| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | WIND MUSICAL INSTRUMENT WITH FREE REEDS AND ADJUSTABLE SOUND PITCH | PCT/FR2017052152 | 2017-07-31 | WO2018024976A3 | 2018-07-12 | TCHUMAK PHILIPPE |
| The invention relates mainly to a wind instrument with free reeds comprising a frame onto which a blowing mouthpiece, opening into a reservoir, is mounted, and a plurality of keys, each key being linked with a valve, the movement of which valve, caused by the instrumentalist actuating the corresponding key, connects the reservoir with a first upstream cavity that opens out onto a blade formed by a reed mounted on a frame, allowing the blade to vibrate. The instrument is essentially characterised in that each blade (13,13a,13b) opens out, in the direction of the blown air flow, on an opening (20, 20a, 46b) through which the air flows outwards; in that the instrument thus has at least a first plurality of air flow openings (20, 20a, 46b) arranged in a single plane; in that it includes closure means (22, 22a, 44b) for closing said air flow openings (20, 20a, 46b), that can be actuated by the instrumentalist and that can move to a first, open position in which the air flowing through the air flow openings (20, 20a, 46b) is not subjected to any pressure, and a second, closed position in which the closure means (22, 22a, 44b) simultaneously cover all the air flow openings (20, 20a, 46b); and in that, from the first position to the second position, the closure means (22, 22a, 44b) are able to move to a plurality of positions that increase the air pressure in the vicinity of the blades (13,13a,13b), thereby lowering the sound frequency of the blades in question (13,13a,13b) . | ||||||
| 102 | SET OF ORGAN PIPES | PCT/EP2011055121 | 2011-04-01 | WO2011121119A3 | 2011-12-01 | DELPORTE DENYS |
| The present invention relates to a set of organ pipes including at least 54 pipes, characterized in that said set has a variation in the richness of the harmonics generated by said pipes during use, and in that the ratio of the intensity of the first harmonic to the intensity of the fundamental is at a maximum at a frequency between 150 and 500 Hz, preferably between 200 and 300 Hz, wherein said maximum is different by at least 20dB with respect to the ratio of the intensity of the first harmonic to the fundamental of the pipe producing the lowest frequency note. | ||||||
| 103 | SYSTEM AND METHOD FOR HAPTIC INSTRUMENTAL ELECTRONIC DEVICE | US15946463 | 2018-04-05 | US20180330705A1 | 2018-11-15 | Wojciech Karim Palmowski |
| Embodiments of the disclosure provide a haptic instrumental device comprising an electronic device having a display screen, one or more keys provided along the display screen, and one or more brackets coupled with the one or more keys and secured to the electronic device. Further, the one or more keys may include one or more capacitive nibs that, when pressed against the display screen, cause the electronic device to receive an input. | ||||||
| 104 | SUPPORT ASSEMBLY AND KEYBOARD APPARATUS | US15952826 | 2018-04-13 | US20180233114A1 | 2018-08-16 | Akito OHBA; Shunsuke ICHIKI |
| A support assembly according to one embodiment of the present invention is provided, the support assembly including a jack rotatably supported by a support; a repetition lever rotatably supported with respect to the support; a protrusion disposed at an intersecting portion of the jack and the repetition lever; and a protrusion receiving portion for receiving the protrusion; wherein the protrusion receiving portion defines a movable range of the protrusion and limits a rotation range of the jack. | ||||||
| 105 | ULTIMATE FLEXIBILITY WIRELESS SYSTEM FOR REMOTE AUDIO EFFECTS PEDALS | US14687728 | 2015-04-15 | US20150221294A1 | 2015-08-06 | Michael J. Vumbaco; James Arcidiacono |
| A system for providing wireless connections in configuring an instrument or microphone with audio effects, effects pedal boards, mixers, and other studio equipment. The signal from an audio source such as an instrument or microphone is connected to a main unit, from which it is transmitted via wireless link to a floor unit connected to one or more effects pedals or other studio equipment. After processing, the audio signal is returned via wireless link to the main unit and then routed to an amplifier. | ||||||
| 106 | Ultimate flexibility wireless system for remote audio effects pedals | US13670353 | 2012-11-06 | US09012748B2 | 2015-04-21 | Michael J. Vumbaco; James Arcidiacono |
| A system for providing wireless connections in configuring an instrument or microphone with audio effects, effects pedal boards, mixers, and other studio equipment. The signal from an audio source such as an instrument or microphone is connected to a main unit, from which it is transmitted via wireless link to a floor unit connected to one or more effects pedals or other studio equipment. After processing, the audio signal is returned via wireless link to the main unit and then routed to an amplifier. | ||||||
| 107 | Tone control device | US13919970 | 2013-06-17 | US08835732B2 | 2014-09-16 | Junichi Miki; John K. McFerran; Takahiro Sugizaki; Kenji Nogami |
| Provided is a tone control device coupled to a musical instrument including a plurality of pipes capable of generating tones with differing pitches for keys, wherein the pipes are arranged in rows, comprising: a tone generation device that generates tone; a pipe designation device that designates a specified pipe among the pipes installed; and a control device that causes the tone generation device to generate a substituting tone corresponding to the specified pipe when a depressed key comprising one of the keys corresponds to the specified pipe designated by the pipe designation device, and the specified pipe is a pipe belonging to one of the rows of pipes designated as a tone generation subject for the depressed key. | ||||||
