RU2753068C1 - Heat-insulated button of valve lever of saxophone keyboard - Google Patents

Abstract

FIELD: musical instruments.

SUBSTANCE: invention relates to musical instruments, in particular to their keyboards, which allows the musician’s hands to perform musical works with high accuracy at the desired tempo and quality, regardless of the ambient temperature. The heat-insulated button of the valve lever of the saxophone keyboard is designed to insulate the fingers of the musician’s hands when performing a musical work in cold conditions, it is made in the form of a metal saucer with a rounded bottom and raised edges, filled to the top with a white or black plastic material with a concave smooth and slippery outer surface on which symbols can be engraved or printed. A 0.5-1.0 mm thick gasket made of synthetic porous ultralight solid aerogel with the lowest thermal conductivity is firmly placed between the pad and the metal part of the button on the entire area of their contact with each other. In cold conditions, the button of the valve lever of the saxophone keyboard.

EFFECT: invention prevents excessively intense and deep cooling of the musician’s fingertips, swelling, tight mobility, surface anesthesia, deterioration of accuracy and slowing down the speed of movement of the fingers on the keyboard buttons, slowing down the tempo and quality of performance of a musical work.

1 cl, 1 dwg

Description

The invention relates to musical instruments, in particular to their keyboard, allowing the hands of a musician to perform musical works with high accuracy at the desired tempo regardless of the ambient temperature.

Known metal alto saxophone, made with valve levers, the free ends of which end with metal buttons (Alto saxophone keys, https://allmusicalinstruments.net/saxophone-types/alto-saxophone-keys/) [1].

The disadvantage of the known metal buttons is a narrow range of application, low efficiency, accuracy and safety, since they do not provide the use of a material with low thermal conductivity for thermal insulation of the working surface of the button from the metal valve lever and from the connected saxophone body made of metal with high thermal conductivity with weighing from 1.9 to 9 kg. The fact is that saxophones are made of special metal alloys: tombak (an alloy of copper and zinc), pakfong (the same composition, with the addition of nickel) or brass, which have a very high thermal conductivity. Therefore, during performance of a piece of music in cold conditions, the known button intensely lowers the temperature of the musician's fingertip to excessively low values when it comes into contact with the surface of the button. Cooling the finger disrupts metabolism, plasticity, sensitivity, changes the volume of soft tissues and functional activity of the finger, which ultimately slows down the tempo for many people and impairs the quality of the performance of a piece of music on the saxophone.

The fact is that the appearance of a zone of local hypothermia in the distal phalanx of the finger in some people leads to a biphasic reaction of the blood vessels of the finger. Moreover, usually in the first phase of the action of cold, a spasm of blood vessels develops, which is combined with the appearance of a feeling of tingling and paresthesia, and sometimes a feeling of aches and pains in the cooled fingertip, since pain receptors located inside the vascular walls are irritated with vasospasm (Urakov A. L., Baranov A.G., Sutyagin S.P., Odiyankov E.G., Ipatova E.N., Kapachinskaya L.G., Petlenko V.B., Kolodkin D.E., Baramba R.I. Improving blood flow in organs and preventing thrombus formation with the help of cold Bulletin of Experimental Biology and Medicine 1985; 719-20) [2]; (Urakov AL, Odiyankov EG, Odiyankov YG, Muravyov MF, Kolodkin DE, Volkov VV Local hypothermia in the treatment of acute obstruction of the limb arteries. Bulletin of surgery. 1988; 7: 62-65.) [3]; (Muravyov M.F., Odiyankov E.G., Urakov A.L., Odiyankov Yu.G., Maryin G.G. Pharmacological cold therapy in severe chronic lower limb ischemia. Surgery. 1989; 3: 25-29.) [4].

Cooling the fingertips first leads to thickening of the blood inside the vessels, to a decrease in the elasticity of the soft tissues of the phalanges of the fingers and to surface anesthesia in the pads. Then, a longer cooling of the fingers in them leads to the replacement of vasoconstriction with vasodilation, that is, to cold paralysis of the blood vessels. Cold paralysis of the blood vessels increases the blood supply to the vessels and the volume of the distal phalanx of the finger. As a result, the toe suddenly becomes red and puffy due to cold hyperemia and increased blood flow to it. As a result, the functional activity and size of the finger suddenly change, which prevents an unadapted musician from playing music correctly on the famous saxophone. It is important to note that cold paralysis of the vessels of chilled fingers develops in different people in different ways, and each person depends on many factors. The phenomenon itself was first described about 100 years ago and was called hunting response or cold-induced vasodilatation (CIVD) (Cheung SS Responses of the hands and feet to cold exposure. Temperature (Austin). 2015 ; 2 (1): 105-120. Published 2015 Feb 27. doi: 10.1080 / 23328940.2015.1008890.) [5].

