RU2696350C2 - Dynamic loudspeaker cooling system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to electrodynamic loudspeakers, namely, to means for reduction of heating of voice coil of loudspeaker. Motor of electrodynamic loudspeaker, including at least one permanent magnet and at least one magnetic field concentrator, for concentration of magnetic field created by permanent magnet, in a magnetic gap, and a voice coil consisting of a frame and winding, located in a magnetic gap, wherein the voice coil has at least one protruding element for heat removal, located on the inner and/or outer surface of the voice coil.

EFFECT: technical result is increase in speaker maximum long-term power.

24 cl, 13 dwg

Description

The invention relates to electrodynamic loudspeakers (speakers), and in particular to means for reducing the heating of a voice coil of a speaker.

The following technical solutions are known from the prior art.

A known cooling system for a speaker, consisting of a plate with a pole tip, an annular magnet, an annular top plate, a frame, a voice coil, a damper, conical paper, a dust cover, a gasket, a terminal and a flexible wire. The air in the part formed by the plate, the voice coil and the dust cap passes through the spiral groove by moving up and down the voice coil, and also passes through the through hole and is replaced by outside air (Japan No. S 6482898, 03/28/1989).

The disadvantage of the solution known from the above patent is that the heat exchange surface is not increased. The channels will provide air movement between the core and the coil. But not on the entire plane of the coil, but only on its part. The heat exchange surface is not increased, but only the air circulation between a part of the coil heat exchange surface and the core has improved. This can have a negligible effect in heat dissipation; radical changes are not worth the wait.

The closest analogue of the patented solution is a speaker cooling system whose magnetic system contains a core, a magnetic circuit, a power coil frame, a power coil winding, an annular gap, and grooves. The voice coil is located in the annular gap of the magnetic system and can move under the action of an alternating current flowing through it. The heat exchange surfaces in contact with the air in the gap contain grooves. The flow of air in the gap of the transducers of acoustic systems is formed due to a change in the volume of the internal cavity of the magnetic circuit by an oscillating power coil (RF patent No. 2131163, 05.27.1999).

The disadvantage of the closest analogue is that the heat transfer area of the voice coil is not increased in comparison with the standard design, the change in circulation efficiency is ambiguous. The increase in heat sink is ambiguous.

The technical problem solved by the invention is that when the speaker is operating in nominal and maximum power modes, heating of the voice coil occurs. Heating the voice coil above the maximum possible operating temperature is called overheating. Overheating of the voice coil with its subsequent failure is one of the most common breakdowns for speakers. There are two main types of ZK destruction: loss of strength of the glue of the winding of the voice coil (due to overheating) with subsequent sliding of the turns, and a breakdown of the insulation of the conductor (due to overheating), followed by interturn closure. The negative effects of heating, it is worth considering thermal compression - a decrease in speaker efficiency due to heating of the voice coil conductor (when heated, the conductor increases its resistance, which reduces the speaker's efficiency). In some cases, thermal compression can reduce sound pressure by more than 3 decibels, which is equivalent to a decrease in power by more than half. All this is due to strong heating of the voice coil. So, by reducing the heating of the voice coil, you can increase the efficiency at high power and increase the limit of "thermal strength" of the speaker. It is possible to reduce coil heating by improving the heat sink from it.

The problem is solved primarily by increasing the area of heat transfer and, secondly, by increasing the speed of air moving around the coil (improving the circulation of air around the coil).

The technical result of the claimed technical solution is to increase the ultimate long-term power supplied to the speaker by improving the heat sink from the coil during operation of the speaker, as well as increasing the efficiency of converting the electrical signal to sound when working at powers close to the nominal and higher than the nominal.

The specified technical result is ensured by the design of the motor of the electrodynamic loudspeaker. The motor of the electrodynamic loudspeaker includes a magnetic system and a voice coil.

The magnetic system consists of a permanent magnet or magnets that create a constant magnetic field, and a hub or concentrators (magnetic cores) that concentrate the magnetic field created by the permanent magnet or magnets in the magnetic gap or gaps. The magnetic system can have various designs, a classic design with an external arrangement of a magnet or magnets and a gap between the core (internal magnetic circuit) and the upper magnetic circuit, a design with an internal arrangement of a magnet and a gap between the core and an external magnetic circuit, a design with a magnetic gap formed between the core and magnet or magnets, a construction with two or more magnetic gaps formed between core or cores and magnetic cores.

