KR102288973B1 - Geneva Gear Structure based Sound Insulation Device - Google Patents

Abstract

The present invention relates to a Geneva gear structure-based sound insulation device capable of protecting workers' hearing. More specifically, the Geneva gear structure-based sound insulation device comprises: a main body part having a receiving groove of a concave shape formed on one side and including an insertion part of a hollow cylindrical shape formed on the other side so that at least a part can be inserted into a user's external auditory meatus; a disc accommodated in the receiving groove and formed on the basis of a Geneva gear structure including one or more sound insulating materials; a cap part rotating the disc so that any sound insulating material located in a straight line with the central axis of the insertion part can be replaced with another sound insulating material; and a flange bearing positioned between the disk and the cap part in the receiving groove.

Description

Geneva Gear Structure based Sound Insulation Device

The present invention relates to a Geneva gear structure-based sound insulation device, and more specifically, Geneva, which can block external sounds by replacing any sound insulation material with another sound insulation material using a disk having a Geneva gear structure and a driving pin inserted into one side of a dial. It relates to a sound insulation device based on a gear structure.

At home and abroad, there are restrictions on the time workers are exposed to noise at industrial sites. In Korea, noise exposure time is limited to less than 8 hours at a maximum of 90 dB, but experts say that there is a high risk of noise-induced hearing loss if workers continuously hear noises of 85 dB or higher in an industrial setting.

Currently, industry provides earplugs to protect workers, but most of the earplugs provided are disposable earplugs or low-end earplugs that can only block noise.

Earplugs block the entrance from the pinna to the inside of the ear with a certain pressure to reduce the transmission of noise into the inside of the ear. As earplugs, elastic materials such as sponges or rubber materials are mainly used to apply pressure to the ear entrance. However, these earplugs reduce the size (amplitude) of noise and at the same time reduce the sound of conversations with other workers, so there is a limit that makes communication impossible.

In addition, in the industrial field, there is a mixture of a low-frequency sound corresponding to the sound of a human conversation and a high-frequency sound corresponding to the noise of a mechanical device, so it is necessary to selectively treat them, but the existing earplugs do not play this role. Accordingly, there is an urgent need for customized noise-blocking earplugs that can properly block noise according to workers and noise environments in industries and industrial sites.

Related Document 1 relates to a push-in earplug, which is provided to have an outer layer made of an inflatable second material including a long core made of a first material and a thermoplastic shell to block the external auditory meatus without a hollow part, thereby providing a sound insulation effect Although there is an increasing effect, there is a limit in that the user cannot properly block noise from external sounds having various frequencies while wearing earplugs.

Related Document 2 relates to a noise processing method linking individual noise-reducing earplugs and a smartphone. However, it is difficult for workers in the industrial field to control the sound while operating the smartphone at the same time as work.

KR 10-2015-0031332 KR 10-2020-0057312

The present invention is to solve the above problems, and a disc having a Geneva gear structure and a driving pin inserted into one side of the dial to enable communication with other workers in the industrial field and noise isolation at the work site with one sound insulation device. The purpose of this is to obtain a sound insulation device based on Geneva gear structure that can block external sound by replacing any sound insulation material with another sound insulation material using

In order to achieve the above object, the Geneva gear structure-based sound insulation device of the present invention is provided with a receiving groove having a concave shape on one side, and includes an insertion part in the form of a hollow cone on the other side so that at least a portion can be inserted into the user's external auditory meatus. a body part; a disc accommodated in the receiving groove and formed based on a Geneva gear structure including one or more sound insulating materials; a cap part for rotating the disk so that any sound insulating material positioned in a straight line with the central axis of the insertion part can be replaced with another sound insulating material; and a flange bearing positioned between the disk and the cap in the receiving groove.

As described above, according to the present invention, by providing a Geneva gear structure-based sound insulation device that can block external sound by replacing any sound insulation material with another sound insulation material using a disk having a Geneva gear structure and a driving pin inserted into one side of the dial, Without an additional connecting device, the dial can be gripped and rotated to prevent communication with other workers at the industrial site and noise isolation at the work site with a single sound insulation device, thus protecting the worker's hearing. there is.

