This application claims priority from Korean Patent Application No. 10-2014-0045916, filed on Apr. 17, 2014, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference in its entirety.
1. Field
Apparatuses and methods consistent with exemplary embodiments relate to a rotary knob assembly, and more particularly, to a rotary knob assembly capable of a rotary motion and an up-and-down motion.
2. Description of the Related Art
Generally, acoustic devices such as audio players, and the like, have a volume controller for controlling a volume of sound. For example, three types of volume controllers may be used. The first type is a protruding type of volume controller, and is formed so that a rotary knob protrudes. In this example, a user can adjust the volume of sound by rotating or turning the rotary knob. Here, if the rotary knob is rotated in one direction, the volume of sound is increased, and if the rotary knob is rotated in the opposite direction, the volume of sound is reduced.
A second type of volume controller is a button type of volume controller which is typically provided with a sound up button and a sound down button which are separately formed. In this example, if the sound up button is pressed, the volume of sound is increased, and if the sound down button is pressed, the volume of sound is decreased.
A third type of volume controller is a touch type of volume controller which is used in acoustic devices that have a touch screen. Similar to the example of the button type of volume controller, a sound up button image and a sound down button image are displayed on the touch screen. In this example, when a user touches the sound up button image, the volume of sound is increased, and when the user touches the sound down button image, the volume of sound is decreased.
However, because the conventional volume controllers project outwardly or require the use of a touch screen, there is a limit in designing the acoustic device. Accordingly, a different type of volume controller is needed to increase the diversity of the design of the acoustic device.
Exemplary embodiments overcome the above disadvantages and other disadvantages not described above. Also, an exemplary embodiment is not required to overcome the disadvantages described above, and an exemplary embodiment may not overcome any of the problems described above.
The exemplary embodiments relate to a rotary knob assembly capable of up-and-down motion in which, when not in use, the rotary knob may be accommodated within a device and does not protrude. Furthermore, when in use, the rotary knob can be projected by one-touch and a projecting motion of the rotary knob is smooth.
According to an aspect of an exemplary embodiment, there is provided a rotary knob assembly capable of up-and-down motion, including a lower case in which an oil damper is disposed; a rotary sleeve rotatably disposed with respect to the lower case, the rotary sleeve including a connecting hole; a slide cam that moves linearly with respect to the lower case, the slide cam including a pair of cam grooves which are inclined with respect to the lower case and a sleeve hole through which the rotary sleeve passes; an elastic member disposed between the slide cam and the lower case, the elastic member including a first end fixed to the lower case and a second end fixed to the slide cam; an up-and-down moving sleeve that moves up and down with respect to the rotary sleeve, the up-and-down moving sleeve including a pair of up-and-down cams that are inserted in the pair of cam grooves of the slide cam; a rotary knob that is rotatably connected to the up-and-down moving sleeve, the rotary knob including a connecting member that is inserted in the connecting hole of the rotary sleeve; and an upper case connected to an upper side of the lower case, the upper case being configured to limit up and down movement of the rotary knob, wherein a moving speed of the slide cam is controlled by the oil damper.
The rotary knob assembly may include an output variable element including a rotation shaft connected to a bottom end of the rotary sleeve; and a printed circuit board in which the output variable element is disposed, the printed circuit board being fixed to the lower case.
The output variable element may include a variable volume.
The oil damper may include a pinion gear; and an oil tank rotatably supporting the pinion gear, the oil tank being filled with oil, wherein a rotation speed of the pinion gear may be slowed by a viscosity resistance of the oil in the oil tank.
The slide cam may include a rack gear that is formed parallel to a moving direction of the slide cam and that is engaged with the pinion gear of the oil damper.
The rotary knob may include an upper rotary knob including a hollow cylindrical shape with a bottom, and a lower rotary knob including a hollow cylindrical shape, wherein the connecting member may be formed at a center of the bottom of the upper rotary knob, and the upper rotary knob may be detachably coupled to the lower rotary knob.
The lower rotary knob may include a flange that is caught by a bottom surface of the upper case.
The up-and-down moving sleeve may include a sleeve cap including a hollow cylindrical shape, the sleeve cap including a sleeve flange caught by a top end of the lower rotary knob; and a sleeve body including a hollow cylindrical shape, the sleeve body may be coupled to the sleeve cap, and the pair of up-and-down cams may be formed in a lower portion of a side surface of the sleeve body.
