JP6183125B2 - drum - Google Patents

Description

  The present invention relates to a drum.

  2. Description of the Related Art Conventionally, a technique for sensing sound output from a drum has been developed in order to amplify and adjust the sound when a performance is performed on a drum. For example, Patent Document 1 discloses a technique for installing a plurality of microphones inside a drum. In addition, a configuration in which a performance sound is collected by arranging a microphone outside the drum is frequently used. In addition to a configuration in which a microphone is installed around a drum by a microphone stand or the like, a configuration as in Patent Document 2 is also known. Patent Document 2 discloses a configuration in which a sound collecting device including a shell and a diaphragm is installed so as to face a bass drum.

US Pat. No. 7,297,863 JP 2004-325908 A

  In the case of a configuration in which a microphone is installed inside the drum as in the technique disclosed in Patent Document 1, formation of a sound field inside the drum is hindered, and sound quality is degraded. That is, a normal microphone, such as a dynamic microphone, is configured to include a front cavity and a back cavity in order to widen a frequency band in which sound can be collected, and the configuration is complicated and large. Therefore, the formation of the sound field inside the drum is hindered.

On the other hand, in the configuration in which the microphone is arranged outside the drum or the configuration disclosed in Patent Document 2, there is a case where the performance operation of the performer is obstructed or the arrangement of the drum at the position desired by the performer is obstructed. there were.
The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique that does not hinder the formation of a sound field inside the drum and does not hinder the player's operation and the selection of the arrangement position of the drum.

  In order to achieve the above object, a drum comprising a cylindrical shell, a drum head attached to one open end of the shell, and a dynamic speaker that collects performance sounds installed inside the drum head and the shell Configure.

  That is, the dynamic speaker includes a diaphragm for outputting sound. When sound enters the diaphragm, the diaphragm vibrates according to the incident sound, and the dynamic speaker responds to the incident sound. Is output. Therefore, it can be used as a sound collecting device with a simple configuration. Therefore, a configuration is adopted in which a dynamic speaker is installed in the drum instead of a microphone, and the output of the dynamic speaker is acquired as a performance sound output. According to this configuration, since the sound inside the drum can be collected by a small sound collecting device, the degree to which the sound field inside the drum is disturbed is suppressed more than that of a general microphone. Sound can be collected. Further, since it is not necessary to arrange a sound collecting device outside the drum, the performance operation of the performer is not obstructed, and the arrangement of the drum at a position desired by the performer is not obstructed.

  Here, the shell is a cylindrical member, and it is sufficient that the drum head can be held at a predetermined tension at at least one opening end. Various configurations can be adopted as a configuration for attaching the drum head to the shell.For example, a drum head holding member is configured by a lug attached to the outer periphery of the shell and a hoop attached to the lug, and the lug is attached to the lug. A configuration in which a hoop is attached and a drum head is attached to the hoop can be employed. The cylinder may be a cylinder, or may be another shape (for example, a cylinder having a polygonal opening).

  The drum head is a vibrating membrane attached to one open end of the shell. Therefore, it is only necessary to generate a drum performance sound by hitting the drum head with a stick or the like. Of course, another head (resonance head) may be attached to the opening end opposite to the opening end of the shell to which the drum head is attached, or another head may not be attached.

  When comparing a microphone that collects sounds in the same frequency band with a dynamic speaker, the dynamic speaker is smaller, and thus the dynamic speaker occupies less space inside the drum than the microphone. Specifically, the dynamic speaker can assume a configuration including a diaphragm, a coil, a permanent magnet, and a housing. That is, when the diaphragm and the coil are joined, and the coil is arranged in the magnetic field of the permanent magnet, electromagnetic induction is performed by the vibration of the coil accompanying the vibration of the diaphragm, and a signal corresponding to the vibration of the diaphragm is transmitted to the coil. Any configuration may be used. The casing may be a structure that supports the diaphragm so as to vibrate and supports the permanent magnet. Of course, as long as the dynamic speaker is smaller than the microphone, the dynamic speaker may include other configurations, and may include a back cavity, a front cavity, and the like.

