressure sensitivity obtained by enlarging the loudspeaker plate in the high-efficiency amplification region is at least 10 dB higher than that obtained in the low-efficiency amplification region. The position set in the high-efficiency amplification area of the seismicizer should be determined according to the intensity distribution of the bush strips around the plate because the amplification plate produces a higher pressure sensitivity distributed more uniformly within a specific frequency range. In general, the strength of the position and the boost strip in the high-efficiency amplification region of the decomposer is determined by analyzing the sound pressure sensitivity frequency spectrum generated by the combination of the strengths of the different deplacer positions and the bush strip by the quantum method.

As described above, the design of a highly efficient composite laminated panel panel speaker includes the ratio of the elastic module and the weight density of the composite suitably used, the method of laminating the composite laminated board (including the number of layers and the fiber angle of each layer), The design parameters such as the position of the strip strip strength and the position of high efficiency of the predetermined number of seismic units shall be selected. Since the optimization method has already been widely applied and many process problems have been effectively solved, the design parameters of the composite laminate panel panel of the present invention can be effectively obtained by applying these optimization methods.

As another simple design method, a method of designing a composite laminated panel panel speaker in a two-stage manner has been adopted. That is, in the first step, first, the composite laminate without the bus strip is designed, and the sound pressure sensitivity frequency spectrum generated by the lamination in the high-efficiency region of the plate is analyzed to stack the appropriate composite and the laminate (the number of layers and the fibers). Angle). Then, in the second step, the position is designed in the strength of the bush strip around the plate and in the high-efficiency region of the predetermined number of diaphragms by the quantification method or the optimization method.

2. Example

1 is a schematic diagram showing a composite laminate panel type speaker of the present invention. In the drawing, reference numeral 6 denotes a composite laminated panel panel speaker, and the length a, the width b, and the thickness h, respectively, where b is smaller than a and is larger than or equal to a / 4, and the rectangular composite amplification plate 7 ). The composite amplification plate 7 is composed of a composite laminate plate 40, a set of bush strips 60 and at least one separator 50.

Around it is also connected a fixed soft suspension system 20 next to the flame 10 which is not easily deformed. The suspending system 20 is made of a high damping foam rubber strip, a wave-shaped flexible rubber scrim strip or a cobweb-shaped plastic strip, and besides suspending the expansion plate 7, it is generated next to the expansion plate 7. It has a function of removing noise. The structure and characteristics of the composite laminate 40 including the amplification plate and the bush strip 60 formed around the back side thereof will be described in detail with reference to FIG. 3.

Further, a high-efficiency loupe region 30 is partitioned on the loupe plate, and its length and width are a / 4 and b / 4, respectively, and are located in the center region of the loupe plate. The diaphragm 50 on an amplification plate is fixed in a high-efficiency amplification area | region, drives a composite laminated board, and produces | generates a vibration to this and makes it sound. The position in the high-efficiency amplification region of the diaphragm 50 is determined by the sound pressure sensitivity frequency spectrum analysis proposed by the present invention. In the case of driving the composite laminate with only one diaphragm, the length a of the plate must be less than or equal to 40 cm.

The oscillator 50 is connected to the current amplifier by two wires 56, and the magnitude of the thrust of the oscillator can be adjusted by controlling the amplification factor of the current amplifier, so that the loudness of the sound pressure generated in the speaker can be controlled. Can be.

2 (a) and 2 (b) are diagrams showing the elastic suspension system 20 for hanging the expansion plate 7, respectively. 2 (a) is a cross-sectional view of FIG. 1, which is made by using a suspension system made of foamed rubber strip 20a on the right side of the expansion plate 7 and a wave-like flexible rubber cotton cloth 20b on the left side. Suspension system is arranged. Each hanging system is identified around the direct flame 10.

On the other hand, Fig. 2 (b) is an enlarged view of each corner of the lower corner of Fig. 1, the edge of the expansion plate 7 and the cobweb-like plastic suspension system 20c is connected to each other, the other end of this suspension system is a rectangular flame It is fixed to the periphery of (10).