The rotary sleeve may include an upper rotary sleeve including the connecting hole and a receiving space in which the connecting member of the rotary knob is received; and a lower rotary sleeve coupled to the upper rotary sleeve and including a fixing groove in which a rotating object is inserted.
The rotary sleeve may be rotatably disposed in the lower case by a fixing ring.
A plurality of inclined teeth may be concentrically formed at a top end of the lower rotary sleeve.
The connecting hole of the upper rotary sleeve may include a central hole and a plurality of slots extending from the central hole, and the connecting member of the rotary knob may include a body inserted in the central hole and a plurality of ribs that extend from the body and are inserted in the slots.
A bottom surface of the upper rotary sleeve may include receiving grooves in which the ribs of the rotary knob are received.
The rotary knob assembly may include an elastic member which is disposed between the rotary knob and the rotary sleeve, and which elastically supports the rotary knob.
In response to the rotary knob being pressed once, the connecting member of the rotary knob may be caught by the rotary sleeve so that the rotary sleeve remains in a pressed state.
In response to the rotary knob being pressed again, the connecting member of the rotary knob may get out of the rotary sleeve and project to an original position.
The lower case may include a pair of supporting brackets to support an up and down movement of the up-and-down moving sleeve.
The lower case may include a push-push latch, and a secondary fixing hook which is coupled to or separated from the push-push latch according to a movement of the slide cam may be formed in the slide cam.
Other objects, advantages and salient features of the present disclosure will become apparent from the following detailed description, which, taken in conjunction with the annexed drawings, discloses the exemplary embodiments.
These and/or other aspects and advantages of the present disclosure will become more apparent and more readily appreciated from the following description, taken in conjunction with the accompanying drawings, in which:
Throughout the drawings, like reference numerals will be understood to refer to like parts, components and structures.
Hereinafter, certain exemplary embodiments will be described in detail with reference to the accompanying drawings.
The matters defined herein, such as a detailed construction and elements thereof, are provided to assist a reader in a comprehensive understanding of the invention. Thus, it is apparent that one or more exemplary embodiments may be carried out without those specifically defined matters. Also, well-known functions and/or constructions may be omitted to provide a clear and concise description of the exemplary embodiments. Further, dimensions of various elements in the accompanying drawings may be arbitrarily increased or decreased for assisting in a comprehensive understanding.
Referring to
The case 100 creates a frame for the rotary knob assembly 1 which is capable of up-and-down motion according to an embodiment of the present disclosure, and accommodates the slide cam 200, the elastic member 300, the rotary sleeve 400, the up-and-down moving sleeve 600, and the rotary knob 700. As an example, the rotary knob assembly 1 may be disposed inside a device such as an audio player, for example, a receiver, a television, a DVD player, a game console, a Blu-ray player, a computer, and the like.
The case 100 may be formed of a shape that has a substantially rectangular cross-section, and which includes an upper case 150 and a knob hole 151 through which the rotary knob 700 projects, and a lower case 110 which is removably coupled to the upper case 150 and supports the slide cam 200 which is movable. The upper case 150 and the lower case 110 may be formed such that they are coupled by one-touch. For example, the upper case 150 and the lower case 110 may be coupled by a hook connection. In this example, the lower case 110 may be provided with two hooks 111 in a diagonal direction, and the upper case 150 may be provided with two catching portions 153 in which the two hooks 111 of the lower case 110 are caught. The hook connection of the upper case 150 and the lower case 110 is merely for purposes of example, and it should be appreciated that the upper case 150 and the lower case 110 may be coupled by various ways, such as a screw connection, and the like.