The voice coil has a winding or coils located in the magnetic gap or gaps and a frame connecting the coil with a diffuser (the diffuser is not part of the electrodynamic speaker motor), in addition to the coil and frame, the voice coil has protruding cooling elements on the inner and outer surfaces that increase the area heat sink. Elements can be in the form of plates located at an angle of plates, perforated plates, curved plates, profile plates of needles or arches. Elements can be small in size, and a coil with such elements can freely move in a magnetic gap along the core axis. Elements may have dimensions that do not allow a voice coil with such elements to fit in the magnetic gap and for elements it is necessary to make slots in a magnetic concentrator, concentrators and / or magnets. The cooling elements located on the voice coil frame may be part of the frame and not be part of the voice coil frame, while the frame may be monolithic or composite. The cooling elements located on the winding of the voice coil can be made of a monolithic part or individual parts. Also, the cooling elements located on the surface of the winding can be connected to the frame or with cooling elements located on the other side of the winding, which will cover the windings and additionally fix the winding on the frame. The frame can be located on the inner surface of the winding, on the outer surface of the winding, or between the winding layers of the voice coil.

In this case, the magnetic system and slots can be made in such a way that during the operation of the electrodynamic loudspeaker, air circulates in the slots and the magnetic gap and cools the voice coil. You can also optionally install an air pump for cooling the voice coil with cooling elements and / or magnetic system.

There are the following types of heat exchange with the environment for the coil:

- heat transfer by radiation;

- heat transfer;

- convective heat transfer.

For any type of heat transfer, the heat transfer area is one of the factors affecting the heat transfer efficiency. The higher the area, the greater the heat transfer. Convective heat transfer contributes most to heat removal from the voice coil. To increase its efficiency, it is also necessary to increase the heat transfer area and / or the speed of moving air. To increase the heat transfer surface, it is necessary to increase the surface area of the voice coil, since winding the voice coil is the main source of heat. You can do this by executing a coil as a radiator (with protruding elements) or by installing an additional radiator or radiators on the voice coil. The radiator coil can have a different shape, but the main thing is that heat is removed directly from the winding of the voice coil. The cooling elements must be part of the winding, part of the frame or be installed directly on the frame or winding. This embodiment of the voice coil increases the heat exchange surface and contributes to a more efficient heat removal from the winding of the voice coil, into the air, in the part of the magnetic system and into the frame.

By increasing the heat sink from the coil, its heating is reduced in the framework of the speaker in the nominal and maximum mode, as well as an increase in the working power limit and a decrease in thermal compression. A product manufactured in accordance with the claimed technical solution works more reliably and efficiently when working in nominal and maximum operating conditions.

Next, the solution is illustrated by reference to the figures, which show the following.

FIG. 1.a - a general diagram of the dynamics in the context.

FIG. 1.b is a general diagram of a magnetic system of a speaker of a classical type, a sectional side view.

FIG. 1.c - a general diagram of the magnetic system of a speaker of a classical type from above.

FIG. 1.d is a general diagram of a speaker’s magnetic system with an internal arrangement of a magnet, a sectional side view.

FIG. 1. e - a general diagram of a speaker’s magnetic system with an internal arrangement of the magnet, top view.

FIG. 1.е - a general diagram of the speaker’s magnetic system with a magnetic gap between the magnets and the concentrator in a sectional side view.

FIG. 1. g - a top view of a general diagram of a speaker’s magnetic system with a magnetic gap between magnets and a hub.

FIG. 1.z - a general diagram of a magnetic system of a speaker with two magnetic gaps in a sectional side view.

FIG. 1.and - a general diagram of the magnetic system of the speaker with two magnetic gaps top view.

FIG. 2.a - a general diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system and a voice coil. Dimetry

FIG. 2.b is a general diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system and a voice coil. Section in dimetry.

FIG. 3.a is a diagram of the motor of an electrodynamic loudspeaker consisting of a classical type magnetic system and a voice coil with internal cooling elements. Dimetry

Fig.3b is a diagram of the motor of an electrodynamic loudspeaker consisting of a classical type magnetic system and a voice coil with internal cooling elements. Section in dimetry.