1 is an exploded view of a sound insulation device based on a Geneva gear structure according to an embodiment of the present invention.
2 is an internal side view of a sound insulation device based on a Geneva gear structure according to an embodiment of the present invention.
3 is an exploded perspective view of a sound insulation device based on a Geneva gear structure according to an embodiment of the present invention.
4 is a view showing that a disk, a flange bearing, and a dial bearing are sequentially stacked on the main body according to an embodiment of the present invention.
5 is a view showing the movement of the disk as the dial rotates according to an embodiment of the present invention.

The terms used in this specification have been selected as currently widely used general terms as possible while considering the functions in the present invention, which may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings. 1 is an exploded view of a sound insulation device 1000 based on a Geneva gear structure according to an embodiment of the present invention. 2 is an internal side view of a sound insulation device 1000 based on a Geneva gear structure according to an embodiment of the present invention. 3 is an exploded perspective view of a sound insulation device 1000 based on a Geneva gear structure according to an embodiment of the present invention. 4 is a view showing that the disk 1200, the flange bearing 1400, and the dial bearing 1340 are sequentially stacked on the main body 1100 according to an embodiment of the present invention.

First, referring to FIG. 1 , the sound insulation device 1000 based on the Geneva gear structure of the present invention includes a body portion 1100 , a disk 1200 , a cap portion 1300 , and a flange bearing 1400 .

More specifically, the main body 1100 has a receiving groove 1110 having a concave shape on one side, and includes an insertion part 1120 in the form of a hollow cone on the other side so that at least a part can be inserted into the user's external auditory meatus. do.

Meanwhile, the insertion part 1120 may be provided eccentrically from the center of the other side surface of the body part 1100 . This is because the user's ear is connected to the user's face at a predetermined angle. That is, the insertion part 1120 is more closely attached to the inner surface of the ear to prevent the insertion part 1120 from being separated from the inside of the user's external auditory meatus even when the user moves. it is most preferable

In addition, the insertion part 1120 may include a tip hooking part 1121 at the distal end for hooking a tip in contact with the inside of the user's external auditory meatus. The tip is also generally referred to as an ear tip, is a part in direct contact with the sensitive skin inside the ear, and serves to block the user's ear hole, thereby greatly affecting sound insulation. The inside of the human ear has different shapes, so it is important to use an ear tip that suits the user. For example, if an ear tip that is not suitable for the user is used, the earphone continues to come off when worn or is too close to the ear canal, causing discomfort or discomfort due to friction, and effective sound isolation is difficult. Accordingly, the present invention is provided with the tip locking part 1121 at the distal end of the insertion part 1120 so that the tips of different sizes, shapes, and materials can be exchanged according to the size of the user's inner ear canal and the user's preference. characterized in that

In addition, the receiving groove 1110 includes a first step 1111 having an inner diameter corresponding to the outer diameter of the disk 1200 so that an empty space between the disk 1200 and the side surfaces of the receiving groove 1110 is minimized. characterized by forming. However, the first step 1111 may be provided to provide a predetermined empty space so that the disk 1200 can rotate.

Referring to FIG. 2 , the first step 1111 has a height slightly larger than the width of the disk 1200 . This is because the edge of the flange bearing 1400 is positioned on the upper surface of the first step 1111 after the disk 1200 is accommodated in the receiving groove 1110, so that the disk 1200 and the flange bearing 1400 are located. to avoid this contact. Accordingly, the flange bearing 1400 may not interfere with the rotational movement of the disk 1200 , and the space of the receiving groove 1110 is the space in which the disk 1200 rotates and the driving pin 1310 . It can be divided into a space in which the inserted dial 1320 rotates.

In addition, referring to FIG. 1 , the receiving groove 1110 forms a pair of second steps 1112 in a direction opposite to the top of the first step 1111 . The flange bearing 1400 may include a flange portion 1410 that is formed to be concave in an 'I' shape in both directions from the outer diameter, and is provided with a pair in the opposite direction.

In addition, the flange portion 1410 of the flange bearing 1400 may be coupled to the second step 1112 . Accordingly, the flange bearing 1400 has an effect of being fixed without rotating due to the aftermath of a rotational force generated as the disk 1200 or the dial 1320 rotates.

Next, the disk 1200 is accommodated in the receiving groove 1110 and is formed based on a Geneva gear structure including one or more sound insulating materials 1210 .

First, since the disk 1200 is formed based on the Geneva gear structure, intermittent rotation is possible. That is, the present invention may not separately include a stopper capable of setting the driving range. Also, as shown in FIG. 2 , there is a remarkable effect that the central axis of the insertion part 1120 and the central axis of the sound insulating material 1210 can be more easily positioned in a straight line.