The upper case 150 may include a plurality of fixing brackets 155 which are used to secure the rotary knob assembly 1 to another device. For example, in
The lower case 110 supports the slide cam 200 so that the slide cam 200 may move linearly within the lower case 110. Also, the lower case 110 supports the rotary sleeve 400 so that the rotary sleeve 400 can perform a rotary movement. For example, the slide cam 200 may be disposed on the upper side of the bottom surface 113 of the lower case 110 so that the slide cam 200 can slide in approximately a straight line with respect to the bottom surface 113. The bottom surface 113 of the lower case 110 may include a damper hole 115 through which a pinion gear 551 of an oil damper 550 projects and a sleeve hole 117 through which the rotary sleeve 400 projects. The sleeve hole 117 may have an inner diameter that is smaller than an outer diameter of a rotary flange 420 provided in a lower end of the rotary sleeve 400 so that the rotary flange 420 can not pass through the sleeve hole 117. A pair of supporting brackets 119 that guide the movement of the up-and-down moving sleeve 600 and limits right and left shaking of the up-and-down moving sleeve 600 may be disposed around the sleeve hole 117. In the example of
As illustrated in
A volume circuit board 920 may be disposed at a top end of the fixing ring receiving portion 120 of the lower case 110. For example, a plurality of female screw portions 122 may be provided in an outer peripheral surface of the fixing ring receiving portion 120. In this exemplary embodiment, three female screw portions 122 are provided. Accordingly, the volume circuit board 920 may be fixed to the female screw portions 122 of the lower case 110 by a plurality of screws or bolts. If the volume circuit board 920 is fixed to the lower case 110, the fixing ring 500 may not come out from the fixing ring receiving portion 120 of the lower case 110.
The volume circuit board 920 may be a printed circuit board in which a variable volume 900 is disposed. The variable volume 900 may be fixed to a surface of the volume circuit board 920, and a wire or a flexible cable (not illustrated) may be connected to the other surface of the volume circuit board 920. The volume circuit board 920 may serve to fix the fixing ring 500 to the fixing ring receiving portion 120 of the lower case 110. Here, a rotation shaft 910 is disposed in a top surface of the variable volume 900. Accordingly, if the rotation shaft 910 is rotated, the volume is varied. In detail, if the rotation shaft 910 is rotated in one direction, the volume is increased, and, if the rotation shaft 910 is rotated in the opposite direction, the volume is decreased. The variable volume 900 may use related variable volumes. Accordingly, descriptions for the structure and operation of the variable volume 900 are omitted. The rotation shaft 910 of the variable volume 900 is connected to the bottom end of the rotary sleeve 400 so that the rotation shaft 910 is rotated integrally with the rotary sleeve 400.
According to various exemplary embodiments, the fixing ring 500 is fixed to the lower case 110 by the volume circuit board 920. However, this is merely for purposes of example. The rotary knob assembly 1 capable of up-and-down motion may be used not only to control the volume. For example, the rotary knob assembly 1 capable of up-and-down motion according to an exemplary embodiment may be configured so that an output variable element output of which is changed by rotation of a rotation shaft instead of the variable volume 900 is disposed in the printed circuit board 920 and the rotation shaft of the output variable element is rotated by the rotary sleeve 400.
In this example, an oil damper 550 is disposed at a side of the fixing ring 500 in the lower side of the bottom surface 113 of the lower case 110. The oil damper 550 may control a moving speed of the slide cam 200. For example, as illustrated in
The slide cam 200 is disposed such that it can slidably move in a straight line with respect to the bottom surface 113 of the lower case 110, and is formed in a substantially flattened U shape. For example, referring to
A rotary sleeve 400 disposed in the lower case 110 passes through a rotary sleeve through hole 211, and is formed in the base plate 210. The rotary sleeve through hole 211 may have an elongated hole shape so that, when the slide cam 200 is moved linearly, the slide cam 200 does not interfere with the rotary sleeve 400. A moving groove 213 in which the pinion gear 551 of the oil damper 550 is able to move is formed in parallel to the rotary sleeve through hole 211 in one side of the rotary sleeve through hole 211 in the bottom surface of the base plate 210. A rack gear 240 is formed on the side surface of the moving groove 213 to engage with the pinion gear 551 of the oil damper 550. Accordingly, if the slide cam 200 is moved, the pinion gear 551 of the oil damper 550 that is engaged with the rack gear 240 is rotated.