FIG. 4.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system and a voice coil with external cooling elements. Dimetry

FIG. 4.b is a diagram of the motor of an electrodynamic loudspeaker consisting of a classical type magnetic system and a voice coil with external cooling elements. Section in dimetry.

FIG. 5.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal and external cooling elements. Dimetry

FIG. 5.b is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal and external cooling elements. Section in dimetry.

FIG. 6.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with external small cooling elements. Section in dimetry.

FIG. 6.b is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with external small cooling elements. View from above.

FIG. 6.c - diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with external small cooling elements. View A from FIG. 6b (Scale 5: 1).

FIG. 7.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal small cooling elements. Section in dimetry.

FIG. 7.b is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal small cooling elements. View from above.

FIG. 7.c - diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with internal small cooling elements. View B from Fig 7.b (Scale 5: 1).

FIG. 8.a - diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with internal and external small cooling elements. Section in dimetry.

FIG. 8.b is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with internal and external small-sized cooling elements. View from above.

FIG. 8.c - diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with internal and external small cooling elements. View C from Fig 8.b (Scale 5: 1).

FIG. 9.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal and external, arched cooling elements of small size. Section in dimetry.

FIG. 9.b is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal and external, arched cooling elements of small size. View from above.

Fig. 9c is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located inside it with internal and external, arched cooling elements of small size. View C from Fig 9.b (Scale 5: 1).

FIG. 10.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with external, inclined small-sized cooling elements. Section in dimetry.

FIG. 10.b is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with external, inclined small-sized cooling elements. View from above.

FIG. 10.c - a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with external, inclined small-sized cooling elements. View C from Fig. 10b (Scale 5: 1).

FIG. 11.a is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with dual external and internal cooling elements. View from above.

FIG. 11.b is a diagram of the motor of an electrodynamic loudspeaker consisting of a classical type magnetic system with a voice coil located in it with dual external and internal cooling elements. View A from FIG 11.a (Scale 5: 1).

FIG. 11. c - diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with built-in external and internal cooling elements. View from above.

FIG. 11.d is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with built-in external and internal cooling elements. View A from FIG 11.c (Scale 5: 1).

FIG. 11.d is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with built-in internal elements and external cooling elements with five plates in a block. View from above.

FIG. 11.е - schematic of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with built-in internal elements and external cooling elements with five plates in a block. View A from Fig 11.e (Scale 5: 1).

FIG. 11.g - diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with built-in internal elements and external cooling elements with five plates in the block, as well as small cooling elements. View from above.

FIG. 11.h - circuit of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with built-in internal elements and external cooling elements with five plates in the block, as well as small cooling elements. View A from Fig 11.g (Scale 5: 1).

FIG. 11.i is a diagram of the motor of an electrodynamic loudspeaker consisting of a classical type magnetic system with a voice coil located in it with arched internal and external cooling elements. View from above.

FIG. 11.k is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with arched internal and external cooling elements. View A from FIG 11.i (Scale 5: 1).

FIG. 11.l is a diagram of the motor of an electrodynamic loudspeaker, consisting of a classical type magnetic system with a voice coil located in it with four external and internal cooling elements. View from above.

FIG. 11.m is a diagram of the motor of an electrodynamic loudspeaker consisting of a classical type magnetic system with a voice coil located in it with four external and internal cooling elements. View A from FIG 11.l (Scale 5: 1).

FIG. 12.a - The circuit of the voice coil with needle cooling elements. Isometry.

FIG. 12.b - Scheme of a voice coil with needle cooling elements. Isometry

FIG. 12.c - Scheme of a voice coil with needle-shaped cooling elements. Isometry.

FIG. 12.d - Scheme of a voice coil with plate cooling elements. Isometry.

FIG. 12.d - Scheme of a voice coil with plate cooling elements. Isometry.

FIG. 12.е - Scheme of a voice coil with plate cooling elements. Isometry

FIG. 12.g - Scheme of a voice coil with plate cooling elements. Isometry

FIG. 12.z - Scheme of a voice coil with plate cooling elements. Isometry.

FIG. 13.a - Diagram of a monolithic frame-radiator. Isometry.

FIG. 13.b - Scheme of the composite frame-radiator. Isometry

FIG. 13.c - Diagram of a composite radiator frame. Isometry.