In addition, one side of the disk 1200 may be provided with a pin groove 1230 provided in a concave shape from one surface of the disk 1200 so that the driving pin 1310 of the cap unit 1300 can be driven according to the guideline. there is. And the area of the disk 1200 is divided according to the number of the pin grooves 1230 .

In other words, the disk 1200 is a kind of intermittent gear like the conventional Geneva gear, and when the engine rotates, the pin is gradually engaged with the groove of the driven vehicle to make intermittent motion, but each area within the disk 1200 is There is a clear difference in that it has an area sufficient to accommodate the sound insulating material 1210 and the sound insulating material accommodating part 1220 .

Here, the sound insulating material 1210 may be at least one of the memory foam, a damper that is an acoustic resistor for attenuating external sound in a specific frequency band, and a filter having a sound insulating rate.

The sound insulating material 1210 may be inserted into the sound insulating material accommodating part 1220 provided in each region of the disk 1200 in the shape of a through hole, and the sound insulating material accommodating part 1220 may have a size of the sound insulating material 1210 . Accordingly, it may have a shape of a through-hole having a different size.

Meanwhile, on one side of the disk 1200 , the number of the pin grooves 1230 and the number of regions within the disk 1200 may be determined according to the number of the sound insulating material 1210 . For example, as shown in FIG. 1 , if three sound insulation materials 1210 are to be provided in the sound insulation device 1000 based on the Geneva gear structure of the present invention, the pin groove 1230 is divided into three branches based on the central axis of the disk 1200 . It may be formed to be concave, and the disk 1200 may be divided into a first zone, a second zone, and a third zone. In addition, one sound insulating material accommodating part 1220 may be formed in each zone, and the sound insulating material 1210 may be completely inserted one by one into each of the sound insulating material accommodating parts 1220 .

In addition, referring to FIG. 3, the sound insulation device 1000 based on the Geneva gear structure of the present invention is formed concavely on the lower surface of the receiving groove 1110 with respect to the central axis, and has a concave portion ( 1113) and the disk 1200 may further include a disk protrusion 1240 formed to protrude convexly with respect to the central axis on the other side. In addition, after the disk protrusion 1240 is completely inserted into the concave portion 1113 by an interference fitting method, it may not be separated by the locking jaw.

Accordingly, after being accommodated in the receiving groove 1110, the disk 1200 can be fixed in the vertical direction and can only be rotated so that the sound insulating material 1210 is positioned on the central axis of the insertion part 1120. It can be positioned in a straight line and the sound insulation effect can be improved.

Next, the cap unit 1300 rotates the disk 1200 so that any sound insulating material 1210a positioned in a straight line with the central axis of the insertion unit 1120 can be replaced with another sound insulating material 1210b, 1210c. .

More specifically, the cap part 1300 may include a driving pin 1310 , a dial 1320 , a plate 1330 , and a dial bearing 1340 . The driving pin 1310 may transmit power to enable the disk 1200 to rotate. It can be the same as the crankshaft function in a normal Geneva gear.

Next, the dial 1320 may have a predetermined length so that the user can grip it, and may have a driving pin receiving groove 1321 on one side so that one side of the driving pin 1310 can be inserted. And when the dial 1320 rotates in a clockwise or counterclockwise direction by a user's external force, the driving pin 1310 may perform a circular motion having a rotation radius in the same direction. On the other hand, the driving pin receiving groove 1321 may be provided eccentrically from the center of one side of the dial 1320 so that the driving pin 1310 can move in a circle having a rotation radius.

Also, referring to FIG. 3 , a step having an outer diameter smaller than the outer diameter of the dial 1320 may be formed at one end of the dial 1320, and a portion of the outer diameter of the step may be concave. In addition, the dial bearing 1340 is formed in a ring shape and may be fastened to one side of the dial 1320 having the driving pin receiving groove 1321 . A portion of the inner diameter of the dial bearing 1340 may be convex.

That is, the concave portion formed in the step formed at one end of the dial 1320 and the convex portion formed in a portion of the inner diameter of the dial bearing 1340 are fastened, so that the dial bearing 1340 rotates the dial 1320. When it rotates together, it has the effect of attenuating friction between the dial 1320 and the flange bearing 1400 and enabling smooth rotation.

