KR102819203B1 - Speaker with Coil Thin Flim Pattern - Google Patents

Abstract

A speaker without thermal deformation according to the present invention is characterized in that the temperature T_low of a voice coil (50), a coil thin film pattern (60) joined to the voice coil (50), a diaphragm (70) mounted on the coil thin film pattern (60), and the diaphragm (70) joined to the coil thin film pattern (60) is lower than the temperature T_high at which the voice coil (50) and the coil thin film pattern (60) are joined.

Description

Speaker with Coil Thin Flim Pattern

The present invention relates to a speaker having a coil thin film pattern formed thereon.

In general, a speaker is an acoustic device that generates sound waves by converting an electrical signal into the vibration of a diaphragm and generating a low-pass wave in the air. In other words, a speaker is a conversion device that converts electrical energy into acoustic energy, and is largely composed of a vibration system, a support system, and a magnetic system. These speakers can be classified into several types depending on the location of the diaphragm, which is a vibration system component, the shape of the diaphragm, and the principle and method of converting the electric signal into a sound wave. In particular, speakers used in display devices such as TVs are radiation-type speakers in which the diaphragm is placed directly in the air. They generally utilize the principle that when an audio signal current is passed through a coil located in a magnetic field formed by a permanent magnet, a mechanical force is applied to the coil according to the strength of the current to cause movement.

Recently, there has been a problem in the speaker manufacturing process where the heat-sensitive diaphragm deteriorates or deforms, resulting in deteriorated speaker performance or durability.

Korean Patent No. 10-1607529

The present invention aims to solve these problems by adding a coil thin film pattern so as not to directly connect the voice coil and the diaphragm, thereby making it possible to manufacture a speaker without thermal deformation during the manufacturing process.

According to one embodiment of the present invention, a speaker without thermal deformation comprises: a voice coil (50); a coil thin film pattern (60) bonded to the voice coil (50); a diaphragm (70) mounted on the coil thin film pattern (60); a T_low temperature, which is a temperature of the diaphragm (70) bonded to the coil thin film pattern (60), is lower than a T_high temperature, which is a temperature at which the voice coil (50) and the coil thin film pattern (60) are bonded, so that the T_low temperature and the T_low temperature are T_high > T_low.

Additionally, the coil thin film pattern (60) is arranged parallel to the inner peripheral surface of the diaphragm (70).

In addition, the above coil thin film pattern (60) has a shape of a circumferential surface with a certain width.

In addition, in the coil thin film pattern (60), a conductive part for conducting the voice coil (50) protrudes toward the center from a circumferential surface of a certain width to form A and B spots.

Additionally, electrodes A and B are formed by extending radially from the above spots A and B.

Additionally, the electrodes A and B are bonded to the lower surface of the diaphragm (70) at the T_low temperature.

In addition, the electrodes A and B are bonded so as to make surface contact along the curved or uneven shape of the diaphragm.

Another thermally deformation-free speaker according to one embodiment of the present invention comprises: a voice coil (50); a coil thin film pattern (60) joined to the voice coil (50); a diaphragm (70) mounted on the coil thin film pattern (60); and an inner peripheral surface of the diaphragm (70) joined to the coil thin film pattern (60) may be parallel to each other, and the voice coil (50) joined to the coil thin film pattern (60) may be orthogonal to each other.

Another method for manufacturing a speaker without thermal deformation according to an embodiment of the present invention comprises the steps of: joining a coil thin film pattern (60) and a voice coil (50) in the shape of a circumferential surface with a predetermined width at a temperature of T_high so that they are perpendicular to each other; and bringing an inner circumferential surface of a diaphragm (70) on a predetermined width of the coil thin film pattern (60) into surface contact with each other so that the inner circumferential surface thereof is parallel to each other at a temperature of T_low; and may be characterized in that T_high > T_low.

Figure 1 is an exploded view of a speaker according to the present invention.
Figure 2 is a cross-sectional view of a speaker according to the present invention cut along a coil thin film pattern (60).
Figure 3 shows a structure in which a coil thin film pattern (60) of the present invention is joined to a voice coil (50).
Figure 4 is the lower shape of the diaphragm.
Figure 5 shows a structure in which the electrode portion (62), including the electrode interview portion (64) and the electrode terminal portion (66), forms a certain angle.
Figure 6 is a shape comparison between the electrode section and the diaphragm cross section.