Known buttons on the free ends of the metal valve levers of the accordion keyboard, each of which is made in the form of a metal saucer with a rounded bottom and raised edges, filled to the top with an overlay made of white or black plastic material with a smooth and slippery surface, the bottom of the saucer is covered with a layer of clean outside not dyed and soft leather (Repair of buttons on the accordion. http://russian-garmon.ru/forum-home/obsluzhivanie-i-remont/25058-remont-knopok-na-garmoni.) [6].

The disadvantages of the known buttons are a narrow range of application, low efficiency, accuracy and safety, since they do not provide the use of materials with low thermal conductivity. Therefore, when performing a piece of music in cold conditions, the known buttons do not maintain a normal temperature in the musician's fingertips. Moreover, the known buttons are made of materials with high thermal conductivity, placed on the free ends of metal arms with high thermal conductivity, covered with pads made of plastic material with high thermal conductivity, and are not isolated from the metal parts of the buttons by spacers made of material with low thermal conductivity. Therefore, in cold conditions, the well-known buttons are cooled to ambient temperature, and upon contact with the musician's fingers, they intensively take heat from them, which is why the fingertips are quickly cooled.

Local cooling of the fingertips after a few minutes causes a spasm of blood vessels in them, reduces the delivery of warm blood to the phalanges of the fingers, to thickening of blood inside the vessels, to a decrease in the elasticity of the soft tissues of the phalanges of the fingers, to a decrease in tactile sensitivity in the pads (to the development of surface anesthesia) and to the appearance of a feeling of pain inside the fingers. All this, from the first minutes of performing a piece of music in cold conditions, slows down the tempo and makes it difficult to perform a piece of music.

Longer cooling of the fingers leads after 8-15 minutes to the replacement of vasoconstriction in them with vasodilation, that is, to cold paralysis of the blood vessels of the fingers [2]. Cold paralysis of the blood vessels increases the volume of blood vessels and the volume of the fingertips, which, due to the resulting cold hyperemia, suddenly turn red, plump and lengthen. Changes in the elasticity, functional activity and size of the fingers make it difficult for the musician to use them as usual for playing a musical instrument and performing a piece of music at the desired tempo.

Known buttons for metal levers of typewriter keyboards, made of metal or plastic with a concave working surface on which characters can be engraved or printed (Computer keyboard. Https://en.wikipedia.org/wiki/Computer_keyboard.) [7].

The disadvantage of the known buttons is a narrow range of application, low efficiency, accuracy and safety, since they do not provide the use of materials with low thermal conductivity, therefore, do not exclude intense and deep local cooling of the fingertips when in contact with them in cold conditions. Moreover, in cold conditions, the known buttons quickly cool to ambient temperature, and upon contact with fingers, they intensively take heat from them, which causes a deep local cooling of the fingers quickly.

Local cooling of the fingers spasms the blood vessels in the phalanges of the fingers, thickens the blood inside the vessels, reduces the supply of warm blood to the phalanges of the fingers, reduces their elasticity, causes stiff mobility, surface anesthesia in the pads and causes a feeling of pain inside the fingers. All this, a few minutes after the beginning of the period of repeated contact of the finger pad with the known button, causes progressive cooling of the finger, its stiff mobility, worsens the "obedience" of the finger, its reactivity, reduces the accuracy of selecting buttons on the keyboard and slows down the speed.

Longer periodical repetitive contact of the fingers with the buttons in cold conditions leads to the fact that the known buttons continuously remove heat from the fingertips, causing them to cool longer and deeper and replace vasoconstriction with vasodilation in the fingers. This vasodilation is known as cold blood vessel paralysis [2]. Cold paralysis of the blood vessels in the fingers increases the volume of blood vessels and the volume of the fingers. The toes become thicker and longer. Changes in finger elasticity, function, and size make it difficult to use them to accurately locate the desired buttons and quickly move fingers from button to button on the keyboard, which slows down the speed.

The objective of the invention is to expand the scope of application, improve efficiency, safety and accuracy by placing between the plastic pad and the metal part of the button gaskets with a thickness of 0.5-1.0 mm, made of synthetic porous ultra-light solid airgel with the lowest thermal conductivity, excluding intense heat dissipation from the pads of the fingers of the musician's hands, the development in them of deep local hypothermia, cold vasoconstriction, subsequent cold vasodilation, superficial anesthesia and feelings of deep pain.

The technical result is to prevent excessive cooling of the fingertips of the musician's hand, surface anesthesia of the pads, swelling, stiff mobility, inaccurate movement of the fingers over the keyboard buttons, slowing down the tempo and quality of the performance of the musical work when performing musical works in cold conditions.

The essence of the invented insulated valve lever button of the saxophone keyboard, designed for thermal insulation of the musician's fingers when performing a piece of music in cold conditions, made in the form of a metal saucer with a rounded bottom and raised edges, filled to the top with an overlay made of plastic material of white or black color with a concave smooth and slippery the outer surface, on which symbols can be engraved or printed, is that between the cover and the metal part of the button over the entire area of their contact with each other, a gasket 0.5-1.0 mm thick is firmly placed, made of synthetic porous ultra-light hard airgel with the lowest thermal conductivity.