3 (a) and 3 (b) are cross-sectional side views in the longitudinal direction and the width direction of the speaker 6 in FIG. 1, respectively. In the figure a loudspeaker plate 7, a hanging system 20 and a flame 10 are shown. Among them, the amplification plate 7 is composed of a three-layer composite laminate 40 and a set of bush strips 60, and the number of laminated sheets of the composite laminate and the strength of the bush strips are determined according to the size of the laminate. The material of the composite laminate is limited by equation (4), the layer per composite layer is 0.1mm to a2mm, and the number of laminated sheets is determined by the size of the plate. Here, when the length of the composite laminate is a and the number of laminated layers is N, the number of laminated layers is selected as follows.

when a ≦ 30 cm, N ≦ 3;

when a is between 30 cm and 50 cm N = 4;

If a≥50cm, N≥5 (5)

For a large area amplification plate, when a≥50cm, the optimal fabrication method is to design the amplification plate using the sandwich plate of the composite, use the composite laminate as a panel, and use the foam or non-hive structure for the sandwich layer. do. The stacking method of the composite amplification laminate is made by symmetrically laminating using a composite structure layer having a fiber angle of 0 ° and 90 °, for example, [0 ° / 90 ° / 0 ° /... ] s lamination method. "S" displayed at the bottom right of the parenthesis indicates that the laminate is symmetrical blue. In addition, the lamination method used is an interlaced composite layer of fiber angles θ and -θ, for example, [θ / −θ / θ /... ] s in the manner of lamination.

(Theta) represents the angle (0 degrees <(theta) <90 degrees) larger than 0 degrees and smaller than 90 degrees. The bush strips 60 are fixed to the edges of the composite laminate 40 and each bush strip has different strengths. By changing the strength of the bush strip, the natural mode parameter of the composite laminate 40 can be changed, thereby changing the vibration type of the composite laminate of the bias strip, and reducing the interference of sound pressure caused by the opposite phase angle region of the plate. In this way, the sound pressure sensitivity frequency spectrum can be obtained relatively uniformly distributed, and the facsimile effect of the expansion plate can be improved.

The feature of the bias strip is that the cut is rectangular, but the thickness must be less than three times the thickness of the laminate, the width must be less than one tenth of the laminate, and the Young's modulus equal to or less than the E1 value of the composite used. shall. FIG. 3 (b) is a cross-sectional side view of the B-B cross-sectional view of FIG. 1, and the auxiliary strips having different sizes are formed at the edges of the composite laminate 40. FIG.

4 (a) and 4 (b) are diagrams showing the electromagnetic coil type diaphragm 50 having different current flow directions. In the figure, each of the diaphragms 50 is formed by the permanent magnet 58, the induction magnet 54c and the coil winding 51 respectively connected to the anodes of the two permanent magnets 58, respectively. The terminals of both induction magnets 54 form north and south anodes, and generate a magnetic field in the horizontal direction between the anodes. The coil winding 51 has a conical coil 52 and an end cover 53 disposed at the top of the coil, and the end cover 53 adheres the diaphragm 50 to the composite laminate 40. The coil 52 is arranged between the north and south poles of the induction magnet on the concentric circle by connecting to the soft support 55.

Therefore, when the current flows through the coil, the coil moves in the vertical direction between the two induction magnets 54. In Fig. 4A, when a current flows through the connection point on the left side of the decomposer, it flows from the top to the coil, and then flows out of the decomposer through the right connection point d. The upward movement is performed to the diaphragm coil 52 according to the flow direction of the current direction, and upward slabs are generated. In addition, in Fig. 4B, the flow direction of the current in the diaphragm is opposite to that in Fig. 4A, and the current flows from the bottom of the coil to the top.

Therefore, the coil is made to move downward to generate slats downward.

FIG. 5 is a view showing a state in which four diaphragms 50 are arranged in the high-efficiency expansion region 30 of the expansion plate 7. In the figure, each of the two segregators is divided into one pair, and the tank and the tank are connected in a parallel manner, and the two seismic periods in each tank are connected in a direct thermal manner. If the resistance of each one of the seismic units is R, the resistance of the entire seismic circuit system also becomes R according to the Ohm's law.