Figure 1 is an exploded view of a speaker according to the present invention. The speaker frame (10) has a circular container shape, and a circular wall is formed along the circumference at a certain height, and serves as a lower casing in which components described later are accommodated inside. A portion of the circular wall of the speaker frame (10) has no circular wall, and a PCB is positioned on the circumference. The PCB plays a role in controlling the voice coil.

The speaker frame is hollow with a certain radius from the center, and a yoke (20) is formed in the hollow portion of the circular plate. The yoke (20) forms a concave receiving portion and is inserted into the hollow portion formed in the center of the speaker frame to be formed integrally.

A magnet (30) is positioned on the yoke (20), and is mounted on the yoke (20) in the shape of a disc with a certain thickness, and the outer diameter of the magnet (30) is smaller than the inner diameter of the yoke (20). A circular plate (40) is positioned on top of the magnet (30). The diameter of the circular plate and the diameter of the magnet are the same. Therefore, the magnet (30) is positioned inside the yoke (20), and the circular plate (40) is positioned on top of the magnet.

A voice coil (50) is formed along the circumference of a circular plate (40). A coil thin film pattern (60) is bonded to the upper portion of the voice coil of the present invention. The coil thin film pattern (60) is also attached to a diaphragm (70), and is integrally bonded to the lower surface of the diaphragm along the cross-sectional shape of the diaphragm (70). The temperature at which the coil thin film pattern (60) is bonded to the upper portion of the voice coil is, for example, a thermal fusion temperature of several hundred degrees (hereinafter, T_high), and the temperature at which the coil thin film pattern (60) is also bonded to the diaphragm (70) is, for example, a thermal fusion temperature of 100 degrees or less (hereinafter, T_low). That is, the bonding of the coil thin film pattern (60) and the voice coil (50) is performed in a T_high temperature range, and the bonding of the coil thin film pattern (60) and the diaphragm (70) is performed in a T_low temperature range. T_high and T_low are related to the material of the diaphragm, and the coil thin film pattern (60) and the diaphragm (70) are bonded in the T_low temperature range where the material of the diaphragm is not affected by the bonding temperature, and at the T_high temperature where the material of the diaphragm is affected by the bonding temperature, the voice coil (50) avoids direct bonding with the diaphragm (70), and the coil thin film pattern (60) and the voice coil (50) are bonded in the T_high temperature range, and the coil thin film pattern (60) and the diaphragm (70) are bonded in the T_low temperature range. The electrode terminal end portion (66) of the coil thin film pattern (60) described later is also bonded in the T_low temperature range.

The coil thin film pattern (60) is formed in the shape of two half rings of electrodes A and B, and each electrode section (62) is additionally formed to be electrically connected to the voice coil and to an external power source, and is attached to the lower surface of the diaphragm and extended to be electrically connected to the PCB of the speaker frame (10). A dust cap (80) is formed in the center of the diaphragm (70), and the dust cap (80) is a center diaphragm that can be seated on the inner circumferential surface formed along the hollow portion of the diaphragm (70).

FIG. 2 is a cross-sectional view of a speaker according to the present invention cut along a coil film pattern (60). A speaker frame (10) in the shape of a circular container is divided into a lower part of the speaker frame that accommodates a yoke and an upper part of the speaker frame that supports a diaphragm. The yoke mounted on the lower part of the speaker frame is in the shape of a circular container and accommodates a magnet (30) and a circular plate (40). The circular plate (40) supports the up-and-down movement of an electromagnet by a voice coil with respect to the magnet (30). A voice coil (50) wound along the outer circumference of the circular plate (40) becomes an electromagnet by a PCB, and its relative movement with respect to the magnet (30) is controlled. The magnet (30), the circular plate (40), and the voice coil (50) within the yoke all have clearance from the inner circumference of the yoke. This is so that the voice coil (50) can move up and down, and the magnet is attached or fixed so as to be mounted within the yoke.

