WO2018076917A1 - 音质优化共振器 - Google Patents

音质优化共振器 Download PDF

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Publication number
WO2018076917A1
WO2018076917A1 PCT/CN2017/099219 CN2017099219W WO2018076917A1 WO 2018076917 A1 WO2018076917 A1 WO 2018076917A1 CN 2017099219 W CN2017099219 W CN 2017099219W WO 2018076917 A1 WO2018076917 A1 WO 2018076917A1
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WO
WIPO (PCT)
Prior art keywords
sound quality
resonator
sound
wood material
present
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PCT/CN2017/099219
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English (en)
French (fr)
Inventor
陈宏远
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陈宏远
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Publication of WO2018076917A1 publication Critical patent/WO2018076917A1/zh

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    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10CPIANOS, HARPSICHORDS, SPINETS OR SIMILAR STRINGED MUSICAL INSTRUMENTS WITH ONE OR MORE KEYBOARDS
    • G10C3/00Details or accessories
    • G10C3/06Resonating means, e.g. soundboards or resonant strings; Fastenings thereof
    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10DSTRINGED MUSICAL INSTRUMENTS; WIND MUSICAL INSTRUMENTS; ACCORDIONS OR CONCERTINAS; PERCUSSION MUSICAL INSTRUMENTS; AEOLIAN HARPS; SINGING-FLAME MUSICAL INSTRUMENTS; MUSICAL INSTRUMENTS NOT OTHERWISE PROVIDED FOR
    • G10D3/00Details of, or accessories for, stringed musical instruments, e.g. slide-bars
    • G10D3/02Resonating means, horns or diaphragms
    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10KSOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
    • G10K11/00Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
    • G10K11/02Mechanical acoustic impedances; Impedance matching, e.g. by horns; Acoustic resonators

Definitions

  • the utility model relates to a resonator.
  • the sound is generated by squeezing the air at different vibration frequencies and then transmitting it to the person's ears.
  • a slight change in the vibration frequency will produce different changes in sound quality.
  • Different materials are placed under the sound source, and the vibration frequency of the sound source changes. Some materials have a vibration-damping frequency, and some materials reflect and absorb sound fluctuations. For example, different instrument materials have different appearances, and the sound produced by the sound is completely different.
  • the purpose of the utility model is to provide a device for improving the sound quality effect of the sounding body.
  • the sounding body refers to a body capable of emitting a sound that a person can feel, including a musical instrument, an audio device, a human body, an animal body, and the like.
  • the present invention provides a sound quality optimized resonator for improving the sound quality of a sound emitted by a sounding body, comprising a plurality of wood material blocks stacked on top of each other. A sheet of metallic material is interposed between adjacent opposing faces of the plurality of blocks of wood material.
  • the sheet of metallic material extends beyond the boundary of the sandwiched block of wood material.
  • the plurality of pieces of wood material and the sheet of metallic material are bonded and fixedly joined together.
  • the plurality of wood material blocks are all cylindrical blocks.
  • the plurality of wood material blocks are two pieces of wood material.
  • the sheet of metallic material comprises a plurality of circular metal sheets side by side.
  • the plurality of side-by-side circular metal sheets comprise opposite sides of the sandwiched block of wood material
  • a central metal sheet of the center and six surrounding metal sheets uniformly distributed around the central metal sheet.
  • the sound quality optimization resonator is mounted below a support point or a support surface of the musical instrument or the sound, and is connected to the support point or the support surface to support the musical instrument or the sound.
  • the outer side of the uppermost piece of wood material of the sound quality optimizing resonator has a groove for facilitating connection with the support point or support surface to support the musical instrument or sound.
  • the sounding body is a musical instrument, an acoustic, and/or a human body.
  • the sounding body is an instrument.
  • the thickness of the block of wood material ranges from 1 to 30 mm
  • the thickness of the sheet of metal material ranges from 0.5 to 20 mm
  • the lateral length of the block of wood material does not exceed 90 mm.
  • the thickness of the wood material block ranges from 5 to 15 mm, and the thickness of the metal material sheet ranges from 1 to 4 mm.
  • the mating surface between the plurality of wooden material blocks is a tapered surface.
  • the side of the piece of wood material sandwiching the sheet of metallic material has a step such that the side has at least two step faces.
  • the block of wood material is bonded by a plurality of blocks.
  • an anti-slip device is disposed on an outer surface of the block of wood material located at the bottom of the sound quality optimizing resonator.
  • the anti-slip device is an anti-slip member embedded in a recess of the outer surface of the block of wood material at the bottom of the sound quality optimizing resonator.
  • the sheet of metallic material is 5-30 mm beyond the boundary of the block of wood material.
  • the sheet of metallic material is 11-14 mm beyond the boundary of the block of wood material.
  • the sheet of metallic material is 12.5 mm beyond the boundary of the block of wood material.
  • the metal material sheet comprises a plurality of side-by-side circular metal sheets
  • a proportion of a circular metal sheet overlapping the boundary of the wood material block extending beyond the boundary of the wooden material block It accounts for 30%-70% of the round metal piece.
  • the proportion of the circular metal sheet overlapping the boundary of the wood material block extending beyond the boundary of the wood material block is from 45% to 55% of the circular metal piece.
  • the sheet of metal material is a sheet of metal material having a plating layer.
  • the sheet of metallic material is a sheet of copper plated or copper plated metallic material.
  • the sheet of metallic material is a sheet of metallic material having a composite layer.
  • the wood material block is a composite layer formed by bonding different wood layers.
  • a hole extending in the axial direction of the sound quality optimizing resonator is provided in the middle of the sound quality optimizing resonator.
  • the aperture is a through hole.
  • the axis of the aperture coincides with the axis of the sound quality optimizing resonator.
  • the hole is for mating with a positioning axis of a player playing a record, and the sound quality optimizing resonator is placed on the record.
  • the record is a vinyl record.
  • the pores have a pore size ranging from 8 to 12 mm.
  • the pores have a pore size of 10 mm.
  • the sound quality optimizing resonator of the present invention can be used alone as a sound quality optimizing resonator of an instrument, or can be used alone as a sound quality optimizing resonator of an acoustic sound, and can all play a significant role in optimizing the sound quality. Moreover, when both the instrument and the sound are present, it can also be used as a sound quality optimized resonator for both the instrument and the sound.
  • the sound quality optimizing resonator of the present invention can also be used to enhance the sound quality of sounds emitted by the human body.
  • a singer can step on his feet or put it on the chest to optimize the sound quality of the singer, and the instrumentalist can step on it under his feet or on the chest to optimize the sound quality of the sound from the instrument.