An elastic member 300 which applies an elastic force that can overcome the viscous resistance of the oil damper 550 to the slide cam 200, is disposed between the slide cam 200 and the lower case 110. For example, the elastic member 300 may be disposed between the side surface of the slide cam 200 on which the rack gear 240 is formed and the lower case 110 facing the side surface thereof. Also, one end of the elastic member 300 is fixed to a first protrusion 241 that is formed on the side wall of the slide cam 200, and the other end of the elastic member 300 is fixed to a second protrusion 130 formed on the side wall of the lower case 110. Here, the side wall of the lower case 110 may include a slot 131 to accommodate the elastic member 300 in the operating direction of the slide cam 200 so that the lower case 110 does not interfere with the operation of the elastic member 300. Also, the elastic member 300 may be a coil spring.
A secondary fixing hook 820 (
In the above examples, the secondary fixing hook 820 is disposed in the slide cam 200, and the push-push latch 810 is disposed in the lower case 110. However, the exemplary embodiments are not limited to the installation of the secondary fixing hook 820 and the push-push latch 810. Although not illustrated, for example, the secondary fixing hook 820 may be disposed in the lower case 110, and the push-push latch 810 may be disposed in the slide cam 200.
The rotary sleeve 400 supports the up-and-down moving sleeve 600 so that it can move up and down. The rotary sleeve 400 is formed such that it can rotate a rotating object, for example, the rotation shaft 910 of the variable volume 900. Referring to
The lower rotary sleeve 410 may be formed of a hollow cylindrical shape, and may include a rotary flange 420 at a bottom end of the lower rotary sleeve 410. The rotary flange 420 may include a size that does not pass through the sleeve hole 117 of the lower case 110, and is supported by the fixing ring 500. Because the rotary flange 420 of the lower rotary sleeve 410 rotates in a space between the fixing ring receiving portion 120 and the fixing ring 500 of the lower case 110, the lower rotary sleeve 410 may not separate from the lower case 110, and may rotate with respect to the lower case 110. A hollow 411 of the lower rotary sleeve 410 is formed in a fixing groove to fix the rotation shaft 910 of the variable volume 900. In the example of
A plurality of inclined teeth 414 are formed around the hollow 411 of the top end of the lower rotary sleeve 410. Referring to the example of
The upper rotary sleeve 450 is formed of a hollow cylindrical shape, and is coupled to the lower rotary sleeve 410. For example, the upper rotary sleeve 450 may be formed in a two-stage structure having different outer diameters. In this example, a lower portion 451 of the upper rotary sleeve 450 is coupled to the lower rotary sleeve 410 and is formed to have the same outer diameter as the outer diameter of the lower rotary sleeve 410 or an outer diameter similar to the outer diameter of the lower rotary sleeve 410. An upper portion 452 of the upper rotary sleeve 450 is formed to have an outer diameter that is smaller than that of the lower portion 451. A ring-shaped spring groove 453 may be formed between the upper portion 452 and the lower portion 451 of the upper rotary sleeve 450 so that a coil spring 350 may elastically support the rotary knob 700 and be disposed in the spring groove 453.
The upper portion 452 of the upper rotary sleeve 450 includes a connecting hole 460 configured to receive a connecting member 760 of the rotary knob 700. In this example, the connecting hole 460 includes a central hole 461 and three slots 462 extending in a radial direction from the central hole 461. The central hole 461 and three slots 462 are formed to penetrate the upper portion 452 of the upper rotary sleeve 450. An example of the connecting member 760 of the rotary knob 700 is further described herein and may be inserted into the central hole 461 and three slots 462 of the upper rotary sleeve 450. A bottom surface of the upper portion 452 of the upper rotary sleeve 450 includes jaws 465 and receiving grooves 464 that are inclined in an upward direction between the slots 462. A side surface of the jaws 465 connected to the slot 462 is inclined upwardly toward the slot 462. Ribs 762 of the connecting member 760 of the rotary knob 700 are caught by the receiving grooves 464 of the bottom surface of the upper portion 452. In this example, the connecting member 760 has three ribs 762, and the connecting hole 460 in which the connecting member 760 is inserted has three slots 462. However, this is merely for purposes of example, and it should be appreciated that the connecting member 760 may be formed to have, one, two, three, four or more ribs 762, and the connecting hole 460 may be formed to have a number of slots 462 corresponding to the number of ribs 762.