All of the seismic units are disposed on the diagonal of the high-efficiency amplification area, and each of the two seismic units is located on both sides of the center point, and the distance between the seismic unit and the center point is determined by the sound pressure sensitivity frequency spectrum analysis proposed in the present invention. . In this case, if four diaphragms are employed, the length a of the plate is preferably less than 100 cm.

FIG. 6 is a view showing a state in which four diaphragms 50 which are other embodiments are arranged in the high-efficiency amplification region 30 of the amplification plate 7. In the figure, the current flow direction in three of the four earthquakes 50 has the act of moving in the same direction as shown in FIG. 4 (a), and the current flow direction in the other one earthquake. Is opposite to the flow direction of the three currents as shown in FIG. There are four sewers divided into two breweries, each with two sewers, with tanks and probes connected in parallel, and two tanks connected with each other in series.

The four diaphragms are respectively arranged on both diagonals in the high-efficiency amplification region 30, and each of the two diaphragms is located on both sides of the center point at the same time. The distance between each of the diaphragms and the high-efficiency region mesothelioma is nodified by the sound pressure sensitivity frequency spectrum method proposed in the present invention. One of these diaphragms having the opposite movement is to move as an actuating tamper to reduce the amplitude of excessively severed frequencies or to adjust the vibration type of the amplification plate 7 to reduce the interference between phase angular pressures on the plate surface. .

FIG. 7 is a view showing a state in which eight diaphragms 50, which is another embodiment, are arranged in the high-efficiency amplification region 30 of the amplification plate 7. FIG. In the figure, all of the diaphragms 50 are arranged on a specific line (including two diagonal lines, one horizontal line and one vertical line) passing through the center point of the high-efficiency amplification region 30. That is, one diaphragm is arrange | positioned at the both sides of the center point of a specific line, respectively.

The distance from the center point in the isolator and high-efficiency amplification region is determined by the sound pressure sensitivity frequency spectrum analysis proposed in the present invention. Among them, as a suitable pattern for arranging the isolator, in a circle having a center point centrifugal and a radius of b / 6 to b / 4, the isolator is disposed at the intersection of this circle and a specific line. The optimal radius of the circle is determined by the sound pressure sensitive frequency spectrum analysis proposed in the present invention.

In addition, the eight segregators are divided into two sets, each of which has four segregators, and the tank and the irradiator are connected in parallel, and the seismic units are connected in a series manner in each tank. If the resistance of each isolator is R, the resistance of the isolator circuit system is 2R by the Ohm's law. In the case of using eight diaphragms, the length a of the expansion plate 7 is preferably set between 100 cm and 200 cm.

FIG. 8 is a view showing a state in which eight diaphragms 50 as another embodiment are arranged in the high-efficiency amplification region 30 of the amplification plate 7. Since seven of the demagnetizers have the same current flow direction as shown in Fig. 4 (a), the operation behavior of the decelerator is the same, but in the eighth decomposer, the current flow direction is shown in Fig. 4 (b). As shown in the figure, the other seven seismic counterparts have opposite actuation behavior. The oscillator with the opposite actuation acts as a damping damper to reduce the amplitude of excessively squeezed frequencies or to adjust the vibration type of the amplification plate 7 to reduce the interference between the sound pressures of opposite phase angles on the plate surface. .

Eight decomposers 50 are arranged on specific lines (including two diagonal lines, one horizontality and one vertical line) passing through the center point of the high-efficiency amplification region 30, respectively. That is, one diaphragm is arrange | positioned at the both sides of the center point of each specific line, respectively. The distance from the center point in the isolator and high-efficiency amplification region is determined by the sound pressure sensitivity frequency spectrum analysis proposed in the present invention. Among them, as a suitable pattern for arranging the segregator, in a circle having a center point centrifugal and a radius of b / 6 to b / 4, a seismic device having seven identical acting behaviors is disposed at the intersection of this circle and a specific line. do.

In addition, one seismic device having a movable action in the opposite direction is disposed near the remaining unloaded intersection. The distance between the diaphragm and the center point and the optimum radius of the circle are determined by sound pressure sensitivity frequency spectrum analysis. In addition, eight segregators are divided into two sets, and each seizure has four sequesters, a tank and a tank are connected in a parallel manner, and the sewers are connected in a series manner in each tank. Therefore, if the resistance of each isolator is R, the resistance of the isolator circuit system is 2R.