  • the existing attachments use only a single material, and the optimization effect on the sound quality is extremely limited; Moreover, the attachment of the musical instrument only has the effect of slipping or suppressing vibration, and the instrument cannot be made. The sound quality is improved.
  • the utility model adopts a superimposed material and a special shape appearance, which can change the vibration frequency of the sounding body, and make the original sound color more cumbersome and rich.
  • the utility model mainly grasps the different characteristics of the reflection and refraction of the sound vibration frequency of wood and metal, promotes the resonance effect of the original sound source, and achieves the purpose of rich and optimized sound quality.
  • the sound quality optimized resonator of the present invention is characterized in that it does not necessarily need to be installed under the support point or the support surface of the sounding body, but can be placed in any part of the sounding body, even The effect is nearby, that is, it can be placed separately beside the sounding body.
  • the sound quality optimizing resonator of the present invention can be placed in a wide range of positions to improve the sound quality of the sound emitted by the sounding body.
  • the sound quality optimizing resonator of the present invention can be placed according to the optimal placement position of different instruments and sound selection effects.
  • the shape and configuration of the sound quality optimizing resonator of the present invention can be specifically designed as needed to adapt to the selected position to obtain an optimum sound quality optimization effect at the position.
  • FIG. 1 is a perspective view of an example 1 of an embodiment of a sound quality optimized resonator of the present invention.
  • FIG. 2 is a perspective view of a second embodiment of the sound quality optimized resonator of the present invention.
  • FIG 3 is a perspective view of an example 3 of an embodiment of a sound quality optimized resonator of the present invention.
  • Figure 4 is a perspective view of Figure 1 after being cut.
  • Figure 5 is a perspective view of Figure 2 after being cut.
  • Figure 6 is a top plan view of the sound quality optimized resonator of Examples 1, 2 and 3 after moving the top main layer.
  • FIG. 7 is a cross-sectional view showing an example 4 of the embodiment of the sound quality optimizing resonator of the present invention.
  • Figure 8 is a cross-sectional view showing an example 5 of the embodiment of the sound quality optimizing resonator of the present invention.
  • FIG. 9 is a cross-sectional view showing an example 6 of the embodiment of the sound quality optimizing resonator of the present invention.
  • Figure 10 is a cross-sectional view showing an example 7 of the embodiment of the sound quality optimizing resonator of the present invention.
  • FIG. 11 is a cross-sectional view showing an example 8 of the embodiment of the sound quality optimizing resonator of the present invention.
  • Figure 12 is a cross-sectional view showing an example 9 of the embodiment of the sound quality optimizing resonator of the present invention.
  • FIG. 13 is a cross-sectional view of an example 10 of an embodiment of a sound quality optimized resonator of the present invention.
  • FIG. 14 is a cross-sectional view of an eleventh embodiment of a sound quality optimized resonator of the present invention.
  • FIG. 15 is a perspective view of an example 12 of an embodiment of a sound quality optimized resonator of the present invention.
  • 16 is a perspective view of an example 13 of an embodiment of a sound quality optimized resonator of the present invention.
  • 17 is a cross-sectional view of an example 14 of an embodiment of a sound quality optimized resonator of the present invention.
  • FIG. 18 is a cross-sectional view of an example 15 of an embodiment of a sound quality optimized resonator of the present invention.
  • 19 is a cross-sectional view of an example 16 of an embodiment of a sound quality optimized resonator of the present invention.
  • FIG. 1, 2 and 3 are respectively perspective views of the first, second and third embodiments of the sound quality optimized resonator of the present invention
  • FIG. 4 is a perspective view of FIG. 1 after cutting
  • FIG. 6 is a top plan view of the sound quality optimized resonator of Examples 1, 2, and 3 after moving the top main layer.
  • the sound quality optimizing resonator of the present invention is used for improving the sound quality of the sound emitted by the sounding body.
  • the sound quality optimizing resonator of the illustrated embodiment includes: two main layers, namely the first main layer 11 and the second main Layer 12; and a layer 2 of metallic material sandwiched between the two main layers.
  • the two main layers are all cylindrical blocks.
  • the metal material layer 2 includes seven circular metal pieces 21-27 side by side, and the center metal piece 27 is located at the opposite side of the sandwiched main layer. At the center of the face, six surrounding metal sheets 21-26 are evenly distributed around the central metal sheet 27.
  • the main layer when the main layer is a wood material, the main layer may also be referred to as a wood material block.
  • the layer of metallic material may also be referred to as a sheet of metallic material.
  • each of the main layers is made of a non-metallic material, and the main layers are stacked together, and a metal material layer is interposed between adjacent opposite faces of the stacked plurality of main layers, and The outermost main layers at both ends of the plurality of main layers are each made of a wood material.
  • the first main layer 11 and the second main layer 12 are both cylindrical wood blocks.
  • the six surrounding metal sheets 21-26 extend beyond the boundaries of the first main layer 11 and the second main layer 12. Since the protruding portion of the six surrounding metal pieces 21-26 is suspended, it is easy to generate vibration, is more favorable for resonance, and can make the sound quality of the sound emitted by the sounding body (for example, a musical instrument and an audio) more pleasant.
  • the first main layer 11 and the second main layer 12 and the metal material layer 2, i.e., the seven circular metal sheets 21-27, are fixedly joined by bonding.
  • the preferred attachment of the primary layer to the layer of metallic material is to be fixedly joined together by bonding.
  • the seven circular metal sheets 21-27 may or may not be in contact with each other when aligned, which may be selected by those skilled in the art at the time of specific design.
  • the sound quality optimization resonator of the present invention may be installed under the support point or the support surface of the sounding body, and connected to the support point or the support surface to support the sounding body, for example, placed on a leg of a piano or a pole of a cello.
  • the sound quality-optimized resonator of the present invention can improve the sound quality of the sound emitted by the sounding body even if it is not attached to the support point or the support surface of the sounding body but is placed separately beside the sounding body.
  • the upper surface of the first main layer 11 of Example 1 has a larger flat bottom groove 111 to facilitate engagement with a larger leg.
  • the groove 112 of the upper surface of the first main layer 11 of Example 2 is smaller to facilitate engagement with a smaller fulcrum, such as the front end of the cello.
  • the upper surface of the first main layer 11 may also be a flat surface without grooves, as shown in Example 3 of FIG.
  • the sound quality optimized resonator of the present invention may have different shapes and configurations in accordance with the principles of the present invention, and Examples 4-16 of the embodiments of the present invention are further described below.
  • the main layer of the sound quality optimizing resonator of the present invention is a plurality of layers, that is, at least two layers, and at least one main layer must be a wood material.
  • Example 4 of Fig. 7 is three main layers 11, 13, and 12, and example 5 of Fig. 8 is four main layers 11, 13, 14, and 12, and a sheet of metal material is interposed between the main layers.