In this example, an inclined teeth receiving hole 470 (shown in
Also, a plurality of screw holes 457 (shown in
The up-and-down moving sleeve 600 is connected to the rotary knob 700, and is moved up and down according to a vertical movement of the rotary knob 700 which allows the slide cam 200 to move linearly in a horizontal direction. For example, the up-and-down moving sleeve 600 may convert a linear movement in a vertical direction into a linear movement in the horizontal direction with the slide cam 200. The up-and-down moving sleeve 600 may include a hollow cylindrical shape, and may include a pair of up-and-down cams 620 in a low end portion of the side surface of the up-and-down moving sleeve 600. Each of the up-and-down cams 620 may include a bar shape having a circular cross-section. A distance ādā between opposing ends of the pair of up-and-down cams 620 is formed so that the ends can be inserted into the top ends of the cam grooves 230 formed in the opposite side walls 220 of the slide cam 200 and to press the opposite side walls 220 of the slide cam 200 forming the cam groove 230. Accordingly, the pair of up-and-down cams 620 of the up-and-down moving sleeve 600 may be inserted into the cam groove 230 through the top end 231 of the slide cam 200, and press or otherwise apply pressure to the slide cam 200. Because the upper side of the slide cam 200 is covered by the upper case 150, even in an example in which the up-and-down moving sleeve 600 is being moved up and down, the up-and-down moving sleeve 600 does not come out of the cam groove 230.
As illustrated in
As illustrated in
Accordingly, if the sleeve cap 650 is inserted in the connection step 611 of the sleeve body 610, each of the plurality of coupling hooks 651 of the sleeve cap 650 may be moved downwardly along the guide grooves 617 of the sleeve body 610, and then may be caught by the hooking jaws 615. Thus, the sleeve cap 650 may be coupled to the sleeve body 610 so that the sleeve cap 650 is not separated from the sleeve body 610. In this example, the number of the coupling hooks 651 is not limited to three. For example, the number of coupling hooks 651 may be one, two, three, four, or more.
The rotary knob 700 is rotatably coupled to the up-and-down moving sleeve 600, and is configured to be moved up and down with respect to the upper case 150 by a force, for example, that is applied from the outside. For example, as illustrated in
The upper rotary knob 750 may be formed of a hollow cylindrical shape with a bottom. A connecting member 760 can be inserted in the connecting hole 460 of the rotary sleeve 400 and may be formed in the center of the bottom of the upper rotary knob 750. The connecting member 760 may be connected to a central axis 755 extending from the bottom of the upper rotary knob 750 by a screw. For example, the connecting member 760 may be formed of a cylindrical body 761 and a plurality of ribs 762 extending radially from the surface of the body 761. A through hole (not illustrated) for screwing to the central axis 755 of the upper rotary knob 750 may be formed in the center of the body 761. The plurality of ribs 762 may be formed in a wedge shape so that the ribs 762 move smoothly along the slots 462 of the connecting hole 460 of the rotary sleeve 400. Also, the ribs 762 may be smoothly inserted into the slots 462 from the receiving grooves 464 of the bottom surface of the rotary sleeve 400.
As a non-limiting example, the connecting member 760 may include three ribs 762 in the same manner as the number of the slots 462 of the connecting hole 460 of the rotary sleeve 400. Accordingly, if the connecting member 760 of the rotary knob 700 is inserted into the connecting hole 460 of the rotary sleeve 400, the rotary knob 700 may be moved up and down with respect to the rotary sleeve 400. Also, if the connecting member 760 of the rotary knob 700 is located within the connecting hole 460 of the rotary sleeve 400, and the rotary knob 700 is rotated, the rotary sleeve 400 may be rotated together with the rotary knob 700. If the connecting member 760 of the rotary knob 700 passes through the connecting hole 460 and is located in the inclined teeth receiving hole 470, the rotation of the rotary knob 700 may not be transmitted to the rotary sleeve 400. In this example, the connecting member 760 is formed separately from the upper rotary knob 750. However, this is merely for purposes of example, and it should be appreciated that the connecting member 760 may be formed integrally with the upper rotary knob 750.