Also, the height of the step formed at one end of the dial 1320 may be greater than the width of the dial bearing 1340 . This is the first of the flange bearing 1400 when the dial 1320 and the flange bearing 1400 are sequentially stacked on the body 1100 and the cap 1300 is fastened to the body 1100 . The step of the through hole 1420 and one end of the dial 1320 is fixed after being fastened to a predetermined width.

Meanwhile, referring to FIG. 1 , the other side of the dial 1320 may be partially flattened by being chamfered in a cylindrical shape so as to be easily rotated after being gripped by a user with a finger. In addition, the dial 1320 may be provided with a dial locking part 1322 to limit further accommodation after one side is accommodated in the dial receiving groove 1331 of the plate 1330 .

Next, the plate 1330 has a dial receiving groove 1331 having an inner diameter corresponding to the outer diameter of the dial 1320 so that one side of the dial 1320 having the driving pin receiving groove 1321 can be accommodated. can be provided The dial 1320 is formed in the dial receiving groove 1331 , and the receiving range may be limited by the dial engaging portion 1322 .

In addition, the plate 1330 may have a plate protrusion 1332 having an outer diameter corresponding to the inner diameter of the main body 1100 on one side to be fastened to the main body 1100 . Most preferably, the plate protrusion 1332 may have a pair of concave portions facing each other so as to be fastened with the second step 1112 formed in the receiving groove 1110 as shown in FIG. 3 .

In addition, the cap part 1300 is, most preferably, an air flow path in a portion spaced apart from the dial receiving groove 1331 of the plate 1330 by a predetermined distance to resolve the pressure difference between the receiving groove 1110 and the outside. It may further include an air hole 1350 that provides Accordingly, there is an effect of reducing the pressure difference that the user can feel when the user wears the Geneva gear structure-based sound insulation device 1000 of the present invention on a part of the external auditory meatus.

Most preferably, the hollow shaft of the air hole 1350 and the insertion part 1120 is formed so that the external sound is guided to the receiving groove 1110 through the air hole 1350 and then insulated from the sound insulating material 1210 . It may be positioned on a straight line. That is, the air hole 1350 , the sound insulating material receiving part 1220 of the disk 1200 , and the hollow shaft of the inserting part 1120 are positioned in a straight line, so that the sound insulation effect can be further maximized.

In addition, as mentioned above, the flange bearing 1400 is It may be positioned between the disk 1200 and the cap part 1300 in the receiving groove 1110 . In addition, the flange bearing 1400 is in contact with the dial bearing 1340 , has an outer diameter smaller than the outer diameter of the dial bearing 1340 , and a first through hole 1420 for guiding the circular motion of the driving pin 1310 . ) and a second through hole 1430 .

Here, in the flange bearing 1400 , the reason that the first through-hole 1420 and the second through-hole 1430 are distinguished is the part through which the disk 1200 is driven through the driving pin 1310 and the air hole. This is to distinguish the part where the external sound is introduced along the line 1350 .

Next, referring to FIG. 4A , there is a receiving groove 1110 of the main body 1100 , and referring to FIG. 4B , the disk 1200 is provided in the receiving groove 1110 . can be At this time, the concave portion 1113 of the receiving groove 1110 and the disk protrusion 1240 are fastened in an interference fit manner so that the disk 1200 rotates only without moving up and down inside the receiving groove 1110. It can be provided so that

Also, referring to FIG. 4C , the flange bearing 1400 may be positioned on the upper end of the disk 1200 . Most preferably, the flange bearing 1400 may be placed on the upper surface of the first step 1111 so as not to interfere with the rotation of the disk 1200, and the second step 1112 and the flange bearing to prevent additional movement. The flange part 1400 of 1400 may be fastened. And referring to FIG. 5D , the dial bearing 1340 may be positioned in contact with the first through hole 1420 .

Next, FIG. 5 is a view showing the movement of the disk 1200 as the dial 1320 rotates according to an embodiment of the present invention. Referring to FIG. 5 , in the second through hole 1430 , when the dial 1320 is rotated, the driving pin 1310 inserted into the dial 1320 rotates together, and the driving pin 1310 is the pin groove 1230 . It can be seen that the disk 1200 moves according to the movement along the .

Referring to FIG. 5A , when the driving pin 1310 moves counterclockwise in the pin groove 1230 between the blue sound insulating material and the red sound insulating material, the red sound insulating material moves through the first through hole 1420 as shown in FIG. 5B . ) can be located. And again, when the driving pin 1310 moves counterclockwise in the pin groove 1230 between the red sound insulating material and the yellow sound insulating material, the yellow sound insulating material may be positioned in the first through hole 1420 as shown in FIG. 5C .