  In addition, various configurations can be adopted for installing the dynamic speaker inside the drum head and the shell, and a holding member is attached to the inner wall or lug of the shell, and the dynamic speaker is dynamically attached to the holding member. By attaching the speaker, it is possible to adopt a configuration in which a dynamic speaker is installed in a space (inside the drum) surrounded by the inner wall of the shell. Of course, the installation position of the dynamic speaker in the drum is arbitrary, and can be various positions. In addition, the shape and material of the holding member are arbitrary, and it may be configured such that vibration is not transmitted to the dynamic speaker via the holding member by forming at least a part of the holding member with an elastic material. good.

  The performance sound collected by the dynamic speaker may be taken out as an output of the dynamic speaker. For example, the performance sound output can be obtained by wiring connected to a coil included in the dynamic speaker. The wiring is preferably configured such that the performance sound output is utilized outside the drum by extending to the outside of the drum through a shell or other part. Of course, if a small wireless transmitter or the like is used, the performance sound output can be used externally without using wiring.

  One or more dynamic speakers may be installed inside the drum, but a plurality of dynamic speakers may be installed. In this case, it is preferable to install a plurality of dynamic speakers having different frequency bands of collected sound. That is, a small dynamic speaker has a narrower frequency band of collected sound than a general microphone, has a sensitivity peak in a narrow frequency band, and tends to have low sensitivity at a frequency different from the peak frequency.

  On the other hand, the frequencies of sounds recognized as drum sounds are distributed in different frequency bands. For example, the attack sound generated immediately after hitting the drum head with a stick or the like is a relatively high frequency band, and the body sound generated by drum head vibration that continues after the attack sound is attenuated (depending on the tension acting on the drum head). The sound of a specific pitch to be determined is a sound in a relatively low frequency band. Further, a snare wire sound caused by a snare wire (also referred to as a snappy) attached to the snare side of the snare drum is generally a sound in a higher frequency band than the attack sound.

  In the interior of the drum, the internal standing wave is excited by hitting the drum head such that the particle velocity is zero and the sound pressure is maximum on the inner wall of the drum (the inner wall of the drum head or the inner wall of the shell). Such an internal standing wave often has a frequency band different from the frequency band of the sound as a drum performance sound such as an attack sound, a body sound, and a snare wire sound.

  Therefore, if a plurality of dynamic speakers having different frequency bands of sound to be collected are installed inside the drum head and shell, performance sounds such as attack sound, body sound, and snare wire sound are separated from each other and separated from each other. Sound can be collected by a dynamic speaker. In this case, it is possible to configure so that unnecessary internal standing waves are not collected. Needless to say, the frequency bands of the dynamic speakers need only be different, and a part of them may overlap.

  More specifically, a plurality of dynamic speakers are configured by a dynamic speaker that collects sound in the first frequency band and a dynamic speaker that collects sound in the second frequency band lower than the first frequency band. An example can be assumed. According to this configuration, either or both of the attack sound and the snare wire sound can be collected by the dynamic speaker that is the first frequency band in which the frequency band of the collected sound is relatively high. Further, the body sound can be collected by the dynamic speaker that is the second frequency band in which the frequency band of the sound to be collected is relatively low. Furthermore, an unnecessary internal standing wave existing in a frequency band between high and low sounds (a frequency band intermediate between frequency bands collected by these dynamic speakers) can be configured not to collect sound.

  Further, a plurality of dynamic speakers are configured by a dynamic speaker that collects an attack sound generated immediately after hitting the drum head and a dynamic speaker that collects a body sound generated by vibration of the drum head after the attack sound is attenuated. An example can be assumed. That is, if the frequency band including the main component of the attack sound in the drum and the frequency band including the main component of the body sound are specified in advance, a dynamic speaker that can collect the sound of each frequency band is provided inside the drum head and the shell. If installed, the attack sound and body sound are collected separately, and the internal standing wave that is in the frequency band between the attack sound frequency band and the body sound frequency band is not collected. It can be constituted as follows.

(1A) is a sectional view of a drum according to an embodiment of the present invention, (1B) is a sectional view of a first dynamic speaker, and (1C) is a sectional view of a second dynamic speaker. (2A) shows the frequency characteristics of the sensitivity of the dynamic speaker and microphone, (2B) shows the frequency characteristics of the relative sound pressure level of the bass drum, and (2C) shows the frequency characteristics of the relative sound pressure level of the tam tom. FIG. It is a figure which shows the frequency characteristic of the relative sound pressure level of a snare drum.