| 108 | ULTIMATE FLEXIBILITY WIRELESS SYSTEM FOR REMOTE AUDIO EFFECTS PEDALS | US13670353 | 2012-11-06 | US20140126609A1 | 2014-05-08 | Michael J. Vumbaco; James Arcidiacono |
| A system for providing wireless connections in configuring an instrument or microphone with audio effects, effects pedal boards, mixers, and other studio equipment. The signal from an audio source such as an instrument or microphone is connected to a main unit, from which it is transmitted via wireless link to a floor unit connected to one or more effects pedals or other studio equipment. After processing, the audio signal is returned via wireless link to the main unit and then routed to an amplifier. | ||||||
| 109 | Action magnets and drivers to reduce musical instrument wiring, connections, and logic | US13570664 | 2012-08-09 | US08609971B2 | 2013-12-17 | William Henry Morong |
| The present invention provides, for musical instruments such as organs, action-magnets and action-magnet drivers that facilitate reduction of wiring, connections, and logic circuitry. Some embodiments of present invention provide stop action-magnets, also called SAM's, comprising integral drive circuitry and, which may further comprise additional integral circuitry. Embodiments of this invention may comprise, logic circuits such as a shift-register cells, micro-controllers, or both. Some embodiments of this invention comprise shift-cells and registers combining both SIPO and PISO functions for addressing SAM's. A single-coil SAM embodiment of the present invention may respond to signals intended to operate traditional two-coil SAM's. In another embodiment, a pipe action-magnet driver comprises logic circuitry. In yet another embodiment a pipe action-magnet comprises an integral driver that further comprises logic circuitry. | ||||||
| 110 | Method Used to Tune an Electronic Organ with Associate air Organ pipes | US12083578 | 2006-01-23 | US20090229446A1 | 2009-09-17 | Rolando Luciani |
| The present invention refers to a method used to automatically tune, thanks to the presence of a suitably designed electronic device, an electronic organ with the air organ pipes associated with it; it being provided, in particular, that the said operation is performed based on the tuning variations detected in real time on the air pipes based on parameters referring to the frequency of the emitted sound and to environmental temperature. | ||||||
| 111 | Construction and method of wind musical instrument | US10271210 | 2002-10-15 | US06852917B2 | 2005-02-08 | Michael McAleenan |
| An associated method of construction and fabrication of organ windpipes and wind musical instruments utilizing composite materials. The fiber reinforced composite construction is a combination of fibers and resinous material. The fibrous material, maybe Carbon fibers, and/or Kevlar fibers, and/or Fiberglass fibers, and/or Wood Veneer(s) and/or core material, or any combination thereof, which is oriented and layered to create a laminate. The fibrous material can be pre-impregnated with a resinous material or impregnated with a resinous material. The acoustical resonance properties of the fiber reinforced composite wall material or laminate resonates with the generated pressure wave of the wind musical instrument, thereby providing improved tonal and acoustic performance.The lightweight fiber reinforced composite wind instrument, produces richer and more brilliant tones, as well as multiple harmonics. In the preferred embodiment, there are minimal dimensional changes unfavorably affecting the musical sound qualities, such as shrinkage or elongation from adverse environmental conditions. | ||||||
| 112 | Electromagnetically operated valve | US68792 | 1993-06-01 | US5370029A | 1994-12-06 | Justin Kramer |
| An electromagnetically operated valve assembly having a valve closure means attached to a vertically suspended armature supported at its top portion, is held in magnetic fields at both the top and bottom portions of the armature, caused by permanent magnets reacting to iron or other permanent magnets. The movement of the armature is guided to insure close alignment and to eliminate side play by means of a main frame assembly mounted in a pipe organ wind chest so as to control air under pressure from the wind chest into at least one pipe organ. The permanent magnet at the bottom portion of the armature cooperates with an iron core of a solenoid mounted to the main frame assembly, to close or open the valve. The valve may also be provided with a second solenoid to both assist moving the valve to the open position, and to aid in holding the valve in the open position. | ||||||
| 113 | Tracker action touch for keys in a keyboard musical instrument | US456061 | 1983-01-06 | US4479415A | 1984-10-30 | Harold E. Haberstumpf |
| A key action for an electronic musical instrument for simulating a mechanical-type tracker action having a single means embodying an electrical contact means and a motion retarding means to cause a toggling of the key while the electrical contact is maintained. | ||||||
| 114 | Pipe organ | US182211 | 1980-08-28 | US4408517A | 1983-10-11 | Leonard W. Ellen |
| A pipe organ in which information relevant to actuation of keys and stops at a console of the organ is stored in random access memory, and the specifications for stops are held in pre-programmed read only memory, the requirements for each pipe being examined in turn by scanning means. | ||||||
| 115 | Electronically controlled swell shutter operator for pipe organs | US189999 | 1980-09-23 | US4361069A | 1982-11-30 | Richard H. Peterson; James A. Mornar |