FIG. 13.d - Scheme of a voice coil with a radiator frame, fastened to each other by cooling elements. Isometry

FIG. 13.d - Scheme of a voice coil with a frame located between the turns of the winding of the voice coil. Isometry

Fig.13.e is a diagram of a voice coil with a frame located on the outer part of the winding of the voice coil. Isometry.

In FIG. 1a, a general diagram of an electrodynamic loudspeaker (speaker) with a classical type magnetic system is given. The speaker consists of a frame (16), a centering washer (17), terminals (18), flexible supply wires (19), a diffuser (20), a dust cap (21), a suspension (22), a voice coil including winding (5) and the frame (6), and the magnetic system. The magnetic system consists of a permanent magnet or magnets (3), a lower magnetic concentrator including a lower magnetic circuit (1) and a core (2), and an upper magnetic concentrator (upper magnetic circuit) (4). The winding of the voice coil is located in the magnetic gap (9), with a constant magnetic field and fastened through the frame with a diffuser. The magnetic system and the coil form the motor of the speaker, it drives the diffuser, and the diffuser creates a sound wave.

In FIG. 1b, FIG. Figure 1c shows a diagram of a classical-type magnetic system (with an external arrangement of a permanent magnet or magnets). A classical type magnetic system consists of a permanent magnet or magnets (3), a lower magnetic concentrator including a lower magnetic circuit (1) and a core (2) (the lower concentrator can be made as a monolithic part), and an upper magnetic concentrator (4) (upper magnetic circuit) . Magnetic cores (1, 4) and core (2) are used to concentrate the magnetic field of a permanent magnet (3) in the magnetic gap (9). The magnetic gap (9) is located between the core (2) and the upper magnetic circuit (4).

In FIG. 1g, fig 1.d The diagram of the magnetic system with the internal arrangement of the magnet is shown. In this system, the magnet is located within the inner diameter of the voice coil. A magnetic system with an internal magnet arrangement consists of a magnet (3), an internal magnetic concentrator (2) (core) and an external magnetic concentrator (13) (external magnetic circuit). The magnetic gap is located between the core (12) and the external magnetic circuit (13).

In FIG. 1e, fig 1.zh. A diagram of a magnetic system with magnets forming one of the poles of the magnetic gap is presented. The magnetic system consists of a magnet or magnets (3), and a magnetic concentrator, including a core (2), a lower magnetic circuit (1) and external magnetic circuits (13). The magnetic gap is located between the magnets (3) and the core (2). External magnetic circuits (13) can be made in one piece. The core (2) and the lower magnetic circuit (1) can be made in one piece. The core (2), the lower magnetic circuit (1) and the external magnetic circuit (13) can be made in one piece.

In FIG. 1h, fig 1.i. A diagram of a magnetic system with two magnetic gaps is given. The magnetic system consists of a lower magnetic concentrator (1) (lower magnetic circuit), an upper magnetic concentrator (4) (upper magnetic circuit), a permanent magnet or magnets (3), a core (2) and a flange made of a material with low magnetic permeability (15), connecting the core to the lower magnetic circuit. This design has 2 magnetic gaps between the core (2) and the lower magnetic circuit (1), and between the core (2) and the upper magnetic circuit (4). The voice coil should also be divided into two windings in height and located in both magnetic gaps.

In FIG. 2.a and 2.b shows a diagram of a standard embodiment of a speaker motor (classical type magnetic system + voice coil), which was modified in the claimed invention. The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of a winding (5) and a frame (6). The winding of the voice coil (5) is placed in the magnetic gap (9) and can freely move along the axis of the core (2).

In FIG. Figures 3.a and 3.b show a diagram of the motor of an electrodynamic loudspeaker, including a classical type magnetic system and a coil with internal protruding cooling elements (7) in the form of plates. The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of a winding (5) and a composite frame (6) combined with internal cooling elements (7). The core (2) has slots (10) for free movement of the voice coil with internal cooling elements (7) along the axis of the core (2).

In FIG. Figures 4.a and 4.b show a diagram of the motor of an electrodynamic loudspeaker, including a classical type magnetic system and a coil with external, protruding cooling elements (8) in the form of plates. The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6) and external cooling elements (8). The upper magnetic circuit (4) has slots (11) for free movement of the voice coil with external cooling elements (8) along the core axis (2).