  • the intermediate main layer 13 is not made of wood, but other non-metallic materials such as resin, ABS are used.
  • the metal material layer is a patchwork circular metal piece in the previous example
  • the metal material layer of the present invention may also adopt a monolithic metal material layer.
  • the wooden material can be loose, Woods such as cypress, alfalfa, pear, rosewood, rosewood, etc., are selected by those skilled in the art as needed.
  • the layer of metallic material may extend beyond the main layer or within the boundaries of the main layer.
  • the example 6 of FIG. 9 and the example 7 of FIG. 10 show a one-piece circular metal piece 2, and the edge of the circular metal piece 2 in the example 6 of FIG. 9 protrudes from the main layer to be suspended, but FIG. The edge of the circular metal piece 2 in the example 7 is located within the boundary of the main layer.
  • the opposite sides of the main layer may be flat or may have surfaces having different patterns, and may be selected as long as the object of the present invention can be achieved.
  • the opposite sides of the example 8 of FIG. 11 and the example 9 of FIG. 12 are tapered.
  • the side faces of the main layers 11 and 12 sandwiching the metal material layer 2 have steps such that the side mask of the main layer 11
  • step faces 113 and 114 There are at least two step faces 113 and 114, and the side of the main layer 12 has at least two step faces 123 and 124.
  • the height of the step can be specifically designed as needed.
  • the height of the step corresponds only to the thickness of the metal material layer 2, and the step surface 123 is flush with the upper surface of the metal material layer 2;
  • the height of the step in the example 11 of Fig. 14 is much larger, which is much larger than the thickness of the metal material layer 2.
  • the shape of the metal material layer may need to be changed accordingly.
  • the metal material layer 2 varies depending on the shape of the side surface of the main layer, and the specific shape of the metal material layer 2 can be specifically designed as needed.
  • the metal material layer 2 of the example 8 of Fig. 11 protrudes from the boundary of the main layer, and the edge of the metal material layer 2 of the example 9 of Fig. 12 is within the boundary of the main layer.
  • the patchwork portions of the patchwork metal material layer 2 are not in contact with each other, but a gap is left.
  • the pieces can be spliced together and can be selected as needed.
  • the metal material layer can be pieced together by different independent parts, but the main layer can also be pieced together or spliced.
  • the main layer is spliced with different independent portions, and in the example 12 of FIG. 15, the main layer includes four independent portions, and in the example 13 of FIG. 16, the main layer includes 6 separate parts, each of which is fixed by bonding.
  • the sound quality optimizing resonator of the present invention can be placed not only in the vicinity of the sounding body but also in the support point or the supporting surface to support the sounding body.
  • the anti-slip structure is provided on the lower surface of the main layer 12 at the bottom to help support the sounding body (for example, musical instruments, sounds) Ringing and the human body).
  • the anti-slip structure may be a depression or a protrusion formed in the lower surface of the main layer 12, or a non-slip member may be provided on the lower surface of the main layer 12, such as a non-slip sheet for bonding or inserting rubber, plastic or resin, and anti-slip particles. .
  • Example 14 of Figure 17 shows an embodiment.
  • an anti-slip ring 121 is provided on the lower surface of the main layer 12.
  • the center of the lower surface of the main layer 12 has a boss 122 around which the anti-slip ring 121 is embedded in the recess of the lower surface edge.
  • the anti-slip ring 121 is bonded to the groove in a bonded manner.
  • the boss 122 is a part of the wood of the main layer 12 in this example, but it is also possible to bond a piece of wood as the boss 122.
  • the coverage area of the anti-slip structure is reduced as much as possible.
  • the inlaid anti-slip sheet and the anti-slip grain can have as small a coverage area as possible.
  • the anti-slip ring 121 in the example 14 of FIG. 17 can be as narrow as possible, and the anti-slip ring 121 is also It can be deformed into discrete small anti-slip sheets. Thus, it is possible to ensure that the lower surface of the anti-slip ring 121 directly contacts the floor with as large an area as possible.
  • Example 15 of Figure 18 and Example 16 of Figure 19 give additional specific embodiments, the embodiments of Examples 15 and 16 being characterized by having holes 3 as compared to the previous examples.
  • the hole 3 extends longitudinally through the sound quality optimizing resonator of the present invention, including the through holes 31, 32, and 33 of the first main layer 11, the metal material layer 2, and the second main layer 12, respectively.
  • the hole 3 is a blind hole that penetrates only a portion of the sound quality optimized resonator of the present invention. Specifically, the blind hole is formed only in the second main layer 12 as shown in FIG. The hole 3 does not pass through the first main layer 11 and the metal material layer 2.
  • One of the functions of the hole 3 is as a positioning hole for the sound quality optimizing resonator, which is matched with the protruding fixing member, thereby facilitating the fixing of the sound quality to optimize the position of the resonator.
  • the other function of the hole 3 is also a unique function of the sound quality optimizing resonator of the present invention, and is used as a receiving hole in a specific application, so that the sound quality optimizing resonator can improve the sound quality of the sounding body.
  • the hole 3 is for accommodating a positioning shaft for playing a vinyl record, so that the sound quality optimizing resonator of the present invention can be placed on a vinyl record in the center of the vinyl record, thereby greatly improving the sound quality of the played music.
  • the hole 3 may be a through hole extending through all of the main layer and the metal material layer.
  • the aperture may also be a blind aperture and does not have to extend longitudinally through the sound quality optimized resonator of the present invention.
  • the hole 3 is preferably located at the axial center of the sound quality optimizing resonator of the present invention, as shown in the figure. 18 and 19 are shown.
  • the axis of the hole 3 can also deviate from the axial center of the sound quality optimizing resonator of the present invention, and the degree of deviation can be designed as needed.
  • the hole 3 may be a cylindrical hole as shown in Figs. 18 and 19, or may be a hole of another shape such as an elliptical hole or the like.
  • the lateral or radial dimensions of the aperture can be specifically designed as desired.
  • the aperture range is 8-12 mm, preferably 10 mm.
  • the positioning height of the positioning shaft for positioning the vinyl record is generally 1-15 mm, and can be specifically designed with reference to this data when specifically designed to accommodate the hole 3 of the positioning shaft.
  • the utility model adopts a special structure in which a metal material is centered and a non-metal material such as wood is combined.
  • the utility model grasps that the non-metal materials mainly reflect the sound vibration frequency of wood and metal.
  • the different characteristics of refraction promote the resonance effect of the original sound source and achieve the purpose of rich sound quality optimization.
  • the following is a description of the sound propagation mode in the sound quality optimizing resonator of the present invention, taking wood as the main layer and the main layer as two layers.