Here, embodiments of the present invention will be described in the following order.
(1) Drum configuration:
(2) Sound collection characteristics:
(3) Other embodiments:

(1) Drum configuration:
FIG. 1A is a cross-sectional view showing a drum 1 according to an embodiment of the present invention, and shows a state cut by a shell 10 and drum heads 20a and 20b. The shell 10 is a cylindrical member having a substantially constant inner diameter. Lugs 10c are attached to the outer wall of the shell 10 at a plurality of positions. In the present embodiment, the lugs 10c are attached to a plurality of positions (for example, six positions) along the circumferential direction, and at two positions along the height direction (a direction perpendicular to the opening surface of the shell 10). It is attached. A tuning pin 10b extending parallel to the height direction of the shell 10 is attached to the lug 10c.

  A hoop 10a is attached to the tuning pin 10b. The hoop 10a is a cylindrical member, and the inner diameter of the hoop 10a is larger than the outer diameter of the shell 10, and the outer diameter of the hoop 10a is determined by the distance between two tuning pins 10b arranged on an extension line of the diameter of the shell 10. small. Therefore, the hoop 10a can be disposed between the outer periphery of the shell 10 and the tuning pin 10b. Furthermore, by adjusting the tuning pin 10b with the hoop 10a attached to the tuning pin 10b, the position of the hoop 10a in the height direction can be adjusted.

  The drum heads 20a and 20b are thin circular members, and their edges can be attached to the hoop 10a. Therefore, the drum head 20a, 20b is attached to the hoop 10a, and the height of the hoop 10a is adjusted by the tuning pin 10b, thereby adjusting the tension acting on the drum head 20a, 20b. 20 a and 20 b can be attached to the open end of the shell 10. In this embodiment, the drum head 20a shown in the upper part in FIG. 1A is a surface (butter head) hit by a stick or the like, and the drum head 20b shown in the lower part in FIG. 1A is a surface (resonance) not hit by a stick or the like. Head).

  Inside the drum heads 20a and 20b and the shell 10, a first dynamic speaker 30a and a second dynamic speaker 30b are installed. In the present embodiment, plate-like holding members 31a and 31b are attached to two locations on the inner wall of the shell 10, and the first dynamic speaker 30a is attached to one surface (the surface on the drum head 20a side) of the holding member 31a. It is done. Further, the second dynamic speaker 30b is attached to one surface (the surface on the drum head 20a side) of the holding member 31b. In the present embodiment, the first dynamic speaker 30a is located closest to the maximum movable range without interfering with the maximum movable range of the drum head 20a when the drum head 20a is hit for performance. And the 2nd dynamic speaker 30b is arrange | positioned. That is, the first dynamic speaker 30a and the second dynamic speaker 30b are arranged as close to the drum head 20a as possible within a range that does not interfere with the operation of the drum head 20a.

  FIG. 1B is a cross-sectional view showing the structure of the first dynamic speaker 30a. As shown in FIG. 1B, the first dynamic speaker 30a includes a housing 30a1, a diaphragm 30a2, a permanent magnet 30a3, and a coil 30a4. The housing 30a1 is a member that supports the diaphragm 30a2 and the permanent magnet 30a3. In this embodiment, the housing 30a1 has an external shape such that two cylinders having different outer diameters are joined, and the inside is hollow with spaces having different inner diameters (Rb, Rs) formed therein. Opening is made at one end (upper end shown in FIG. 1B).

  The diaphragm 30a2 is a thin film diaphragm, and is stretched on the inner wall of a portion having a large inner diameter Rb in the hollow portion of the housing 30a1. The permanent magnet 30a3 has an outer diameter obtained by joining two cylinders having different outer diameters, and is attached to the inner wall on the opposite side to the opening of the housing 30a1. The inner diameter of the coil 30a4 is larger than the outer diameter of the permanent magnet 30a3, and the outer diameter of the coil 30a4 is smaller than the smaller inner diameter Rs in the hollow portion of the housing 30a1. Therefore, the coil 30a4 can be disposed between the inner wall constituting the small inner diameter Rs in the hollow portion of the housing 30a1 and the outer wall of the permanent magnet 30a3. The coil 30a4 is attached so as to extend from one surface of the diaphragm 30a2 (the lower surface shown in FIG. 1B) to the permanent magnet 30a3 side, and is held without contacting the permanent magnet 30a3.