In FIG. Figures 5.a and 5.b show a diagram of the motor of an electrodynamic loudspeaker, which includes a classical type magnetic system and a coil with internal (7) and external (8) protruding cooling elements in the form of plates. The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6) of internal cooling elements (7) and external cooling elements (8). The core (2) has slots (10), the upper magnetic circuit (4) has slots (11) for free movement of the voice coil with internal (7) and external (8) cooling elements along the axis of the core (2).

In FIG. 6.a, 6.b and 6.c. A diagram of the motor of an electrodynamic loudspeaker is presented, which includes a classical magnetic system and a coil with external protruding cooling elements in the form of small plates (8) located in the magnetic gap (9). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6) and external cooling elements (8). External cooling elements (8) have dimensions that allow the voice coil to move freely in the magnetic gap (9) along the core axis (2).

In FIG. 7.a, 7.b and 7.c. A diagram of the motor of an electrodynamic loudspeaker is presented, which includes a classical type magnetic system and a coil with internal protruding cooling elements in the form of small plates (7) located in the magnetic gap (9). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6) and internal cooling elements (7). The internal cooling elements (7) are sized to allow the voice coil to move freely in the magnetic gap (9) along the core axis (2).

In FIG. 8.a, 8.b and 8.c shows a diagram of the motor of an electrodynamic loudspeaker, including a classical type magnetic system and a coil with internal (7) and external (8) protruding cooling elements in the form of small-sized plates located in the magnetic gap (9). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of a winding (5), a frame (6) and internal cooling elements (7) and external cooling elements (8). The internal cooling elements (7) and the external cooling elements (8) have dimensions that allow the voice coil to move freely in the magnetic gap (9) along the core axis (2).

In FIG. 9.a, 9.b and 9.c shows a diagram of the motor of an electrodynamic loudspeaker that includes a classical type magnetic system and a coil with internal (7) and external (8) protruding cooling elements in the form of small arches located in the magnetic gap (9). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of a winding (5), a frame (6) and internal cooling elements (7) and external cooling elements (8). The internal cooling elements (7) and the external cooling elements (8) have dimensions that allow the voice coil to move freely in the magnetic gap (9) along the core axis (2).

In FIG. 10.a, 10.b and 10.c shows a diagram of the motor of an electrodynamic loudspeaker that includes a classical type magnetic system and a coil with external protruding cooling elements in the form of inclined plates of small size (8) located in the magnetic gap (9). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6) and external cooling elements (8). External cooling elements (8) have dimensions allowing the voice coil to move freely in the magnetic gap (9) along the core axis.

In FIG. 11.a and 11.b show the arrangement of cooling elements (7), (8) on the voice coil, with two parallel plates on each side of the winding of the voice coil, located in the slots of the core (10) and the slots of the upper magnetic circuit (11). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6), internal cooling elements (7) and external cooling elements (8).

In FIG. 11.c and 11.d, the arrangement of cooling elements (7), (8) on the coil is shown, with three parallel plates on each side of the voice coil located in the core slots (10) and the top magnetic core slots (11). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6), internal cooling elements (7) and external cooling elements (8).

On Fig.11.d and 11.e shows the arrangement of cooling elements on the coil, with three angled plates (7) inside the voice coil located in the core slots (10) and with five angled plates (8) outside the sound coils located in the slots of the upper magnetic circuit (11). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6), internal cooling elements (7) and external cooling elements (8).

In FIG. 11.g and 11.z the arrangement of cooling elements on the coil is shown, with three angled plates (7) inside the voice coil located in the core slots (10) and with five angled plates (8) outside the voice coil located in the slots of the upper magnetic circuit (11), but what about the small-sized elements (7) (8) located inside and outside the voice coil in the magnetic gap (9). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6), internal cooling elements (7) and external cooling elements (8).

In FIG. 11.i and 11.k the arrangement of cooling elements on the coil is shown, with internal (7) and external (8) arched cooling elements located in the core slots (10) and the top magnetic core slots (11). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6), internal cooling elements (7) and external cooling elements (8).