  • the vibration frequency When the vibration frequency is refracted through the metal and transmitted to the bottommost wood, a new vibration frequency reflection and refraction is generated. Finally, the refractive vibration frequency that penetrates the underlying wood is transmitted to the floor, and the floor also reflects the vibration frequency according to the material characteristics.
  • the original sound source will be affected by the reflected vibration frequency of different materials, which will change the sound quality and achieve the purpose of sound quality optimization.
  • the main layer is made of a material different from wood, or the main layer is more than two layers, the principle of optimizing the sound of the sound quality optimizing resonator of the present invention can be easily understood based on the above description.
  • a plurality of factors can affect the effect of optimizing the sound quality of the sound quality optimizing resonator.
  • the influence degree of factor 1 is the largest, the factor is 2 times, and the factors 3 and 4 are successively followed.
  • the material of the main layer is preferably a wood material, and it is of course also possible to use other non-metal materials as needed.
  • the wood material is better in hardness, density and toughness, such as eucalyptus, ash, maple, rosewood, rosewood, ebony. , hard boxwood, etc.
  • Metal materials such as titanium, silver, platinum, copper and other metals and alloys can be used. According to the study of the inventors, the optimization of copper to sound quality is in the middle of metal materials.
  • the metal material layer may be a metal material having a plating layer, such as a copper gold plated material, or a copper silver plated material, and the metal material layer may be a composite material in which different metals are firmly composited.
  • the non-metallic material of the main layer may also be a composite non-metallic material which is firmly composited by different non-metal materials, for example, a composite material which is firmly connected by different woods, and the manner of firmly connecting may be bonding.
  • wood materials and metal materials that are more effective and how to match these materials.
  • the main layer may be a cylinder, and its cross section may also be an elliptical shape or a rectangular shape.
  • the layers of metallic material can have different shapes. In addition, as described above, it may be a piece of independent metal piece or a single piece. In addition, when the metal material layer protrudes from the boundary of the main layer, the optimization effect is better. Further, the bonding faces may have different shapes, such as a step shape, etc. Naturally, the upper and lower surfaces may also have different shapes.
  • the layer of metallic material may be 5-30 mm beyond the boundary of the primary layer, preferably in the range of 11-14 mm, such as 12.5 mm.
  • the metal material layer is a circular metal sheet such as that shown in Figures 1-8, the circular metal sheet protrudes in a proportion of 30% to 70%, preferably 45% to 55%, of the metal sheet.
  • Thickness is also a more important factor.
  • the thickness of the main layer ranges from 1 to 30 mm, and the preferred thickness ranges from 5 to 15 mm, such as 8, 10, 12 mm, and the like.
  • the thickness of the metal material layer ranges from 0.5 to 20 mm, and the preferred thickness ranges from 1 to 4 mm, such as 1, 1.5, 2, 2.5 mm, and the like.
  • the maximum lateral length of the block is 90 mm.
  • the metal sheets may be in contact with each other or may have a gap; the main layer may also be a separate independent portion.
  • This practical new The components of the type of sound quality optimized resonator can be fixed by bonding, and the contact faces can be completely bonded or partially bonded.
  • the sound quality optimized resonator of the present invention can be placed in a wide range of positions associated with the sounding body to optimize the sound quality. This feature is explained in detail below.
  • the sound quality optimizing resonator of the present invention can be placed in a position directly in contact with the sounding body, which is a different part of the sounding body.
  • the sounding body such as under the support point or support surface of the instrument or sound.
  • placed on the support surface of the instrument or the sound can enhance the sound quality.
  • Another example is that at the foot of a music singer, or on the chest, there is a clear improvement in sound quality.
  • the sound quality optimized resonator of the present invention can be placed at a position that is not in direct contact with a sounding body (such as a musical instrument or an audio), including spaces above, below, and in the vicinity, which can enhance the sounding body (such as a musical instrument or an acoustic). Sound quality.
  • a sounding body such as a musical instrument or an audio
  • an instrument with a piano table such as a guqin, a guzheng, and the like, does not have to directly contact the instrument itself, and placing it on the piano table has a greatly improved sound quality.
  • the sound quality optimized resonator of the present invention can be stepped under the foot or placed in the chest, and the sound quality of the instrument can be optimized.
  • the player's body acts to transmit vibration, and thus the sound quality-optimized resonator resonance that excites the present invention is generated by the player's body. Optimize the sound quality.
  • the sound quality-optimized resonator of the present invention can be used to enhance the sound quality in a wide range of positions, there is a relatively better position with the sounding body.
  • the optimal position is not necessarily the position below the audio equipment, but may be above the audio equipment.
  • the optimal position of the audio equipment is determined by the unique shape and construction of the sound quality optimized resonator of the present invention.
  • the piano king of the instrument can put the sound quality optimization resonator of the present invention on any corner of the piano to improve the sound quality of the piano, but the cushion is optimal under the piano foot.
  • a musician or singer can step on the sound quality optimized resonator of the present invention. Next, to optimize the sound quality, however, it is better to use the sound quality optimizing resonator of the present invention with both feet.
  • those skilled in the art can select the sound quality optimizing resonator of the present invention according to different sounding bodies, and can design the shape and structure of the sound quality optimizing resonator of the present invention to suit the selection. The location to get the best sound quality optimization at that location.
  • the sound quality optimization resonator have stronger applicable directivity, the effect of optimizing the sound quality for different sounding bodies is better and more convenient for the user.
  • the sound quality optimized resonator of the present invention can greatly improve the sound quality of the sound emitted by the sounding body, and those skilled in the art can specifically design the sound quality optimizing resonator according to the spirit of the present invention disclosed in the present application. Shape and construction to achieve the desired design goals.
  • the embodiments of the sound quality optimizing resonator of the present invention have been described above, and the purpose thereof is to explain the spirit of the present invention. It is to be noted that those skilled in the art can modify and combine the features of the above embodiments without departing from the spirit of the present invention. Therefore, the present invention is not limited to the above embodiments.
  • the specific features of the sound quality optimized resonator of the present invention such as shape, size and position, can be specifically designed by the effects of the features disclosed above, which are all achievable by those skilled in the art.
  • the technical features disclosed above are not limited to the combination of the disclosed features and other features, and other combinations between the technical features may be performed by those skilled in the art according to the purpose of the utility model, which is to achieve the purpose of the present invention. .