  The coil 30a4 is connected to the wiring 32a shown in FIG. 1A (not shown in FIG. 1B). Therefore, when the diaphragm 30a2 vibrates due to the sound generated around the first dynamic speaker 30a, a signal corresponding to the vibration of the diaphragm 30a2 is output to the wiring 32a. The wiring 32a is connected to a connector 33a penetrating the inner wall and the outer wall of the shell 10, and by connecting an amplifier or the like to the connector 33a, a signal output to the wiring 32a can be taken out as a performance sound output. it can. In the present embodiment, the diaphragm 30a2 of the first dynamic speaker 30a is directed toward the drum head 20a. Therefore, in the first dynamic speaker 30a, the sound excited by the drum head 20a can be collected effectively.

  FIG. 1C is a cross-sectional view showing the structure of the second dynamic speaker 30b. As shown in FIG. 1C, the second dynamic speaker 30b includes a housing 30b1, a diaphragm 30b2, a permanent magnet 30b3, and a coil 30b4. The housing 30b1 is a member that supports the diaphragm 30b2 and the permanent magnet 30b3. In the present embodiment, the housing 30b1 has an outer shape like a hollow truncated cone, and the bottom surface Sb (larger plane: the upper surface in FIG. 1C) of the truncated cone is opened, and the bottom surface Sb An upper surface Ss (smaller plane: the lower surface in FIG. 1C) of the parallel truncated cone has a circular opening at the center.

  The diaphragm 30b2 is a thin film diaphragm and has an outer diameter of a truncated cone. The bottom surface Sdb (larger plane: the upper surface in FIG. 1C) of the truncated cone is opened, and the upper surface Sds (smaller plane: the lower surface in FIG. 1C) of the truncated cone is directed toward the inside of the truncated cone. Projecting into a spherical shape. Further, the diaphragm 30b2 is stretched at the opening on the bottom surface Sb side of the truncated cone of the housing 30b1.

  The permanent magnet 30b3 has a shape in which a cylinder Ch having a larger diameter is disposed around the thin column C and the column C and the cylinder Ch are connected to each other at one end. Accordingly, the permanent magnet 30b3 has a shape having a hole around the thin cylinder C at the center. In the present embodiment, the permanent magnet 30b3 is attached to the upper surface Ss of the truncated cone when the casing 30b1 is regarded as a truncated cone. The coil 30b4 has an outer diameter and an inner diameter that can be inserted into a hole around the thin cylinder C at the center of the permanent magnet 30b3, and the coil 30b4 can be disposed in the hole. The coil 30b4 is attached so as to extend from the upper surface Sds of the truncated cone of the diaphragm 30b2 to the permanent magnet 30b3 side, and is held without contacting the permanent magnet 30b3.

  The coil 30b4 is connected to the wiring 32b shown in FIG. 1A (not shown in FIG. 1C). Therefore, when the diaphragm 30b2 vibrates due to the sound generated around the second dynamic speaker 30b, a signal corresponding to the vibration of the diaphragm 30b2 is output to the wiring 32b. The wiring 32b is connected to a connector 33b penetrating the inner wall and the outer wall of the shell 10, and by connecting an amplifier or the like to the connector 33b, a signal output to the wiring 32b can be taken out as a performance sound output. it can. In the present embodiment, the diaphragm 30b2 of the second dynamic speaker 30b is directed toward the drum head 20a. Therefore, in the second dynamic speaker 30b, the sound excited by the drum head 20a can be collected effectively.

(2) Sound collection characteristics:
In the present embodiment, since the first dynamic speaker 30 a and the second dynamic speaker 30 b are installed inside the drum 1, a general microphone is used to prevent the sound field inside the drum 1 from being obstructed. The sound of the drum 1 can be collected in a more suppressed state. Further, since it is not necessary to arrange a sound collecting device outside the drum 1, the performance operation of the performer is not hindered, and the arrangement of the drum 1 at a position desired by the performer is not obstructed.