Referring again to
The lower rotary knob 710 is formed of a hollow cylindrical shape, and includes an upper stem 711 and a lower stem 712. An outer diameter of the upper stem 711 is smaller than an outer diameter of the lower stem 712. The upper rotary knob 750 may be connected to the upper stem 711 of the lower rotary knob 710. The upper stem 711 of the lower rotary knob 710 includes a plurality of fixing grooves 731 by which the plurality of fixing hooks 751 of the upper rotary knob 750 are caught and a plurality of guide grooves 733 into which the plurality of guide protrusions 753 are inserted. Accordingly, if the upper rotary knob 750 is inserted into the upper stem 711 of the lower rotary knob 710, each of the plurality of fixing hooks 751 may be caught by the fixing groove 731 so that the upper rotary knob 750 is connected to the lower rotary knob 710. A flange 720 is also provided in the bottom end of the lower rotary knob 710. The flange 720 of the lower rotary knob 710 is formed larger than the diameter of the knob hole 151 of the upper case 150. Accordingly, when the rotary knob 700 is moved upwardly with respect to the upper case 150, the flange 720 is caught by the bottom surface 157 of the upper case 150. Therefore, the flange 720 may function as a stopper to limit a rising distance of the rotary knob 700.
The rotary knob 700 may be rotatably coupled to the up-and-down moving sleeve 600 so that the rotary knob 700 can move up and down with the up-and-down moving sleeve 600 while rotating with respect to the up-and-down moving sleeve 600. For example, referring to
Also, because the sleeve flange 660 of the up-and-down moving sleeve 600 is located in a space between the lower rotary knob 710 and the upper rotary knob 750 of the rotary knob 700, the rotary knob 700 can be moved up and down along with the up-and-down moving sleeve 600 by vertical movement of the up-and-down moving sleeve 600. In this example, the rotary knob 700 may be elastically supported by the coil spring 350 disposed in the spring groove 453 of the rotary sleeve 400 that passes through the inside of the up-and-down moving sleeve 600.
Hereinafter, examples of the rotary knob assembly 1 capable of up-and-down motion are described with reference to
In the examples of
In the rotary knob assembly 1 capable of up-and-down motion as illustrated in
In a state in which the rotary knob 700 projects as illustrated in
Hereinafter, an example in which the rotary knob 700 is pressed in a state in which the rotary knob 700 projects as illustrated in
If a user presses the top surface of the rotary knob 700, the rotary knob 700 moves down. When the rotary knob 700 is moved down, the connecting member 760 of the rotary knob 700 and the up-and-down moving sleeve 600 are also moved down along with the rotary knob 700. When the connecting member 760 of the rotary knob 700 is moved down, the plurality of ribs 762 of the connecting member 760 are moved down along the slots 462 of the connecting hole 460 of the rotary sleeve 400, and come into contact with the plurality of inclined teeth 414 that are provided in the top end of the lower rotary sleeve 410.
When a force is continuously applied to the rotary knob 700 in the downward direction, the ribs 762 may be lowered along the inclined surfaces 415 of the inclined teeth 414, and the rotary sleeve 400 may be rotated by a predetermined angle as much as the ribs 762 are lowered along the inclined surface 415. When the rotary sleeve 400 is rotated by the predetermined angle, the ribs 762 of the rotary knob 700 come out of the slots 462 of the rotary sleeve 400.
Accordingly, if the user removes the force applied to the rotary knob 700, as illustrated in
Also, when the up-and-down moving sleeve 600 is moved downward by the rotary knob 700, the pair of up-and-down cams 620 of the up-and-down moving sleeve 600 apply a force (arrow F1) to the cam groove 230 of the slide cam 200 in the downward direction as illustrated in
In this example, if the rotary knob 700 is moved downward, the up-and-down moving sleeve 600 is moved downward, and the up-and-down cams 620 of the up-and-down moving sleeve 600 are moved downward along the cam groove 230 of the slide cam 200. Also, when the up-and-down cams 620 of the up-and-down moving sleeve 600 are located at the P2 position as shown in
In an example of the rotary knob assembly 1 capable of up-and-down movement in which the lower case 110 is provided with the push-push latch 810 and the slide cam 200 is provided with the secondary fixing hook 820, when the slide cam 200 is moved in the horizontal direction by the lowering of the rotary knob 700, the secondary fixing hook 820 of the slide cam 200 may be coupled to the push-push latch 810 of the lower case 110 so that the slide cam 200 may be fixed more stably to the lower case 110. Accordingly, the rotary knob 700 can stably remain in the pressed state. In this example, the push-push latch 810 and the secondary fixing hook 820 are additionally disposed in order to secure the slide cam 200 more stably. Accordingly, as another example, the rotary knob assembly 1 capable of up and down movement may be formed by omitting the push-push latch 810 and the secondary fixing hook 820.