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Abstract

一种音质优化共振器,其用于提升发声体所发出声音的音质,包括多个木质材料块,多个木质材料块叠置,在叠置的多个木质材料块的相邻相对面之间夹置有金属材料片。以特殊的结构使发声体的振动频率改变,让原有的音色更加淸楚、丰富。

Description

音质优化共振器 技术领域
本实用新型涉及共振器。
背景技术
声音的产生都是靠不同的振动频率挤压空气,再传递至人的双耳。振动频率的些微改变就会对音质产生不同的变化。不同的材质放置在音源的下方,对音源的振动频率会产生变化。有些物质的材质会抑制振动频率,有些材质会反射和吸收声音的波动。例如各种不同的乐器材质尺寸外观均不相同,所产生声音的音色也完全不同。
现有的附加装置,如乐器的脚垫,只有止滑或抑制振动的效果,无法使乐器的音质提升。
实用新型内容
本实用新型之目的在于提供一种装置,以提升发声体的音质效果。
在本申请中,发声体是指能够发出人能够感受到的声音的存在体,包括乐器、音响器材、人体、动物体等等。
为实现上述目的,本实用新型提供一种音质优化共振器,用于提升发声体所发出声音的音质,包括多个木质材料块,所述多个木质材料块叠置,在叠置的所述多个木质材料块的相邻相对面之间夹置有金属材料片。
优选地,所述金属材料片延伸而超出夹置的木质材料块的边界。
优选地,所述多个木质材料块和所述金属材料片经粘结而固定地连接在一起。
优选地,对于前述各技术方案,所述多个木质材料块为均为圆柱体块。
优选地,对于前述各技术方案,所述多个木质材料块为两个木质材料块。
优选地,对于前述各技术方案,所述金属材料片包括多个并排的圆形金属片。
优选地,所述多个并排的圆形金属片包括位于夹置的木质材料块的相对面
中心的中心金属片和围绕该中心金属片均布的六个周围金属片。
优选地,对于前述各技术方案,所述音质优化共振器安装于所述乐器或音响的支撑点或支撑面的下方,与所述支撑点或支撑面连接而支撑所述乐器或音响。
优选地,所述音质优化共振器的位于最上方的木质材料块的外侧面具有凹槽,以便于与所述支撑点或支撑面连接而支撑所述乐器或音响。
优选地,对于前述各技术方案,所述发声体是乐器、音响和/或人体。
优选地,对于前述各技术方案,所述发声体是乐器。
优选地,对于前述各技术方案,所述木质材料块的厚度范围1-30毫米,金属材料片的厚度范围是0.5-20毫米,并且,所述木质材料块的横向长度不超过90毫米。
优选地,所述木质材料块的厚度范围是5-15毫米,金属材料片的厚度范围是1-4毫米。
优选地,对于前述各技术方案,所述多个木质材料块之间的配合面为锥形面。
优选地,对于前述各技术方案,所述木质材料块的夹住金属材料片的侧面具有台阶,使得该侧面具有至少两个台阶面。
优选地,对于前述各技术方案,所述木质材料块由多个块体粘结而成。
优选地,对于前述各技术方案,位于该音质优化共振器底部的木质材料块的外表面上设置有防滑装置。
优选地,所述防滑装置为嵌于音质优化共振器底部的木质材料块的外表面的凹槽中的防滑件。
优选地,对于前述各技术方案,所述金属材料片超出木质材料块的边界5-30毫米。
更优选地,所述金属材料片超出木质材料块的边界11-14毫米。
更优选地,所述金属材料片超出木质材料块的边界12.5毫米。
优选地,对于前述各技术方案,当所述金属材料片包括多个并排的圆形金属片,与所述木质材料块的边界重叠的圆形金属片伸出所述木质材料块的边界的比例占该圆形金属片的30%-70%。
更优选地,与所述木质材料块的边界重叠的圆形金属片伸出所述木质材料块的边界的比例占该圆形金属片的45%-55%。
优选地,对于前述各技术方案,所述金属材料片是具有镀层的金属材料片。
更优选地,所述金属材料片是铜镀金或铜镀银的金属材料片。
优选地,对于前述各技术方案,所述金属材料片是具有复合层的金属材料片。
优选地,对于前述各技术方案,所述木质材料块是由不同的木材层粘结而成的复合层。
优选地,对于前述各技术方案,在该音质优化共振器的中部具有沿该音质优化共振器的轴向延伸的孔。
更优选地,所述孔是通孔。
更优选地,所述孔的轴线与所述音质优化共振器的轴线重合。
优选地,对于前述各技术方案,所述孔用于与播放唱片的唱机的定位轴配合,使所述音质优化共振器放置在所述唱片上。
更优选地,所述唱片是黑胶唱片。
更优选地,所述孔的孔径范围是8-12毫米。
更优选地,所述孔的孔径是10毫米。
本实用新型的音质优化共振器可以单独用作乐器的音质优化共振器,也可以单独用作音响的音质优化共振器,都可以起到显著地优化音质的作用。而且,当乐器和音响同时存在时,也可以用作乐器和音响二者的音质优化共振器。
此外,例如,本发明的音质优化共振器也可以用于提升人体所发出声音的音质。例如,歌唱家可以将其踩在脚下或者放在胸口,以优化唱出的声音的音质,乐器演奏家将其踩在脚下或者放在胸口,也可以优化乐器发出的声音的音质。
乐器和音响设计的本质是发出悦耳的声音,但现有的技术只能对声音有单一的影响,无法增加音乐的丰富性。现有技术的材质大都在抑制振动,会让音色偏暗,比较没有生动的声音表现。
经发明人研究,对于发声体,例如乐器和音响,现有的附加装置只使用单一材质,对音质的优化效果极为有限;而且,乐器的附加装置只有止滑或抑制振动的效果,无法使乐器的音质提升。
本实用新型以叠置材质加上特殊的形状外观,可以使发声体的振动频率改变,让原有的音色更加淸楚、丰富。
本实用新型最主要是掌握木材和金属对声音振动频率的反射和折射的不同特性,促进原始音源的共振效应,达到音质丰富优化之目的。
由于具有独特的形状和构造,本实用新型的音质优化共振器的一大特点是不一定需要安装于发声体的支撑点或支撑面的下方,而是可以放在发声体的任何部位,甚至于附近都有其效果,即可以在发声体旁边单独放置,换言之,本实用新型的音质优化共振器可以设置于广泛的位置以改善发声体所发出声音的音质。
而且,可以根据不同的乐器和音响选择效果最佳的放置位置摆放本实用新型的音质优化共振器。
此外,还可以根据需要具体设计本实用新型音质优化共振器的形状和构造来适应选定的位置,以在该位置获得最佳的音质优化效果。
附图说明
图1为本实用新型的音质优化共振器实施方式的示例1的立体示意图。