A coil thin film pattern (60) is attached to the upper end of the voice coil (50) so as to be parallel to the upper surface of the circular plate. The coil thin film pattern (60) is formed by electrodes A and B, and is connected to the speaker frame through an electrode portion (62). It is connected to a position where the upper and lower parts of the speaker frame are fastened, is inserted into a gap between the upper and lower parts of the speaker frame, and is fixed by the engagement of the upper and lower parts of the speaker frame, and is electrically conductive to the PCB by a conductive means connecting the upper and lower parts of the speaker frame. The conductive means may be an electrically conductive structure or part. The electrode portions (62) from the electrodes A and B may be attached and supported to the lower surface of the diaphragm, or may be attached only to the semi-circular electrodes A and B. The diaphragm (70) is a radially elastic structure with up and down hills and valleys formed therein so as to be able to move up and down according to the movement of the voice coil (50), and the electrodes A and B may be joined along the radially elastic structure of the diaphragm. Meanwhile, a dust cap is located in the hollow part of the diaphragm.

Fig. 3 is a structure in which electrodes A and B, which are semi-circular in shape, of the coil thin film pattern (60) of the present invention are each bonded to the voice coil (50). This is a structure for protecting the diaphragm during internal soldering of the diaphragm. In the past, when the bonding (soldering) work was performed on the diaphragm, the diaphragm could melt or become deformed. In the structure in which the diaphragm cavity is formed, the voice coil (50) and the coil thin film pattern (60) are bonded, and then the diaphragm is covered and bonded as in the present invention, the lower surface of the diaphragm can be supported by the radial width of the coil thin film pattern, and the larger the radial width of the coil thin film pattern, the more stable the diaphragm can be supported. Fig. 3(a) is an upper structure in which a diaphragm and a dust cover are covered on a speaker frame. The coil thin film pattern (60) is not visible because it is covered by the dust cover. Fig. 3(b) is a lower structure of the diaphragm, and the electrode terminal end portion (66) is attached to the lower surface of the diaphragm. In Fig. 3(a), the electrodes A and B may be installed so as to be joined to the upper surface of the diaphragm. The coil thin film pattern (60) is formed in a horizontal direction perpendicular to the voice coil (50) so as to support a portion of the hollow portion of the diaphragm along the circumference of the voice coil (50), and in a direction parallel to a portion of the hollow portion of the circular plate or diaphragm so as to stably support the diaphragm, conduct current with the voice coil, and conduct current with an external power source, thereby forming an electrode portion (62).

Fig. 4 is a bottom shape of a diaphragm, and Fig. 4(a) shows that a coil thin film pattern (60) is bonded to be in surface contact with the lower surface of the diaphragm (70) according to the curved or uneven shape. A dust cap (80) is positioned on the opposite side. The coil thin film pattern (60) can be attached in surface contact along the diaphragm (70) up to the electrode terminal end (66), which is the end of the coil thin film pattern (60) for energizing the PCB.

Fig. 4(b) shows that the coil thin film pattern (60) is formed at 180 degrees to conduct current with the voice coil, and has an overall half ring shape with a certain thickness. An electrode contact portion (64) for securing a surface contact area with the electrode portion (62) and an electrode terminal portion (66) securing a certain area for connection to an external power source are additionally formed in the coil thin film pattern. The electrode contact portion (64) secures an axial area from the coil thin film pattern (60) in a half ring shape toward the center of the diaphragm, thereby sufficiently securing contact with the conducting portion by vibration. Likewise, the electrode terminal portion (66) can secure a sufficient contact area with a shape that is larger than the width of the electrode portion (62).

The electrode portion (62), including the electrode contact portion (64) and the electrode terminal portion (66), may be arranged parallel to each other from the electrodes A and B of the semi-circular coil thin film pattern (60), or may be arranged in an even number for each electrode (+/-) to form a certain angle from the center of the diaphragm.

Fig. 4(c) shows that the cross-sectional thickness of the diaphragm (70) to which the electrode portion (62) of the coil thin film pattern (60) is attached is greater than the cross-sectional thickness of the diaphragm without the coil thin film pattern (60). If this is further enlarged, the cross-section of the coil thin film pattern (60) layer and the diaphragm (70) can be distinguished. At this time, the electrode contact portion (64) does not directly contact the diaphragm and is located on the inner side of the coil thin film pattern (60), and the electrode end portion (66) is located on the edge that fixes the diaphragm.

FIGS. 5(a) and (b) show structures in which the electrode portion (62), including the electrode contact portion (64) and the electrode terminal portion (66), form 180 degrees and 90 degrees to each other. In FIG. 5(a), the first electrode contact portion (64a), the first electrode portion (62a), and the first electrode terminal portion (66a) form 180 degrees with the second electrode contact portion (64b), the second electrode portion (62b), and the second electrode terminal portion (66b).