| An electronically controlled swell shutter operator for pipe organs includes an electric motor driving a speed reducer whose output is connected to move the shutters of a pipe organ swell chamber, in order to control the volume of sound heard by the listeners. A swell pedal controlled by the organ player operates a first potentiometer and establishes a first voltage of a given polarity, the magnitude of which represents the exact position that the shutters should be in. The output of the speed reducer operates a second potentiometer which establishes a second voltage of a polarity opposite to that of the swell pedal potentiometer, the magnitude of this second voltage being dependent on the position of the swell shutters. A system of integrated circuit comparators compares the above-mentioned first and second voltages to produce an error signal. A logic system responds to the comparison result to cause the shutters to move in a desired direction and at a suitable speed to reduce the error and to achieve a balance, whereby the swell shutters assume a position corresponding to the position of the swell pedal. Dynamic braking and a system of automatically adjustable dead bands prevents overshoot and hunting. | ||||||
| 116 | Hybrid pipe organ with electronic tonal augmentation | US189984 | 1980-09-23 | US4350073A | 1982-09-21 | Richard H. Peterson |
| A hybrid organ is disclosed wherein many of the musical tones comprising the complete musical instrument are produced by wind blown pipes. Other tones are produced by an electronic tone generating system and produced by loudspeakers. The electronic tone generating system is adapted especially for this purpose and includes simplified means for keeping the electronically produced tones in tune with the organ pipes in spite of the fact that the pipes change their pitch with even slight temperature and other atmopsheric changes. | ||||||
| 117 | Actuator for capture type combination system in organs | US277336 | 1981-06-25 | US4347774A | 1982-09-07 | Irene Roy |
| There is disclosed an actuator for the selector hooks of the capture type combination system used in mechanical or electro-pneumatic organs. All the selector hooks which have been shifted to operating position are simultaneously pulled down by a mechanism actuated by a crank system driven by an electric motor. | ||||||
| 118 | Electronic pipe valve | US190001 | 1980-09-23 | US4341145A | 1982-07-27 | Richard H. Peterson |
| An electronically controlled pipe valve magnet is disclosed. The valve magnet is a solenoid which activates a movable armature to open and close the air flow passageway between a pipe organ wind chest and an individual pipe. The pipe valve is electronically operated by means of a control circuit mounted directly on the solenoid by means of a circuit board which is easily accessible and which may be quickly replaced in the event of circuit failure. The electronic control circuit allows the relatively high solenoid currents to be switched by means of a relatively small control signal, thereby reducing the size and weight of the control cable leading from a keyboard console to the numerous pipe valves in a wind chest. The control circuit is economical and safe for use in a wind chest, and, since relatively low control currents are required, a large number of magnets can be operated directly from a single key contact. | ||||||
| 119 | Blind capture system | US121406 | 1980-02-14 | US4300436A | 1981-11-17 | Gary R. Fritz; John W. Robinson |
| A blind capture system for organs and other electronically actuated musical instruments enabling the setting of control switches, such as voicing tabs or keys of the keyboard, to be stored for reactivation upon command. The system includes a programmable, random access memory capable of storing data representative of the composite states of the switches and includes a plurality of storage frames in which data corresponding to a plurality of separate combinations of actuated switches can be stored. The switches are scanned by a multiplexer to produce a time division multiplexed serial data stream, which is then loaded into the memory during the store mode in such a manner that the data will be entered into the proper storage frame. The data is read out of the memory as a serial data stream, which is demultiplexed to produce a parallel format signal which is connected to the control inputs for the system controlled by the switches over a bidirectional data bus. This same bus is utilized for entering data from the switches when the instrument is in the store mode. When the blind capture system is in use, the switches are electrically isolated from the inputs of the system controlled thereby, such as the organ voicing system, and all control is maintained from the blind capture system over the bidirectional data bus. | ||||||
| 120 | Computerized unit organ relay | US820149 | 1977-07-29 | US4178828A | 1979-12-18 | Lawrence J. Henschen |
| A computerized unit organ relay which utilizes computer hardware and software to interconnect the pipes of the organ with the organ console in such a fashion that the proper pipes are activated in response to the key-stop combinations designated at the console. All of the keys of the various keyboards, and their associated stops, are connected through appropriate input ports to the data processing device which, in a preferred form, comprises a programmed microcomputer. The computer software acts on the input data from the keys and stops to calculate which of the pipes should be activated in response to actuated keys and stops. This information is stored in a continuously updated array and is read out of the computer memory, via appropriate output interface devices, to activate the corresponding pipes of the organ. | ||||||
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