图2为本实用新型的音质优化共振器实施方式的示例2的立体示意图。
图3为本实用新型的音质优化共振器实施方式的示例3的立体示意图。
图4为图1经剖切后的立体示意图。
图5为图2经剖切后的立体示意图。
图6为示例1、2和3的音质优化共振器经移动顶部主层后的平面俯视图。
图7为本实用新型的音质优化共振器实施方式的示例4的剖视示意图。
图8为本实用新型的音质优化共振器实施方式的示例5的剖视示意图。
图9为本实用新型的音质优化共振器实施方式的示例6的剖视示意图。
图10为本实用新型的音质优化共振器实施方式的示例7的剖视示意图。
图11为本实用新型的音质优化共振器实施方式的示例8的剖视示意图。
图12为本实用新型的音质优化共振器实施方式的示例9的剖视示意图。
图13为本实用新型的音质优化共振器实施方式的示例10的剖视示意图。
图14为本实用新型的音质优化共振器实施方式的示例11的剖视示意图。
图15为本实用新型的音质优化共振器实施方式的示例12的立体示意图。
图16为本实用新型的音质优化共振器实施方式的示例13的立体示意图。
图17为本实用新型的音质优化共振器实施方式的示例14的剖视示意图。
图18为本实用新型的音质优化共振器实施方式的示例15的剖视示意图。
图19为本实用新型的音质优化共振器实施方式的示例16的剖视示意图。
具体实施方式
在下文中,将参照附图描述本实用新型的音质优化共振器的实施方式。
在此记载的实施方式为本实用新型的特定的具体实施方式,用于说明本实用新型的构思,均是解释性和示例性的,不应解释为对本实用新型实施方式及本实用新型范围的限制。除在此记载的实施方式外,本领域技术人员还能够基于本申请权利要求书和说明书所公开的内容采用显而易见的其它技术方案,这些技术方案包括采用对在此记载的实施方式的做出任何显而易见的替换和修改的技术方案。
本说明书的附图为示意图,辅助说明本实用新型的构思,示意性地表示各部分的形状及其相互关系。请注意,为了便于清楚地表现出本实用新型实施方式的各部件的结构,各附图之间不一定按照相同的比例绘制。相同的参考标记用于表示相同或相似的部分。此外,在参照附图进行描述时,为了表述方便,采用了方位词如“上”、“下”等,它们并不构成对特征的结构特定地限制。
图1、2和3分别是为本实用新型的音质优化共振器实施方式的示例1、2和3的立体示意图,图4为图1经剖切后的立体示意图,图5为图2经剖切后的立体示意图,图6为示例1、2和3的音质优化共振器经移动顶部主层后的平面俯视图。
本实用新型的音质优化共振器用于提升发声体所发出声音的音质,参见图1-6,图示实施方式的音质优化共振器包括:两个主层,即第一主层11和第二主层12;以及夹在两个主层之间的金属材料层2。在这些示例中,两个主层均为圆柱形块,如图6所示,金属材料层2包括并排的七个圆形金属片21-27,中心金属片27位于夹置的主层的相对面中心,六个周围金属片21-26围绕该中心金属片27均布。
在本实用新型中,当主层为木质材料时,主层也可被称为木质材料块。另外,金属材料层也可被称为金属材料片。
在本实用新型中,每个主层均由非金属材料制成,这些主层叠置一起,在叠置的所述多个主层的相邻相对面之间夹置有金属材料层,并且,所述多个主层中的位于两端的最外面的主层均由木质材料制成。如图1-6所示,这些示例中,第一主层11和第二主层12均为圆柱形木块。
而且,六个周围金属片21-26延伸而超出第一主层11和第二主层12的边界。由于六个周围金属片21-26伸出的部分悬空,易于产生振动,更有利于共振,能够使发声体(例如乐器和音响)所发出声音的音质更动听。
在图1-6中,第一主层11和第二主层12与金属材料层2,即七个圆形金属片21-27,经粘结而固定地连接在一起。而且,在本实用新型中,所述多个
主层和所述金属材料层的优选连接方式是经粘结而固定地连接在一起。
另外,七个圆形金属片21-27在排列时,它们的边缘之间既可以接触也可以不接触,这可以在具体设计时由本领域技术人员作出选择。
本实用新型的音质优化共振器可以安装于发声体的支撑点或支撑面的下方,与所述支撑点或支撑面连接而支撑所述发声体,例如放置于钢琴的支脚或大提琴的支杆的下方。不过,本实用新型的音质优化共振器即使不安装于发声体的支撑点或支撑面的下方,而是在发声体旁边单独放置,也能够改善发声体所发出声音的音质。
作为例子,示例1的第一主层11的上表面具有较大的平底凹槽111,以便于与较大的支脚接合。示例2的第一主层11的上表面的凹槽112较小,以便于与较小的支点接合,例如大提琴的支杆前端。当然,第一主层11的上表面也可以为平坦面,无凹槽,如图3的示例3所示。
本实用新型的音质优化共振器可以依据本实用新型的原理而具有不同的形状和构造,下面进一步说明本实用新型实施方式的示例4-16。
本实用新型的音质优化共振器的主层为多层,即至少是两层,而且,至少一个主层必须是木质材料。图7的示例4为三个主层11、13和12,图8的示例5是四个主层11、13、14和12,而且在主层之间均夹置有金属材料片。在示例4中,中间的主层13没有采用木材,而是采用其它非金属材料,例如树脂、ABS。
虽然在前面的示例中金属材料层采用的是拼凑的圆形金属片,但是,本实用新型的金属材料层也可以采用一个整块的金属材料层。木质材料可以是松、 柏、榆、梨、花梨、紫檀等等木材,本领域技术人员根据需要进行选择。另外,金属材料层可以伸出主层,也可以在主层的边界内。例如,图9的示例6和图10的示例7示出了一个整块的圆形金属片2,而且,图9的示例6中圆形金属片2的边缘伸出主层悬空,但图10的示例7中圆形金属片2的边缘位于主层的边界内。
在本实用新型中,主层的相对侧面可以是平面,也可以是具有不同图案的表面,只要能够实现本实用新型之目的则均可选用。例如,图11的示例8和图12的示例9的相对侧面采用锥形。在图13的示例10和图14的示例11中,主层11和12的夹住金属材料层2的侧面具有台阶,使得主层11的该侧面具
有至少两个台阶面113和114,主层12的该侧面具有至少两个台阶面123和124。台阶的高度可以根据需要来具体设计,例如在图13的示例10中,台阶的高度仅相当于金属材料层2的厚度,台阶面123与金属材料层2的上表面平齐;与之相比,图14的示例11中台阶的高度则大得多,其远大于金属材料层2的厚度。