In FIG. 11.l and 11.m the arrangement of cooling elements on the coil is shown, with internal (7) and external (8) cooling elements made of bent sheet metal. Four cooling elements (7) on the inside of the coil in the core slots (10) and four cooling elements (8) on the outside of the coil in the slots of the upper magnetic circuit (11). The magnetic system consists of a lower magnetic circuit (1), a core (2), an upper magnetic circuit (4), permanent magnets (3). The voice coil consists of winding (5), frame (6), internal cooling elements (7) and external cooling elements (8).

In FIG. 12.a is a diagram of a voice coil with cooling elements made in the form of round needles arranged in a row in one element. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.b is a diagram of a voice coil with cooling elements made in the form of round needles arranged in two rows in one element. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.c shows a diagram of a voice coil with cooling elements made in the form of round needles arranged in a checkerboard pattern in 3 rows in one element. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.d is a diagram of a voice coil with cooling elements made in the form of flat plates located in two rows in one element. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.d is a diagram of a voice coil with cooling elements made in the form of curved plates. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.е shows a diagram of a voice coil with cooling elements made in the form of inclined plates arranged in a row. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.g is a diagram of a voice coil with cooling elements made in the form of perforated plates. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 12.z is a diagram of a voice coil with cooling elements made in the form of plates with a curvilinear generatrix. The voice coil consists of a frame (6), a winding (5) and external cooling elements (8).

In FIG. 13.a shows a diagram of a monolithic frame of a voice coil. The radiator frame combines the frame (6) and the protruding internal elements (7).

In FIG. 13.b shows a diagram of the composite frame of the voice coil in the folded state (in the voice coil the frame is in the folded state). The radiator frame combines the frame (6) and the protruding internal elements (7).

In FIG. 13.c is a diagram of the composite frame of the voice coil in the unfolded state (for clarity). The radiator frame combines the frame (6) and the protruding internal elements (7).

In FIG. 13.d shows the circuit of the voice coil external elements (8) and the frame (6) which are closed in a circuit around the winding (5) to prevent sliding of the windings of the voice coil. The coil consists of a frame (6), a winding (5), internal cooling elements (7) and external cooling elements (8).

In FIG. 13.e shows a diagram of a voice coil frame (6) which is located between the winding layers (5) of the voice coil. The coil consists of a frame (6), a winding (5), internal cooling elements (7) and external cooling elements (8).

In FIG. 13.е shows a diagram of a voice coil frame (6) which is located on the outer surface of the winding (5) of the voice coil. The coil consists of a frame (6), a winding (5), internal cooling elements (7) and external cooling elements (8).

According to the patented solution, the coil is made in the form of a radiator with protruding cooling elements that increase the heat sink area, which can be performed on the outer surface of the winding of the voice coil, on the inner surface of the winding or on both sides.

If the heat sink elements are small, they can be in the magnetic gap, between the voice coil and the surfaces forming the magnetic gap.

If the heat sink elements are large and do not fit in the magnetic gap, it is necessary to make slots or holes in the magnetic concentrators (core, upper magnetic circuit, internal magnetic circuit, external magnetic circuit) or magnets to freely move the heat sink elements (fins, plates, arches in them) or needles).

All elements form a radiator that increases the surface of the heat sink. The radiator can be made both integral and composite. The radiator can be combined with the voice coil frame. The coil frame and radiator can be produced by drawing, casting, and the frame and radiator can be bent or stamped from sheet metal. The fins or needles of the radiator can be of various shapes. For example, flat plates, inclined plates, profiled plates, curved plates, perforated plates, arched-type elements, round needles, elliptical needles. The plates can be located both radially and parallel to the radius and at an angle to the radius, can be combined several into one element. The plates and needles can be arranged in rows or staggered.

A composite metal radiator, when isolating the parts from each other, will slow down the winding in the magnetic gap less than a solid metal frame or radiator made of one part does, since eddy currents form in the frame or radiator, which inhibit the frame or radiator when moving in a magnetic field. Dividing the frame or radiator into separate, isolated parts, we reduce the eddy currents and reduce the resistance to movement in a magnetic field. At the same time, a one-piece radiator can be more technological.

It is also possible to make the magnetic system, the frame and the mobile system so that when moving the mobile system up and down, the air located in the under-cap space (inside the voice coil, between the cap and the core) circulates between the core and the voice coil and in the channels (slots) core, and air from under the centering washer, circulated between the voice coil and the upper magnetic circuit and in the channels (slots) of the upper magnetic circuit. Thus, the speed of air passing by the radiator of the voice coil increases and the heat sink to the environment and to the magnetic system with the speaker frame is additionally increased.

