JP7470314B2 - organ - Google Patents

Description

The present invention relates to an organ, a musical instrument that produces sound by blowing air into it.

Traditionally, organs use a pedal or other device to activate a pump, which sends air into the reeds, causing them to vibrate and produce sound.

In other musical instruments, there is a technique called "vibrato" that vibrates the sound as a form of musical expression, but in the case of organs, a constant supply of air is usually used, and no means of applying vibrato had been developed. For example, Patent Document 1 describes an electronic organ that can apply vibrato.

JP 48-003728 A

However, electronic organ vibrato cannot be applied to an acoustic organ.

The present invention aims to solve the above problems and realize vibrato on the organ, an acoustic musical instrument.

To solve the above problems, the organ of the present invention is an organ that has a sound generating section, a pump section, a pipe section that sends air from the pump section to the sound generating section, and a first air bag and a second air bag provided in the middle of the pipe section.

FIG. 1 is a perspective view showing an organ according to an embodiment. FIG. 2 is a partially enlarged perspective view of FIG. 1 . FIG. 2 is a perspective view showing a lead member in FIG. 1 . 4 is a cross-sectional view taken along the line AA in FIG. 3. FIG. 2 is a perspective view showing a state in which a variable pipe is attached to the organ in FIG. 1.

We will now explain an embodiment of the organ of the present invention. Figure 1 is a perspective view showing the organ of the embodiment.

As shown in FIG. 1, the organ 1 of this embodiment has multiple reed pipes 2 that are sound-producing sections, two foot pumps 3 that serve as pump sections, a pipe section 4 that sends air from the foot pumps 3 to the reed pipes 2, and a first balloon 5 that serves as a first air bag provided in the middle of the pipe section, a second balloon 6 that serves as a second air bag, and a third balloon 7 that serves as a third air bag.

3 and 4, the reed pipe 2 is provided with a T-shaped outer pipe 21, a straight inner pipe 22 inserted into the long side of the outer pipe 21, a sheet member 23 pressed against the ends of the outer pipe 21 and the inner pipe 22, a rubber band 24 that is wound around the outer pipe 21 while pressing the sheet member 23 against the ends with a certain degree of tension to fix the sheet member 23, and a packing 25 that fills the gap between the inner pipe 22 and the outer pipe 21 at the other end of the outer pipe 21. When air is supplied from the end of the short side of the outer pipe 21, the packing 25 sends the air to the sheet member 23 side, pushes the sheet member 23, and supplies it into the inner pipe 22. At this time, the sheet member 23 vibrates because it is given tension by the rubber band 24, and produces a sound between the sheet member 23 and the inner pipe 22. The inner pipe 22 protrudes from the other end of the outer pipe 21, and the pitch changes depending on the length of the inner pipe 22. In this way, a lead pipe 2 can be made from simple materials to function as a sound-producing part with adjustable pitch.

As shown in FIG. 2, each lead pipe 2 is provided with an on-off valve 8 at the connection with the pipe section 4. By pressing this on-off valve 8, the valve opens, and air from the pipe section 4 can be supplied to the lead pipe 2. The on-off valve 8 is biased in the opening direction, so when the on-off valve 8 is released, the valve closes and the supply of air to the lead pipe 2 stops. In addition, by sliding the on-off valve 8 forward while pressing it, the valve can be kept open. By sliding the on-off valve 8 backward, the valve is released from being kept open. In this way, the on-off valve 8 can be used to select and play notes of each scale, allowing a piece to be played as an organ. By leaving the on-off valve 8 open, a performance using the so-called drone technique can be performed.

The pipe section 4 has a branch section 41 for connecting to the lead pipe 2. The tip of the branch section 41 is connected to the on-off valve 8 described above, and the base is connected to the trunk pipes 42 arranged in two tiers, one above the other. These trunk pipes 42 are designed in two tiers because, due to the arrangement of the parts, if they were arranged in a single tier, the spacing between the lead pipes 2 would have to be wider.