  Specifically, as shown in FIGS. 1B and 1C, the first dynamic speaker 30a and the second dynamic speaker 30b used in this embodiment are electromagnetic induction using a coil and a permanent magnet for vibration of the diaphragm. This is a configuration that is detected by the above, and is a very simple configuration as compared with a general microphone. That is, in a general microphone, in order to widen the frequency band of sound that can be collected, a front cavity is provided in front of the diaphragm (in the direction in which sound is incident), and a back cavity is provided behind the diaphragm. Configuration is adopted.

FIG. 2A shows the frequency characteristic S of the sensitivity of the dynamic speaker by a solid line, the frequency characteristic M ₁ of the sensitivity of the microphone having the back cavity by a broken line, and the frequency characteristic of the sensitivity of the microphone having the back cavity and the front cavity by a dashed line. it is a diagram showing a M _2. A speaker that does not include a cavity, such as the first dynamic speaker 30a and the second dynamic speaker 30b, can be considered as a one-degree-of-freedom spring mass system. Therefore, the frequency characteristic of the sensitivity has a peak at a specific frequency like the frequency characteristic S of FIG. 2A, and the sensitivity increases as the frequency increases at a frequency below the peak, and the sensitivity is the frequency at a frequency above the peak. It can be regarded as decreasing with increasing.

Meanwhile, a microphone with a back cavity is large in size than the first dynamic speaker 30a and the second dynamic speaker 30b, as shown in the frequency characteristic M ₁ in FIG. 2A, the high sensitivity and wide band from the frequency characteristic S It becomes a characteristic. A microphone having a back cavity and a front cavity is larger than a microphone having a back cavity, but has a higher sensitivity and a wider band characteristic than the frequency characteristic M _{1 as} shown by the frequency characteristic M ₂ in FIG. 2A.

  As described above, although the frequency characteristics of the dynamic speaker are narrower than those of a general microphone, the sound required as the performance sound of the drum 1 is the total frequency of the sound excited inside the drum 1 during the performance of the drum 1. Exist in some frequency bands. Therefore, if the first dynamic speaker 30a and the second dynamic speaker 30b are installed inside the drum 1 as in the present embodiment, it is possible to collect sound having a necessary frequency. And since the 1st dynamic speaker 30a and the 2nd dynamic speaker 30b are smaller than a general microphone, the state which suppressed the extent to which the sound field inside the drum 1 was inhibited rather than a general microphone The sound of drum 1 can be collected. Further, since it is not necessary to arrange a sound collecting device outside the drum 1, the performance operation of the performer is not hindered, and the arrangement of the drum 1 at a position desired by the performer is not obstructed.

Furthermore, in the interior of the drum 1, the sound pressure is extremely high compared to a general sound collection environment (for example, an environment in which a microphone is arranged outside the drum 1 to collect sound). Therefore, in the microphone such as the frequency characteristics M ₁ and M ₂ shown in FIG. 2A, which has higher sensitivity than the dynamic speaker, the diaphragm vibrates up to the upper limit of the vibration range due to the sound wave, and the sound wave cannot easily be collected. . However, since the dynamic speaker is generally less sensitive than the microphone, it is difficult for the diaphragm to vibrate to the upper limit of the vibration range. Therefore, according to the configuration in which the sound inside the drum 1 is collected by the dynamic speaker, it is easy to faithfully collect the sound wave.

  Furthermore, the sound required as the performance sound of the drum 1 can be roughly divided into two frequency bands. For example, the attack sound generated immediately after hitting the drum head 20a with a stick or the like is a relatively high frequency band, a body sound generated by vibration of the drum head 20a (a specific pitch determined according to the tension acting on the drum head). And the sound that is maintained for a relatively long time even after the attack sound is attenuated) is a sound in a relatively low frequency band. The body sound is a sound of a specific pitch generated according to the tension of the drum head 20a, and the attack sound is a sound in a higher frequency band than the sound of the specific pitch. It can be distinguished.

FIG. 2B is a diagram illustrating a general frequency characteristic of a bass drum, and FIG. In these figures, the relative sound pressure level (dB) with respect to the frequency is shown. In the bass drum shown in FIG. 2B, a peak P ₁ of the relative sound pressure level corresponding to the body sound exists in the vicinity of 80 Hz. After the relative sound pressure level is gradually decreased with a substantially constant slope in the semi-logarithmic graph at the above frequency, the relative sound pressure level is maintained substantially constant without decreasing in the band exceeding 700 Hz, and the frequency increases again from around 8000 Hz. Relative sound pressure level decreases. That is, in the bass drum shown in FIG. 2B, it can be seen that the body sound frequency band exists in the vicinity of 80 Hz, and the attack sound frequency band exists in the vicinity of 1000 Hz to 7000 Hz.