FIG. 9 is a view showing a state in which sixteen diaphragms 50, which is another embodiment, are arranged in the high-efficiency amplification region 30 of the amplification plate 7. FIG. Each diaphragm is arranged on a specific line passing through the center point of the high-efficiency amplification region 30, respectively. By dividing these specific lines into two sets, the specific lines of Article 1 include both diagonals, one horizontal line and one vertical line, and the specific lines of Article 2 are formed by four other specific lines, each of which is subject to Article 1 In the neighboring two narrow angles of equilibrium.

In each specific line, one diaphragm is disposed on each side of the midpoint, and the distance between the second place and the midpoint is determined by the sound pressure sensitivity frequency spectrum analysis proposed in the present invention. Above all, as a suitable pattern for arranging the isolator, in two concentric circles whose center point is the centrifugal center and the radius is b / 4 and b / 8, respectively, the large circle intersects the first set of lines and eight points, Circle intersects eight points of Article 2. Sixteen quakes are divided into two groups of eight, each of which is located at the intersection of both small and large circles.

The tank and the radiator are connected in a parallel manner, and the seismic is connected in a series manner in each tank. Therefore, when the resistance of each of the decomposers is set to R, the resistance of the entire diaphragm circuit system also becomes R. In addition, since each decomposer has the same flow direction of current as shown in Fig. 4A, the operation behavior of each decomposer is the same. In addition, when attaching 16 segregators on a plate surface, it is suitable to set length a of the expansion board 7 larger than 100 cm.

FIG. 10 is a view showing a state in which sixteen diaphragms 50, which is another embodiment, are arranged in the high-efficiency amplification region 30 of the amplification plate 7. FIG. In the figure, since 15 of the 16 capacitors 50 have the same current flow direction as shown in FIG. The flow direction of the current in the seismic device is opposite to the other 15 seismic devices as shown in FIG.

The oscillator having the opposite actuation acts as an actuating damper to reduce the amplitude of excessively squeezed frequencies, or to adjust the vibration type of the loudspeaker plate 7 to reduce the interference between sound pressures of opposite phase angles on the plate surface. will be. Sixteen seismic units are divided into two groups of eight, and the tank and the radiator are connected in a parallel manner, and the seismic groups in each tank are connected in a series manner. Therefore, when the resistance of each isolator is set to R, the resistance of the entire isolator circuit system is also R. Each diaphragm is arranged on a specific line passing through the center point of the high-efficiency amplification region 30, respectively.

These specific lines are divided into two sets, and the specific lines of Article 1 include both diagonal lines, one horizontal line and one vertical line, and the specific lines of Article 2 are constituted by four other specific lines, each of which is defined in Article 1 It is the equilibrium line of both neighboring narrow angles. In each specific line, one diaphragm is disposed on both sides of the center point, and the distance between the seismic center and the center point is determined by the sound pressure sensitivity frequency spectrum analysis proposed in the present invention.

Among them, as a suitable pattern for arranging the isolator, in the two concentric circles with the centrifugal point as the center and the radius b / 4 and b / 8 respectively, the large circle intersects the line of Article 1 and eight points, while the small circle We cross at eight points different from line of Article 2. In the brewing, the seismic device having the same movable behavior is disposed on the intersection of the large circle and the small circle, and the seismic one having the movable operation in the opposite direction is disposed near the diagonal bottom of the large circle and any diagonal. The distance between the diaphragm and the center point is determined by high-pressure sensitivity spectrum analysis.

In addition, the attachment patch with the damper having two or more opposite directions of actuation can be determined based on the above method.

The present invention generates an effective vibration deformation in a specific frequency range, whereby a high efficiency loudspeaker function can be obtained.

The present invention is not limited to the above embodiments, and any modifications, modifications, and substitutions made by those skilled in the art belong to the technical scope of the present invention without departing from the appended claims.