As illustrated in
For example, when the top surface of the rotary knob 700 is located at the same height as the panel 3 or at a height similar to the panel 3, as illustrated in
In this example, if the user presses the rotary knob 700, the connecting member 760 of the rotary knob 700 and the up-and-down moving sleeve 600 are moved downward together. Because the up-and-down cams 620 of the up-and-down moving sleeve 600 are moved from the P2 position to a P3 position as shown in
While the ribs 762 of the connecting member 760 are in contact with the inclined surfaces 415 of the inclined teeth 414 of the rotary sleeve 400, and if the force is continuously applied to the rotary knob 700 in the downward direction, the ribs 762 of the connecting member 760 push the inclined surfaces 415 of the inclined teeth 414 of the rotary sleeve 400 so that the rotary sleeve 400 is rotated by a predetermined angle. Accordingly, the slots 462 of the connecting hole 460 of the rotary sleeve 400 are located above the ribs 762 of the connecting member 760.
In this example, if the force applied to the rotary knob 700 is removed, the slide cam 200 moves in the horizontal direction by the elastic force of the elastic member 300 disposed between the lower case 110 and the slide cam 200. In the example of
When the slide cam 200 is moved in the horizontal direction by the elastic member 300, the pinion gear 551 of the oil damper 550 that is engaged with the rack gear 240 of the slide cam 200 may be rotated. For example, while the rotary knob 700 is pressed as illustrated in
When the up-and-down cams 620 of the up-and-down moving sleeve 600 are moved in an upward direction by the horizontal movement of the slide cam 200, the up-and-down moving sleeve 600 is also moved in the upward direction. When the up-and-down moving sleeve 600 is moved in the upward direction, the rotary knob 700 connected to the up-and-down moving sleeve 600 also is moved in the upward direction. Because the slide cam 200 for moving the up-and-down moving sleeve 600 upwardly is moved slowly in the horizontal direction by the oil damper 550, the up-and-down moving sleeve 600 is also slowly moved in the upward direction. Accordingly, because the up-and-down moving sleeve 600 is slowly moved in the upward direction, the rotary knob 700 is also slowly projected outside the panel 3.
The upward movement of the rotary knob 700 may be limited by the flange 720 of the rotary knob 700. For example, when the rotary knob 700 is raised, the flange 720 of the rotary knob 700 may be caught by the bottom surface 157 of the upper case 150 as illustrated in
Accordingly, when the connecting member 760 of the rotary knob 700 is rotated, the rotary sleeve 400 is also rotated together by the ribs 762 of the connecting member 760. In the state in which the rotary knob 700 projects from the panel 3 as illustrated in
When the rotary sleeve 400 is rotated, the rotation shaft 910 of the variable volume 900 connected to the lower portion of the rotary sleeve 400 may be rotated integrally with the rotary sleeve 400. Accordingly, when the user rotates the rotary knob 700, the rotation shaft 910 of the variable volume 900 is rotated integrally with the rotary knob 700 such that the user can adjust the volume of the variable volume 900.
According to various exemplary embodiments, with the rotary knob assembly 1 capable of up and down movement, the rotary knob 700 of the rotary knob assembly 1 may be located inside a device such that an edge of the rotary knob is substantially or approximately flush with the outside of the case. Also, when pressed by a user, the rotary knob 700 may smoothly project outward from the device. Accordingly, it is possible to increase the degree of freedom in designing the device using the rotary knob assembly 1.
Also, a projection of the rotary knob 700 by the elastic member 300 and the slide cam 200 may be slowly performed due to the oil damper 550, thereby giving users a luxurious feel.
While the exemplary embodiments of the present disclosure have been described, additional variations and modifications of the exemplary embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims shall be construed to include both the above exemplary embodiments and all such variations and modifications that fall within the spirit and scope of the inventive concepts.
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Number | Date | Country | |
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20150303009 A1 | Oct 2015 | US |