As shown in FIG. 2, the upper trunk pipe 42a is connected to a T-shaped pipe 43 at the left end of the figure, and is connected to a first balloon 5 as a first air bag and a second balloon 6 as a second air bag via on-off valves 44 and 45, respectively. Also, as shown in FIG. 1, it is connected to a third balloon 7 at the right end via an on-off valve 46. The third balloon 7 is relayed by an extension pipe 47 and is located on the floor.

As shown in FIG. 1, the lower trunk pipe 42b is connected at its left and right ends to the first pump section 31 and the second pump section 32 via bellows pipes 48 and 49.

The organ 1 is constructed as a whole in this manner, but it is important that the first balloon 5 is softer and easier to inflate than the second balloon 6 and the third balloon 7. Since there are individual differences even among the same balloons, it is best to use the one that is easiest to inflate as the first balloon 5, but it may also be designed in advance to be easy to inflate.

To play such an organ 1, first, air is sent into the pipe section 4 by stepping on the first pump section 31 and/or the second pump section 32. At this time, the on-off valves 44, 45, and 46 of the first balloon 5, second balloon 6, and third balloon 7 are opened to increase the air pressure inside each balloon. As mentioned above, the first balloon 5 is relatively easy to inflate, so it begins to inflate as the internal air pressure increases. On the other hand, the second balloon 6 and third balloon 7 do not inflate beyond a certain level. The pump section 3 is equipped with a check valve, so air does not escape even when you stop stepping on it.

When the first balloon 5 is inflated as shown in Figure 1, pressing the valve 8 of the reed pipe 2 causes air to flow into the reed pipe 2, causing the sheet member 23 acting as a reed to vibrate and produce sound. As mentioned above, the scale is adjusted by the length of the inner pipe 22, so pressing the valve 8 at the appropriate position allows the instrument to be played as an organ.

The pressure of the air that the first balloon 5 sends out as it deflates is almost constant from start to finish. Therefore, during normal playing, the sound is almost constant and can be played at a constant intensity. On the other hand, when the second balloon 6 or the third balloon 7 is grasped or stepped on and pressed while sound is being produced, the air pressure inside the pipe section 4 rises at that moment. When pressure is stopped, the air pressure inside the pipe section 4 returns to normal. In this way, by intermittently pressing the second balloon 6 or the third balloon 7 as if squeezing it, it is possible to vary the volume of the sound, i.e., to produce the so-called vibrato effect.

Figure 5 shows a further development of the organ 1 described above, where a variable pipe 27 has been attached to the tip of the inner pipe 22 of the lead pipe 2 in order to realize not only dynamics, i.e., vibrato of volume, but also pitch, i.e., vibrato of musical intervals. The variable pipe 27 has an inner diameter that is almost the same as, but slightly larger than, the outer diameter of the inner pipe 22, and can be easily moved up and down by hand when attached to the tip of the inner pipe 22, and when released, friction causes it to remain at any position on the inner pipe 22. The length of the variable pipe 27 is also shorter than the inner pipe 22 to which it is attached.

When such a variable pipe 27 is moved up and down along the inner pipe 22, the pitch of the lead pipe 2 becomes lower by the amount that it extends upward from the inner pipe 22. Therefore, by adjusting the amount that the variable pipe 27 protrudes from and retracts from the tip of the inner pipe 22, the pitch can be adjusted, and the pitch can be changed fluidly while the sound is being produced. In addition, if the variable pipe 27 is moved up and down in small increments while the sound is being produced, a vibrato effect in the pitch can be produced.

In this way, according to the present invention, it is possible to play a vibrato with an organ, which continuously changes the volume and pitch of the sound. The pump section and air bag can be the same as those used in conventional organs, and the sound generating section can be a whistle-shaped one instead of a reed. With the organ 1 of this embodiment, if the reed pipe 2 is removed and a whistle-shaped sound generating section is attached, it is easy to play with different sounds.

1 Organ 2 Reed pipe 3 Foot pump 4 Pipe section 5 First balloon 6 Second balloon 7 Third balloon

Claims (1)

1. An organ having a sound generating section, a pump section, a pipe section for sending air from the pump section to the sound generating section, and a first air bag and a second air bag provided in the middle of the pipe section,
The first air bag has a characteristic of being more easily inflated than the second air bag,
Pressing the second air bag produces a vibrato effect.
organ.

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