In addition, in Fig. 5(b), the third electrode interview portion (64c), the third electrode portion (62c), and the third electrode terminal portion (66c) form a 90 degree angle with each other, including the fourth electrode interview portion (64d), the fourth electrode portion (62d), and the fourth electrode terminal portion (66d).

Meanwhile, when connecting the electrode portion from the electrode contact portion to the electrode terminal portion, the electrode contact portion is fixed so that it comes into contact with the coil thin film pattern (60) and the electrode terminal portion comes into contact with the edge of the diaphragm. On the other hand, the electrode portions (62a, 62b, 62c, 62d) are spaced apart from each other so as not to come into contact with the diaphragm, thereby minimizing the influence of the electrode portions on each other regarding the movement of the diaphragm.

In addition, when the semi-circular coil film pattern in direct contact with the voice coil is stretched in the ground direction as shown in Fig. 5 according to the movement of the voice coil, the electrode parts (62a, 62b, 62c, 62d) are linked to the movement at each of the four points.

Fig. 6 is a shape comparison between the electrode section and the diaphragm section. Fig. 6(a) shows that the shape of the electrode section (62a, 62b, 62c, 62d) is a shape that is integrated with or in contact with the diaphragm, and the electrode section follows the movement of the diaphragm.

Fig. 6(b) shows a diaphragm having a predetermined distance from the diaphragm, and the shape of the electrode portion (62a, 62b) forms a shape similar to the shape of the mountain and valley (72a, 72b) of the diaphragm. The electrode portion, except for the electrode contact portion and the electrode end portion, is spaced apart from the diaphragm at a predetermined distance. When the diaphragm moves up and down according to the coil film pattern by the voice coil, the electrode contact portion moves in conjunction with the coil film pattern, and the electrode end portion is fixed to the edge of the diaphragm, so that the electrode portion does not follow the movement of the diaphragm (70) to form the same movement, except for two points, but can be free from the up and down movement of the diaphragm, so that the movement of the diaphragm is free from the influence of the electrode portion. In addition, the electrode portion includes a metal component and forms a cross-sectional shape similar to the cross-section of the diaphragm, thereby forming an elastic restoring force proportional to the up-and-down movement of the diaphragm, and since the electrode portions are arranged at equal angles, such as 90 degrees or 180 degrees, the elastic restoring force can be formed at equal intervals.

The present invention is to prevent a problem in which a diaphragm may melt or deform due to causes such as welding heat during the process of joining a voice coil (50) and a diaphragm (70), and a coil thin film pattern (60) that is in surface contact with an inner surface formed along the hollow portion of a diaphragm in parallel with the voice coil (50) is joined to the voice coil (50). That is, the coil thin film pattern (60) and the voice coil (50) are joined, and the diaphragm is placed on the coil thin film pattern (60), so that heat during the process of joining the coil thin film pattern (60) and the voice coil (50) is not transferred to the diaphragm.

Meanwhile, the coil thin film pattern (60) and the voice coil (50) are not directly connected to each other but are merely joined by thermal fusion. In order to connect to each other, a conductive part for connecting to the voice coil (50) must be provided at a spot on the coil thin film pattern (60). The coil thin film pattern (60) is structured to be divided into two along electrodes A and B.

Claims (12)

delete delete delete delete delete delete delete delete For the speaker,
Voice coil (50);
A coil thin film pattern (60) connected to the above voice coil (50);
A diaphragm (70) mounted on the above coil thin film pattern (60);
The above coil thin film pattern (60) is arranged parallel to the inner surface of the diaphragm (70),
The above coil thin film pattern (60) has a semi-circular shape with a certain width.
In the above coil thin film pattern (60), an electrode contact portion (64) is formed by protruding toward the center from a circumferential surface of a certain width to conduct current to the voice coil (50).
An electrode portion (62) is formed by extending radially from the above electrode interview portion,
A speaker having a coil thin film pattern formed thereon, characterized in that the diaphragm includes a curved or uneven shape, and the electrode portion has a cross-section similar to the curved or uneven shape of the diaphragm, but is positioned at a certain distance from the diaphragm.
delete In Article 9,
A speaker having a coil thin film pattern formed thereon, characterized in that the electrode portions are 180 degrees apart from each other for connection to an external power source.
In Article 9,
A speaker having a coil thin film pattern formed thereon, characterized in that the electrode portions are at 90 degrees to each other for connection to an external power source.

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