In the claimed device, the placement of a spacer made of synthetic porous ultra-light solid airgel with the lowest thermal conductivity between the plastic cover and the metal part of the button over the entire area of their contact with each other provides reliable thermal insulation of the plastic cover from the metal button saucer, metal valve lever and through it from all other metal parts of the saxophone. Thermal insulation of the plastic overlay from the metal parts of the saxophone eliminates excessive and prolonged heat removal from the musician's fingertip when the fingertip is pressed against the button pad while playing a piece of music on the saxophone in cold conditions. The fact is that modern saxophones have metal valves connected by metal levers with metal buttons. Moreover, all of these elements of saxophones are made of special metal alloys: tombak (which is an alloy of copper and zinc), pakfong (which is an alloy of copper and zinc with the addition of nickel) or brass, which have a very high thermal conductivity. In this case, the saxophone has a mass from 1.9-2.5 to 9.0 kg. Therefore, when performing music in cold conditions, the saxophone is a kind of refrigerator for the musician's fingers.

The firm placement of the pad ensures high strength of the pad connection and high reliability of the invented device when performing musical works.

Placement of a 0.5-1.0 mm thick pad is aimed at, on the one hand, a minimum increase in the mass and size of the button, on the other hand, effective thermal insulation of the pad, sufficient to prevent excessive and deep heat removal from the finger and excessive cooling of the finger pad. the hands of a musician while performing a piece of music in cold conditions. At the same time, the declared range of the pad thickness is optimal, since a thinner pad does not provide effective thermal insulation of the pad from the metal part of the button and the saxophone lever, and a thicker pad increases the height of the pad protrusion from the button "socket", exceeding the pad thickness, which causes its early peeling and loss during transport of the saxophone and / or during the performance of a piece of music and reduces efficiency.

The lining is made of synthetic porous ultra-light solid airgel with the lowest thermal conductivity, which ensures the highest efficiency and strength of thermal insulation of the lining from the metal part of the button and its metal lever.

Thus, firm placement of a 0.5-1.0 mm thick pad made of synthetic porous ultra-light hard airgel with the lowest thermal conductivity between the plastic pad and the metal part of the valve lever button of the saxophone keyboard provides reliable thermal insulation of the pad from the metal parts of the saxophone. Such a gasket ensures reliable fastening of the cover to the metal part of the button, maintains the weight of the button within the values permissible for the timely and reliable return of the button by the spring of the valve lever to its original position after the cessation of pressing it with the fingertip, which ensures the required speed, high quality and accuracy of musical performance. works on the saxophone.

Brief description of the drawing.

The drawing of Fig. 1 schematically shows the buttons of the valve levers of the saxophone keyboard when the free ends of the levers with the buttons are in the upper position (A) and the button in section (B).

FIG. 1. Saxophone keyboard valve lever buttons 1, valve lever 2, button metal part 3, gasket 4 made of synthetic porous ultra-light hard airgel with the lowest thermal conductivity, plastic pad 5.

The device is used as follows.

Today, musicians do not perform musical works on saxophones with a high tempo and quality at temperatures below + 5 ° C, since they do not have "winter" saxophones, on the free ends of the valve levers of the keyboard of which there are buttons made of a material with a low thermal conductivity. Therefore, the buttons of modern saxophones do not prevent the intense intake of heat from the musician's fingers and their quick and deep cooling when playing music in the cold, in particular, when the air temperature is below + 5- + 15 ° С.

In this regard, in order to expand the range of applications, increase the efficiency, safety and accuracy of performing musical works in cold conditions, the musician chooses a saxophone made with insulated buttons of the keyboard valve levers that maintain the temperature at the fingertips when performing musical works in the cold, namely - at an ambient temperature below + 5- + 15 ° С. Moreover, a musician performs a piece of music on such a saxophone in cold conditions in the same way as in room temperature, namely, at a temperature of + 24- + 26 ° C.

After completing the performance of a piece of music in cold conditions on a saxophone with insulated keyboard valve levers, the musician disassembles the saxophone as usual, wipes it, folds it disassembled into a standard case, transports and stores in a case under normal conditions.

Thus, the proposed insulated button for the valve lever of the saxophone keyboard, intended for thermal insulation of the musician's fingers in cold conditions, expands the scope, increases the efficiency, safety and accuracy of use in cold conditions by placing a 0.5 -1.0 mm, made of synthetic porous ultra-light solid airgel with the lowest thermal conductivity.

Claims (1)

The insulated button of the valve lever of the saxophone keyboard, designed for thermal insulation of the musician's fingers when performing a piece of music in cold conditions, made in the form of a metal saucer with a rounded bottom and raised edges, filled to the top with plastic material of white or black color with a concave smooth and slippery outer surface, on which symbols can be engraved or printed, characterized in that between the cover and the metal part of the button over the entire area of their contact with each other, a pad 0.5-1.0 mm thick is firmly placed, made of synthetic porous ultra-light solid airgel with the lowest thermal conductivity ...

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