当主层的相对侧面具有不同的图案时,金属材料层的形状可能需要相应地变化。在图11-14的示例8-11中,金属材料层2相应于主层侧面的形状而变化,金属材料层2的具体形状可以根据需要具体设计。
此外,图11的示例8的金属材料层2伸出主层的边界,而图12的示例9的金属材料层2的边缘则在主层的边界内。另外,在图11的示例8、图12的示例9、图13的示例10中,拼凑的金属材料层2的各拼凑部分之间并未接触,而是留有间隙。当然,根据需要,各拼凑部分拼接起来也是可以根据需要选择的。
在本实用新型中,不仅金属材料层可以用不同的独立部分拼凑起来,主层也可以是拼凑或拼接的。参见图15的示例12和图16的示例13,主层是用不同的独立部分拼接起来的,在图15的示例12中主层包括4个独立部分,在图16的示例13中主层包括6个独立部分,各独立部分之间用粘结的方式固定起来。
本实用新型的音质优化共振器不仅可以单独放置于发声体的附近,也可以与支撑点或支撑面连接而支撑发声体。尤其当设置于支撑点或支撑面下方时,在底部的主层12的下表面设置防滑结构是有助于支撑发声体(例如乐器、音 响和人体)的。防滑结构可以是主层12的下表面中形成的凹陷或凸起,也可以在主层12的下表面上设置防滑件,例如粘结或镶嵌橡胶、塑料或树脂之类的防滑片、防滑粒。
图17的示例14给出了一种实施方式。在该示例中,在主层12的下表面上设置有防滑圈121。主层12的下表面的中心具有凸台122,防滑圈121围绕该凸台122嵌于下表面边缘的凹槽中。防滑圈121以粘结的方式与该凹槽连接。当然,在该示例中凸台122是主层12的木材的一部分,但是,如果粘结一块木片作为凸台122也是可以的。
经发明人研究,如果与地板接触的主层12的下表面上覆盖阻尼材料,有可能使音质优化共振器优化音质的效果变差。因此,在设置防滑结构时,可以
将防滑结构的覆盖面积尽可能减小,例如,镶嵌的防滑片、防滑粒可以尽可能具有小的覆盖面积,图17的示例14中的防滑圈121可以尽可能窄,而且,防滑圈121还可以变形为离散的小防滑片。这样,就可以保证防滑圈121的下表面以尽量大的面积直接接触地板。
图18的示例15和图19的示例16给出了另外的特定实施方式,与前面的示例相比,示例15和示例16的实施方式的特点是具有孔3。
如图18的示例15所示,该孔3纵向贯穿本实用新型的音质优化共振器,包括第一主层11、金属材料层2和第二主层12分别具有的通孔31、32和33。
再参见图19的示例16,该孔3为盲孔,仅穿透了本实用新型的音质优化共振器的一部分,具体而言,如图19所示该盲孔仅形成于第二主层12中,该孔3并未穿过第一主层11和金属材料层2。
该孔3的作用之一是作为放置音质优化共振器的定位孔,该定位孔与凸起的固定件相配合,从而便于固定音质优化共振器的位置。
该孔3的另一作用,也是本实用新型的音质优化共振器的一个独特作用,系在特定应用中作为容纳孔,便于该音质优化共振器提升发声体的音质。例如,该孔3用于容纳播放黑胶唱片的定位轴,从而本实用新型的音质优化共振器可以在黑胶唱片的中心部位放置于黑胶唱片上,大幅提升所播放出的音乐音质。
该孔3可以是贯通孔,贯穿全部主层和金属材料层。该孔也可以是盲孔,不必纵向贯穿本实用新型的音质优化共振器。
此外,该孔3优选是位于本实用新型的音质优化共振器的轴向中心,如图 18和19所示。该孔3的轴线也可以偏离本实用新型的音质优化共振器的轴向中心,偏离的程度可以根据需要具有设计。
当然,该孔3可以是如图18和19所示的圆柱孔,也可以是其它形状的孔,例如椭圆形孔等。
该孔的横向或径向尺寸可以根据需要具体设计。当用于放置于黑胶唱片的中心部位时,孔径范围是8-12毫米,优选是10毫米。用于定位黑胶唱片的定位轴的凸出高度一般是1-15毫米,在具体设计用于容纳该定位轴的孔3时可以参考此数据进行具体设计。
本实用新型采用金属材料居中、非金属材料例如木材上下相结合的特殊结构。本实用新型掌握了非金属材料主要是木材和金属对声音振动频率的反射和
折射的不同特性,促进原始音源的共振效应,达到音质丰富优化之目的。
下面以木材做主层并且主层为两层为例说明本实用新型的音质优化共振器中声音的传播方式。
当发声体(例如乐器、音响和人体)产生振动频率时,先会传递到最上层木材,最上层的木材会将一部份的振动能量先反射回原始振动源,另一部份振动能量会折射穿透第一层木材,传递到第二层金属材料。当振动能量传递至第二层金属材料时,也会产生振动能量的反射和折射。但是,由于木材和金属的材质特性不同,对振动频率的反射和折射的能力也不同。最上层木材反射振动频率和第二层金属反射振动频率在强度、波型和时间差上皆不相同,这二种反射的频率在返回原始音源时会对原始的振动频率产生新的共振,进而对音色产生丰富性。
当振动频率折射穿透金属传递至最底层的木材时,又产生新的振动频率反射与折射。最后穿透过底层木材的折射振动频率传递至地板,地板也依据材质特性来反射振动频率。
最终原始音源会受到不同材质的反射振动频率的影响,进而改变了音质,达到音质优化的目的。
当主层采用不同于木材的材料,或者主层多于两层时,本实用新型的音质优化共振器的优化声音的原理也可以根据上述说明而轻而易举地理解。
在本实用新型的音质优化共振器中,多个因素可以影响音质优化共振器优化音质的效果,总的来说,有四个方面的因素:1.主层和金属材料层的材质; 2.部件的形状;3.主层和金属材料层的厚度;4.部件的接触度和固定度。从影响音质优化共振器优化音质的效果的重要程度来说,因素1的影响度最大,因素2次之,因素3和4再相继次之。
主层的材质优选是木质材料,当然也可以是根据需要选用其它非金属材料。为有利于从发声体接受振动并产生振动,经发明人研究,木质材料以硬度、密度较大、较坚韧的为佳,例如梓木、水曲柳、枫木、花梨木、紫檀、黑檀、硬黄杨木等。金属材料层可以采用钛、银、铂、铜等金属以及合金,据发明人研究,铜对音质的优化作用处于金属材料的中间地位。请注意,金属材料层可以采用具有镀层的金属材料,例如铜镀金的材料,或者铜镀银的材料,而且金属材料层可以是不同金属牢固复合而成的复合材料。类似地,主层的非金属材料也可以是不同的非金属材料牢固复合而成的复合非金属材料,例如,由不同的木材牢固连接而成的复合材料,牢固连接的方式可以是粘结。而且,本领域技术人员可以选用效果更好的木质材料和金属材料以及选择这些材料之间如何配合。