Claims (15)

And a panel speaker having a length a and a width b, wherein b is less than a and is greater than a / 4. , (a) analyzing the distribution of the flexible vibration mode and the mode parameters of the composite amplification plate, (b) analyzing the sound pressure sensitivity frequency spectrum distribution of the panel-type speaker and identifying parameters affecting the sound pressure sensitivity frequency spectrum distribution; (c) defining a high-efficiency amplification region for arranging a certain number of seismicizers on the composite amplification plate, generating effective flexible vibrations in the diffuser plate by driving in this region of the seismicizer to generate a high sensitivity sound pressure; and , (d) designing a panel speaker by selecting appropriate parameter values to generate the magnitude and distribution of the sound pressure sensitivity required within a specific frequency range; (e) manufacturing a composite laminated panel panel speaker based on the selected parameter value. The method of claim 1, In the panel-type speaker, the composite amplification plate is composed of a composite laminate, a set of bush strips formed on the edge of the loudspeaker plate, and a specific number of toilets, and the composite laminate is a high-efficiency laminate on the laminate. A method for producing a composite loudspeaker panel speaker, characterized in that the object of amplification is achieved by driving a seismic device disposed in the area. The method of claim 2, Parameters for generating the sound pressure sensitivity frequency spectrum required for the panel-type speaker of the composite laminate are the ratio of the elastic module and the density of the composite, the lamination method of the composite laminate, the strength of the bush strip on the expansion plate edge, and the high-efficiency region of the diaphragm. A method of manufacturing a composite loudspeaker panel type speaker comprising a position within. The method of claim 3, wherein The definition of the high-efficiency amplification region is determined by analyzing the sound pressure sensitivity frequency spectrum generated by the composite amplification plate driven by the seismic device at different positions, In the analysis of the sound pressure sensitivity frequency spectrum, the periphery of the amplification plate does not add any bush strips, The high-efficiency amplification area obtained by the above analysis is a rectangular area, the length and width of which are a / 4 and b / 4, respectively, and the center point is the same as that of the amplification plate. How to make a speaker The method of claim 4, wherein The diaphragm is fixed at a specific position in the high-efficiency amplification area by an adhesive method, and the number thereof is determined according to the size of the amplification plate, which is one or four when the length a of the amplification plate is less than or equal to 40 cm. Composite augmentation, characterized by the use of selectors, the use of 8 or 16 selectors when a is between 100 cm and 200 cm, and the use of 16 or more selectors when a is greater than 200 cm Manufacturing method of plate panel type speaker. The method of claim 5, Simultaneously determining the strength of the bushing strip on the loudspeaker edge and the position within the high-efficiency loudness region of the diaphragm so as to obtain the required sound pressure within a specific sound frequency range, The strength of the busstrip is controlled by the size of the cross section or the Young's modulus of the busstrip, in particular the thickness of the busstrip is less than three times the thickness of the composite laminate, and the width of the busstrip is the width of the composite laminate. Less than one tenth, the Young's modulus of the busstrip is set to be equal to or smaller than the Young's modulus in the fiber direction of the composite, The Young's modulus and density ratio of the composite are in the range of 80 and 180 GPa / (g / cm 3) in the fiber direction, and 3 and 10 GPa / (g / cm 3) in the substrate direction. The lamination method of the laminated plate is made by laminating a composite layer having a fiber angle of 0 ° and 90 ° through a symmetrical method with a plane as a plane of symmetry, or the fiber angles of 0 ° and −θ through a symmetrical method as described above. Is achieved by interlacing the composite layers of °, The number of laminations that the plate can have is determined by the size of the area, and in particular, the thickness of each composite layer is in the range of 0.1 to 0.2 mm, and when the plate length a is within 30 cm, the lamination number is three layers or less, and a is 30 And the number of floors is four layers if it is between -50 cm, and if a is larger than 50 cm, the number of floors is at least five layers. Panel-type speaker which expands by generation of flexible vibration, A rectangular composite laminate having a length a, width b and a bush strip formed around the periphery; At least one separator installed on the composite laminate, the at least one separator for enclosing the composite laminate to generate flexible vibration; And And a high-efficiency region for partitioning the composite laminate onto the surface of the composite laminate and generating a high sound pressure sensitivity compared to other portions by triggering