The second option to increase the air velocity around the radiator is to force the air to circulate in the magnetic gap and the channels of the magnetic system by force (using an air pump). Which will also lead to an increase in heat dissipation from the voice coil.

Especially effective heat will be removed if the thermal conductivity of the adhesive in the winding is high.

In addition to increasing the heat removal from the coil, the radiator can be made so that it covers the winding in a circle and prevents the winding from sliding down. Since we have cooling elements on both sides of the winding, we only need to connect them into a single circuit.

Also, the ribs or plates on the frame are stiffening ribs and additionally increase the stiffness of the voice coil frame, which also increases the reliability of the product.

Embodiments of the voice coil in the form of a radiator are shown in FIG. 3-13.

The system works as follows.

When an electric current flows through a conductor (winding a voice coil) located in a constant magnetic field concentrated in the magnetic gap, a force is generated in the voice coil that makes the coil move in the gap together with a diffuser mounted on the voice coil frame. The diffuser moving back and forth creates a sound wave. To bring the electrical signal to the voice coil, flexible lead wires are used to supply electricity from the terminals to the terminals of the voice coil. At the same time, heat is generated in the winding of the voice coil, which heats the winding of the voice coil and can overheat it if the rated power is exceeded. Due to the implementation of the coil with an increased surface area, the heat transfer area increases, which allows you to transfer more internal energy to the air and surrounding bodies (magnetic concentrators, magnets, frame) and thereby reduce the temperature of the coil during operation. That, in turn, will increase the efficiency of processing electric energy into sound at nominal and maximum operating modes of the speaker, increase the reliability of the product and its nominal and maximum power, and, consequently, increase the sound pressure reproduced by the speaker.

Claims (24)

1. The motor of the electrodynamic loudspeaker, comprising at least one permanent magnet and at least one magnetic field concentrator, for concentrating the magnetic field generated by the permanent magnet in the magnetic gap, and a voice coil consisting of a frame and a winding located in the magnetic gap, characterized in that the voice coil has at least one protruding element for heat removal located on the inner and / or outer surface of the voice coil. 2. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements have dimensions that do not impede the movement of the coil in the magnetic gap. 3. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements are such that for free movement of the voice coil with protruding elements along the axis of the core, slots are made in at least one of the concentrators and / or magnets. 4. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that at least one permanent magnet is located within the inner diameter of the voice coil. 5. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that at least one permanent magnet is located outside the outer diameter of the voice coil. 6. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the magnetic system has at least two magnetic gaps. 7. The motor of the electrodynamic speaker according to claim 1, characterized in that the magnetic gap is formed between two concentrators of the magnetic field. 8. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the magnetic gap is formed between the magnet or magnets and the hub and / or one of the hubs. 9. The motor of the electrodynamic speaker according to claim 1, characterized in that the design of the slots in the hubs and / or magnets allows air to circulate in them during operation of the electrodynamic speaker, thereby cooling the winding of the voice coil. 10. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that it includes an additional air pump that circulates air cooling the voice coil with cooling elements and / or the magnetic system. 11. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements are in the form of plates. 12. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements have the shape of angled plates. 13. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements are in the form of perforated plates. 14. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements are in the form of needles. 15. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements are in the form of arches. 16. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements located on the frame of the voice coil are part of the frame, which is made monolithic. 17. The motor of the electrodynamic speaker according to claim 1, characterized in that the protruding elements located on the frame of the voice coil are part of the frame, which is made integral. 18. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements located on the voice coil frame are not a single part with the voice coil frame. 19. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements located on the surface of the winding of the voice coil are made as a single part. 20. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements located on the surface of the winding of the voice coil are made in separate parts. 21. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the protruding elements located on the outer surface of the voice coil are connected to the frame or to the internal elements, which further fixes the winding with the frame. 22. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the frame is located inside the winding of the voice coil. 23. The motor of the electrodynamic speaker according to claim 1, characterized in that the frame is located between the windings of the voice coil. 24. The motor of the electrodynamic loudspeaker according to claim 1, characterized in that the frame is located outside the winding of the voice coil.

Images