主层可以为圆柱体,其截面也可以是椭圆形或矩形等形状。金属材料层可以具有不同的形状。另外,如前所述可以是独立的金属件拼凑的,也可以一个整体件,另外,当金属材料层伸出主层的边界时,优化效果较好。此外,结合面也可以具有不同的形状,如阶梯形等,自然,上下表面也可以具有不同的形状。
金属材料层可以超出主层的边界5-30毫米,优选尺寸范围是11-14毫米,例如12.5毫米。当金属材料层是例如图1-8所示的圆形金属片时,圆形金属片伸出的比例占该金属片的30%-70%,优选的比例45%-55%。
厚度也是一个较重要的影响因素。在本实用新型中,当主层采用木质材料时,主层的厚度范围1-30毫米,优选的厚度范围是5-15毫米,例如8、10、12毫米等。金属材料层的厚度范围是0.5-20毫米,优选的厚度范围是1-4毫米,例如1、1.5、2、2.5毫米等。附带说明,木块的最大横向长度是90毫米。
上述这些尺寸范围、比例和优选值均是发明人经过深刻研究后得到的,有利于得到具有良好优化效果的本实用新型音质优化共振器。
关于部件的接触度和固定度,如前所述,同一金属材料层中,金属片之间可以接触,也可以具有间隙;主层也可以是不同的独立部分拼凑的。本实用新 型的音质优化共振器的部件之间可以用粘结的方式固定,接触面之间可以全部粘结也可以部分粘结。
特别需要说明的是,由于具有独特的形状和构造,本实用新型的音质优化共振器摆放在与发声体相关的广泛位置就可以起到优化音质的作用。以下详细解释这一特点。
第一、本实用新型的音质优化共振器可以放置于与发声体直接接触的位置,该位置为发声体的不同部位。
例如,作为垫材放置于发声体的下方,比如安装于乐器或音响的支撑点或支撑面的下方。再如,放置于乐器或音响的支承面上,都可以起到提升音质的效果。
再如,放在音乐歌唱家的脚下,或者放在胸口,都对音质有明显的提升效果。
第二、本实用新型的音质优化共振器可以放置于与发声体(例如乐器或音响)不直接接触的位置,包括上面、下面和附近的空间,都可以提升发声体(例如乐器或音响)的音质。
例如,有琴桌的乐器,诸如古琴、古筝之类,不必直接接触到乐器本身,放置在琴桌上就有大幅提升音质的效果。
再例如,乐器演奏家在演奏时,可以将本实用新型的音质优化共振器踩在脚下,或者放在胸口中,也可以优化乐器所发出的音质。实际上,在这种情况下,虽然声音是由乐器发出的,但是,演奏家的身体起到了传递振动的作用,这样,就通过演奏家的身体产生了激发本发明的音质优化共振器共振而优化音质的作用。
第三、虽然本实用新型的音质优化共振器摆放广泛的位置都可以提升音质,但是,随着发声体的不同,存在相对更优的位置。
例如,对于音响器材,最优位置不一定是在音响器材的下方的位置,而可能是在音响器材上方的位置。音响器材的最优位置正是由本发明音质优化共振器的独特形状和构造所决定的。
再例如,乐器之王钢琴,把本实用新型的音质优化共振器摆放在钢琴上的任何角落就可以提升钢琴的音质,但是,垫在琴脚下是最优的位置。
再如,音乐演奏家或歌唱家可以将本实用新型的音质优化共振器踩在脚 下,以优化音质,但是,用两脚均踩住本发明的音质优化共振器之效果更佳。
第四、本领域技术人员可以根据不同的发声体选择效果最佳的放置位置本实用新型的音质优化共振器,而且可以根据需要具体设计本实用新型音质优化共振器的形状和构造来适应选定的位置,以在该位置获得最佳的音质优化效果。
由此,通过使音质优化共振器具有更强的适用指向性,使针对不同发声体优化音质的效果更好,也更便于用户使用。
请注意,本实用新型的音质优化共振器可以做到大幅提升发声体所发出声音的音质,本领域技术人员可以根据本申请所公开的本实用新型之精神,具体地设计该音质优化共振器的形状和构造,以达到所需的设计目标。
以上对本实用新型的音质优化共振器的实施方式进行了说明,其目的在于解释本实用新型之精神。请注意,本领域技术人员可以在不脱离本实用新型的精神的情况下对上述各实施方式的特征进行修改和组合,因此,本实用新型并不限于上述各实施方式。对于本实用新型的音质优化共振器的具体特征如形状、尺寸和位置可以上述披露的特征的作用进行具体设计,这些设计均是本领域技术人员能够实现的。而且,上述披露的各技术特征并不限于已披露的与其它特征的组合,本领域技术人员还可根据实用新型之目的进行各技术特征之间的其它组合,以实现本实用新型之目的为准。

Claims (10)

  1. 一种音质优化共振器,其特征在于,该音质优化共振器用于提升发声体所发出声音的音质,包括多个木质材料块,所述多个木质材料块叠置,在叠置的所述多个木质材料块的相邻相对面之间夹置有金属材料片。
  2. 根据权利要求1所述的音质优化共振器,其特征在于,所述金属材料片延伸而超出夹置的木质材料块的边界。
  3. 根据权利要求1所述的音质优化共振器,其特征在于,所述多个木质材料块和所述金属材料片经粘结而固定地连接在一起。
  4. 根据权利要求1-3中任一项所述的音质优化共振器,其特征在于,所述多个木质材料块为均为圆柱体块。
  5. 根据权利要求1-3中任一项所述的音质优化共振器,其特征在于,所述多个木质材料块为两个木质材料块。
  6. 根据权利要求1-3中任一项所述的音质优化共振器,其特征在于,所述金属材料片包括多个并排的圆形金属片。
  7. 根据权利要求6所述的音质优化共振器,其特征在于,所述多个并排的圆形金属片包括位于夹置的木质材料块的相对面中心的中心金属片和围绕该中心金属片均布的六个周围金属片。
  8. 根据权利要求1-3中任一项所述的音质优化共振器,其特征在于,所述共振器安装于所述乐器或音响的支撑点或支撑面的下方,与所述支撑点或支撑面连接而支撑所述乐器或音响。
  9. 根据权利要求8所述的音质优化共振器,其特征在于,所述共振器的位于最上方的木质材料块的外侧面具有凹槽,以便于与所述支撑点或支撑面连接而支撑所述乐器或音响。
  10. 根据权利要求1-3中任一项所述的音质优化共振器,其特征在于,所述发声体是乐器、音响和/或人体。
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