the composite laminate by the separator. Panel speaker. The method of claim 7, wherein In the panel-type speaker, the composite laminate is a rectangular plate set such that width b is smaller than or equal to length a and b is larger than a / 4. The composite laminate is formed by a composite layer having a specific number or orthogonal material, wherein the thickness of each composite layer is between 0.1 and 0.2 mm, and the Young's modulus and density ratio are 80 and 180 GPa in the fiber direction. interposed between / (g / cm 3), between 3 and 10 GPa / (g / cm 3) in the substrate direction, The composite material layer having the orthogonal material is a panel speaker, characterized in that made of a material such as carbon fiber reinforced epoxy resin, glass fiber reinforced epoxy resin or boron fiber reinforced epoxy. The method of claim 7, wherein The composite laminate used for the panel multiplier is a double lamination method in which the center plane of the lamination plate is a symmetry plane, that is, a lamination method by laminating a composite layer having a fiber angle of 0 ° and 90 ° in a symmetrical manner, and a fiber angle θ. (0 ° <θ <90 °) and a lamination method in which the composite layers of -θ are laminated in a symmetric manner, The number of laminated layers of the composite laminate is determined according to the length a of the plate, and if a is less than 30 cm, the number of laminated layers is 3 or less layers. If a is between 30 cm and 50 cm, the number of layers is 4 layers, and a is greater than 50 cm. A panel speaker comprising at least five floors. The method of claim 7, wherein Peripheral strips having four strengths are additionally formed in the periphery of the rectangular composite laminate, wherein each of the secondary strips is less than three times the thickness of the composite laminate, and the width thereof is 10 times the width of the composite laminate. Less than one-third, and the Young's modulus of each of the bush strips is set smaller than or equal to the Young's modulus in the fiber direction of the composite, In the panel-type speaker, the bush strip is provided with a function of suppressing standing waves remaining on the edge of the composite laminate and adjusting a natural vibration mode of the composite laminate, thereby selecting an appropriate bush strip strength. By reducing the generation of noise and generating a vibration type that contributes to the amplification of the composite laminate, thereby reducing interference of sound pressure generated in the area of the floating surface in the floating movement direction. The method of claim 7, wherein The panel type speaker according to claim 1, wherein the diaphragm for enclosing the composite laminate is an electromagnetic coil or piezoelectric engraver. The method of claim 7, wherein The panel speaker includes a composite laminate in which the bush strip is additionally formed in the periphery, and at least one of the separators fixed in the high-efficiency region on the laminate, And the strength of the bush strip and the position in the high-efficiency amplification region of the seismic generator cause the seismic generator to generate a sound pressure sensitivity distribution required within a specific frequency range. The method of claim 12, The panel speaker, (a) provided with a decompressor which is located at a specific position within one said high-efficiency amplification region and drives said composite laminate, (b) four symmetrical systems, including a seismic device for driving the composite laminate at a specific position diagonally within the high-efficiency region, (c) a complex located at an intersection where four concentric circles and four specific lines in the center of the eight high-efficiency amplification regions intersect to drive the composite laminate, and includes a vibration damper for generating a flexible vibration thereto. The specific line includes two diagonal lines in the high-efficiency region, a horizontal line and a vertical line passing through the center point of the region, (d) a pair of sixteen eights, each of which has a diaphragm for driving the composite laminate, located in concentric circles of two floating radii in the high-efficiency amplification region, and the eight concentrically large eight concentric ones Disposed on the intersection of a circle and four specific lines, wherein the specific line includes both diagonal lines in the high-efficiency region, and horizontal and vertical lines passing through the center point of the region, while being a small concentric circle. Eight isolators are located at the intersection of the circle and four other specified lines, wherein the specified line is the equilibrium line of the angle between the neighboring both specified lines of the large circle, and (e) Two sets of separators are provided with different numbers and opposite directions of movement, and one set of relatively small numbers is a driven damper that adjusts the vibration type of the composite laminate and at excessively severed frequencies. And one of the five types of suns for lowering the sound pressure generated by the sound pressure and generating a sound pressure sensitivity distribution more suitable for the loudspeaker within a specific frequency range. delete delete

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