On the other hand, referring to FIG. 2 , a rubber packing is provided in the empty space between the hollow part of the insertion part 1120 and the disk 1200 to additionally insulate the external sound that the sound insulating material 1210 has failed to insulate. It works.

As described above, according to the present invention, an arbitrary sound insulating material 1210a is replaced with another sound insulating material 1210b, 1210c using the drive pin 1310 inserted on one side of the dial 1320 and the disc 1200 having a Geneva gear structure. By providing the Geneva gear structure-based sound insulation device 1000 capable of blocking external sounds, the dial 1320 is gripped and rotated without an additional connection device to communicate with other workers in the industrial field with one sound insulation device. And it may be possible to block the noise in the workplace, and accordingly, there is an effect of protecting the hearing of workers.

As described above, although the embodiments have been described with reference to the limited embodiments and drawings, various modifications and variations are possible from the above description by those skilled in the art. For example, the described techniques are performed in a different order than the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

1000.. A sound insulation device based on the Geneva gear structure
1100.. body part
1110. Reception home
1111.. First step
1112.. 2nd step
1113. Concave
1120.. Insertion
1121.. Tip catch
1200.. Disc
1210, 1210a, 1210b, 1210c.. sound insulation
1220.. Sound insulating material receiving part
1230.. Pinhome
1240.. Disc protrusion
1300. Cap part
1310.. drive pin
1320.. Dial
1321. Drive pin receiving groove
1322.. Dial lock
1330. plate
1331.. Dial receiving groove
1332.. Plate overhang
1340.. Dial bearing
1350. Air hole
1400.. flange bearing
1410.. Flange part
1420. First through hole
1430.. Second through hole

Claims (5)

a body part having a receiving groove having a concave shape on one side and including an insertion part in the form of a hollow cone on the other side so that at least a portion can be inserted into the user's external auditory meatus;
a disc accommodated in the receiving groove and formed based on a Geneva gear structure including one or more sound insulating materials;
a cap part for rotating the disk so that any sound insulating material positioned in a straight line with the central axis of the insertion part can be replaced with another sound insulating material; and
Including a flange bearing located between the disk and the cap portion in the receiving groove;
The cap part,
a driving pin for transmitting power so that the disk can be rotated;
a dial having a predetermined length so that a user can grip it and having a driving pin receiving groove on one side so that one side of the driving pin can be inserted;
a plate having a dial receiving groove having an inner diameter corresponding to the outer diameter of the dial so that one side of the dial having the driving pin receiving groove can be accommodated; and
A dial bearing formed in a ring shape and fastened to one side of the dial having the driving pin receiving groove to minimize friction with the flange bearing;
The disk is
Including; a pin groove provided in a concave shape from one surface;
One surface is divided into a plurality of zones according to the pin groove, and each of the plurality of zones includes a sound insulating material receiving part,
The driving pin is
When the dial rotates clockwise or counterclockwise by the user's external force, it performs a circular motion with a rotation radius in the same direction,
The Geneva gear structure-based sound insulation device, characterized in that it is gradually engaged with the pin groove to rotate the disk, and any sound insulation material positioned in a straight line with the central axis of the insertion part can be replaced with another sound insulation material. The method of claim 1,
The cap part,
It further comprises;
The Geneva gear structure-based sound insulation device, characterized in that the air hole and the hollow shaft of the insertion part are positioned in a straight line to insulate the sound from the sound insulating material after external sound is guided to the receiving groove through the air hole. The method of claim 1,
The sound insulation material,
It can be inserted into the sound insulating material receiving portion provided in the disk in the form of a through hole,
A Geneva gear structure-based sound insulation device, characterized in that it is at least one of memory foam, a damper that is an acoustic resistance that attenuates external sounds in a specific frequency band, and a filter. The method of claim 1,
a concave portion formed to be concave with respect to the central axis on the lower end surface of the receiving groove and having a locking protrusion formed therein; and
It further includes; a disk protrusion formed to protrude convexly with respect to the central axis on the other side of the disk,
The Geneva gear structure-based sound insulation device, characterized in that after the disk protrusion is completely inserted into the concave portion by an interference fit method, it is not separated by the locking jaw. delete

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