In the tom tom shown in FIG. 2C, there is a relative sound pressure level peak P ₂ corresponding to the body sound in the vicinity of 105 Hz, and after the relative sound pressure level gradually decreases with a substantially constant slope in the semi-logarithmic graph at higher frequencies. In the band exceeding 1000 Hz, the relative sound pressure level is maintained almost constant without decreasing, and the relative sound pressure level gradually decreases with increasing frequency from around 9000 Hz. That is, in the tom tom shown in FIG. 2C, it can be seen that the body sound frequency band exists near 105 Hz and the attack sound frequency band exists near 1100 Hz to 8000 Hz.

  The frequency characteristics shown in FIGS. 2B and 2C are the frequency characteristics of a specific bass drum or a specific tom tom. In general, the peak of the relative sound pressure level of the body sound is about 50 to 600 Hz, and the attack sound. The relative sound pressure level peaks in a band of about 600 to 10000 Hz.

  Therefore, in the present embodiment, the aperture of the diaphragm 30a2 of the first dynamic speaker 30a is configured to be smaller than the aperture of the diaphragm 30b2 of the second dynamic speaker 30b, and sound is collected by the first dynamic speaker 30a. When the frequency band of the sound is the first frequency band, the frequency band of the sound collected by the second dynamic speaker 30b is configured to be a second frequency band lower than the first frequency band. ing. Specifically, for example, the relative sound pressure level peak in the first dynamic speaker 30a is included in 600 to 10000 Hz, and the relative sound pressure level peak in the second dynamic speaker 30b is included in 50 to 600 Hz. Configured as follows. That is, the attack sound is collected by the first dynamic speaker 30a, and the body sound is collected by the second dynamic speaker 30b. As described above, in the present embodiment, since a plurality of dynamic speakers having different frequency bands of the sound to be collected are installed inside the drum head and the shell, the sound collection is performed while separating the attack sound and the body sound from each other. can do.

  Further, in the interior of the drum 1, an internal standing wave that excites the particle velocity at the inner wall of the drum 1 and maximizes the sound pressure is excited by hitting the drum head 20 a. Such an internal standing wave has a bad influence on sound as it is a lower-order internal standing wave (internal standing wave having a long wavelength). However, the internal standing wave is generated in the drum 1 having a normal size. In many cases, the frequency band is different from the frequency band of the sound as a drum performance sound such as an attack sound and a body sound (for example, around 500 Hz). In the present embodiment, the first dynamic speaker 30a and the second dynamic speaker 30b, which have a narrow frequency band of sound to be collected as compared with a general microphone, are used. Therefore, an unnecessary internal standing wave that exists between the frequency band of the attack sound and the frequency band of the body sound is not collected.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments can be adopted as long as the dynamic speaker is installed inside the drum. For example, the number of dynamic speakers installed inside the drum is not limited to two. That is, the frequency characteristic of the dynamic speaker is a characteristic in which a peak of sensitivity exists at a specific frequency and the sensitivity decreases at frequencies other than the peak, but the sensitivity does not become zero at frequencies other than the peak.

  Therefore, a configuration may be adopted in which one dynamic speaker is installed inside the drum so that a specific sound component of the drum is collected particularly accurately. For example, in the configuration shown in FIG. 1A, the second dynamic speaker 30b, the holding member 31b, the wiring 32b, and the connector 33b may be omitted, and the attack sound may be collected particularly accurately. In the configuration shown in FIG. 1A, the first dynamic speaker 30a, the holding member 31a, the wiring 32a, and the connector 33a may be omitted, and the body sound may be collected particularly accurately. In these configurations, compared to the configuration shown in FIG. 1A, the degree to which the formation of the sound field is inhibited is further suppressed, so that the focused sound (body sound or attack sound) is closer to the original sound. Can be collected as. Of course, the diameter of the dynamic speaker to be installed inside the drum 1 may not be the same as that of the dynamic speaker shown in FIG. 1A, and is between the diameter of the first dynamic speaker 30a and the diameter of the second dynamic speaker 30b. It may be a caliber, and various configurations can be adopted.

Furthermore, the structure which installs three or more dynamic speakers in the inside of a drum may be sufficient. FIG. 3 shows a general frequency characteristic of a snare drum in which a snare wire is attached to the snare side (drum head 20b side) in a drum having the same structure as the drum 1 shown in FIG. 1A. FIG. 3 shows the relative sound pressure level (dB) with respect to the frequency. A peak P ₃ of the relative sound pressure level corresponding to the body sound exists in the vicinity of 105 Hz, and is almost constant in the semilogarithmic graph at frequencies higher than that. After the relative sound pressure level gradually decreases with the slope of, the relative sound pressure level gradually decreases with a greater slope as the frequency increases from around 9000 Hz. However, when compared with the frequency characteristic of the tom tom shown in FIG. 2C, one peak (or zero) appears at the tom tom in the high frequency band, whereas two peaks P ₄ and P ₅ (near 2000 Hz) at the snare drum. And around 8000 Hz).

  In general, the snare wire sound resulting from the snare wire is a sound in a higher frequency band than the attack sound. Accordingly, in the frequency band of the snare drum shown in FIG. 3, the body sound frequency band exists near 105 Hz, the attack sound frequency band exists near 2000 Hz, and the snare wire frequency band exists near 8000 Hz. I understand. Further, in general, the relative sound pressure level peak of the body sound is about 50 to 600 Hz, the attack sound relative sound pressure level is about 600 to 10,000 Hz, and the snare wire sound relative sound pressure level is peak. Exists in a band of about 5000 Hz to 10000 Hz.

  Therefore, the snare drum may be configured to include the third dynamic speaker 30c in addition to the first dynamic speaker 30a and the second dynamic speaker 30b. In this case, the aperture of the diaphragm 30a2 of the first dynamic speaker 30a is smaller than the aperture of the diaphragm 30b2 of the second dynamic speaker 30b, and the aperture of the diaphragm of the third dynamic speaker 30c is the diaphragm 30a2 of the first dynamic speaker 30a. It is configured so as to be smaller than the aperture.

  That is, the frequency band of the sound collected by the third dynamic speaker 30c is configured to be the highest (so that the relative sound pressure level peak is included in 5000 Hz to 10000 Hz). In addition, the frequency band of the sound collected by the first dynamic speaker 30a is configured to be next higher than that of the third dynamic speaker 30c (the peak of the relative sound pressure level is included in 600 to 5000 Hz). And it is comprised so that the frequency band of the sound collected with the 2nd dynamic speaker 30b may become the lowest (the peak of a relative sound pressure level is contained in 50-600 Hz). As a result, the snare wire sound, the attack sound, and the body sound can be collected while being separated from each other.

DESCRIPTION OF SYMBOLS 1 ... Drum, 10 ... Shell, 10a ... Hoop, 10b ... Tuning pin, 10c ... Lug, 20a, 20b ... Drum head, 30a ... 1st dynamic speaker, 30a1 ... Case, 30a2 ... Diaphragm, 30a3 ... Permanent magnet, 30a4 ... Coil, 30b ... Second dynamic speaker, 30b1 ... Housing, 30b2 ... Diaphragm, 30b3 ... Permanent magnet, 30b4 ... Coil, 30c ... Dynamic speaker, 31a, 31b ... Holding member, 32a, 32b ... Wiring, 33a, 33b ... Connector

Claims (4)

A cylindrical shell and a drum head attached to one open end of the shell;
A dynamic speaker that collects a plurality of performance sounds installed inside the drum head and the shell;
Drum equipped with. The dynamic speaker is a dynamic speaker that collects sound in a first frequency band and a dynamic speaker that collects sound in a second frequency band lower than the first frequency band.
The drum according to claim 1. The dynamic speaker further includes a dynamic speaker that collects sound in a third frequency band higher than the first frequency band.
The drum according to claim 2. The dynamic speaker is a dynamic speaker that collects an attack sound generated immediately after hitting the drum head and a dynamic speaker that collects a body sound generated by vibration of the drum head after the attack sound is attenuated.
The drum according to any one of claims 1 to 3.

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