KR20120140490A - Manually operated rotational knob apparatus for airtight structure using magnets - Google Patents

Abstract

PURPOSE: A manually operated rotational knob apparatus is provided to minimize the size of a driving part of an inner rotating body and to prevent the loss of a rotating force by a frictional force. CONSTITUTION: A manually operated rotational knob apparatus comprises a cover unit(10), a rotating unit(20). The cover unit comprises a rotating knob(11), a first rotating plate arm(12), and a first magnetic material(13). The first rotating plate arm is arranged to be separated from a cover part which corresponds with the first plate arm. The rotating part comprises a second plate arm(21) and second magnetic member(22). [Reference numerals] (13,22) Magnet

Description

Manual Operated Rotational Knob Apparatus for Airtight Structure Using Magnets

The present invention relates to a manual rotary knob device for a sealed structure, and more particularly, in the manual operation of the rotating body inside the sealed mechanism, since there is no shaft penetrating from the outside to the inside, it is possible to maintain the sealing characteristics of the mechanism perfectly, It relates to a passive rotating knob device for a closed structure using a magnet, by using a non-contact rotary knob, there is no problem of the loss of rotation force due to friction.

In general, in the case of a mechanism in which the internal rotating body is electrically operated through the rotary drive unit and any air pressure is input and output, the mechanism itself should have a good sealing property, which is easily designed and manufactured as shown in FIG. 1. . However, in order to operate the rotating body inside the closed mechanism by automatic and manual combined use, as shown in Figure 2 it must be rotated using an axis penetrating from the inside to the outside.

Therefore, in general, pneumatic parts using mechanical and physical methods such as mechanical seals, rip seals, rotary seals, etc. are mounted on the shaft and designed to maintain the maximum sealing characteristics. However, in this case, when electric rotation (internal drive) and manual rotation (external drive) are used together, the airtight components and the rotating shafts cannot be completely sealed, and because of the frictional force, the non-manual electric In the case of automatic rotation, the loss problem of having to manufacture the additional rotational force in consideration of the frictional force occurs.

Accordingly, there is a need for a manual rotary knob device for a sealed structure that overcomes the unreasonable point of the structure that has been operating the internal rotating body through the shaft penetrating the conventional sealed structure and enables reliable sealing, and does not lose rotational force due to friction. It is rising.

The present invention has been made to solve the above problems, the object of the present invention is to manually maintain the sealing characteristics of the mechanism because there is no shaft penetrating from the outside to the manual operation of the rotating body inside the closure mechanism It is possible to provide a manual rotating knob device for a closed structure using a magnet, which can be free from problems of rotational force loss due to friction by using a non-contacting rotary knob.

According to the present invention for achieving the above object, in the manual rotary knob device for a sealed structure to rotate the rotary body accommodated in the housing by operating a rotary knob located outside the housing of the sealed structure, the rotary knob And a cover part including a first rotating plate arm axially connected to a lower portion of the knob and a first magnetic body accommodated in the first rotating plate arm; And a second rotating plate arm spaced apart from the cover portion at a position corresponding to the first rotating plate arm at a lower portion of the cover portion, the second rotating plate arm axially connected to the internal rotating body, and the second rotating plate arm accommodated in the second rotating plate arm. It is a manual rotary knob device for a closed structure using a magnet, characterized in that it comprises a rotating part including a magnetic material.

And it is characterized in that the rotating drive member is coupled to the shaft connected to the internal rotating body to enable automatic rotation.

According to one aspect of the present invention as described above, the first magnetic body and the second magnetic body are each provided with one magnet facing the opposite magnetic poles, to operate the rotary knob to move the first magnetic body Accordingly, the internal magnetic body is rotated while the second magnetic body is moved by the attraction force.

According to another aspect of the present invention, the first magnetic body and the second magnetic body are each provided with one magnet, the lower magnetic pole of the first magnetic body and the upper magnetic pole of the second magnetic body, the rotation type As the first magnetic body is moved by operating a knob, the internal magnetic body rotates while the second magnetic body is pushed in the same direction as the moving direction of the first magnetic body by repulsive force.

In addition, the second rotation plate arm is provided with an elastic return member, when the force is not applied to the rotary knob, the second rotary plate arm is moved to a position opposite to the direction in which the user operates the rotary knob While the first magnetic material is pushed by the repulsive force with the second magnetic material, the rotary knob automatically returns to the initial position.

According to another aspect of the present invention, the first magnetic body is provided in the form of two magnets having the same direction of the magnetic pole arrangement is spaced apart by a predetermined interval, the second magnetic body is one magnet of the two magnets Located near the central axis, the same magnetic pole as the lower magnetic pole of the first magnetic material is installed so as to be located on the upper side.

According to the present invention as described above, in the manual operation of the rotating body inside the closure mechanism, there is no shaft penetrating from the outside to the inside, it is possible to maintain the sealing characteristics of the mechanism perfectly. In addition, there is no problem of loss of rotational force due to frictional force by making the internal rotating body almost no load state using the non-contact rotary knob, there is an effect that can be designed to minimize the drive of the internal rotating body.

1 is a front sectional view of a rotating body insert-type closed structure mechanism capable of automatic rotation.
Figure 2 is a front sectional view of a rotating body insert-type closed structure mechanism capable of rotating for both automatic and manual.
Figure 3 is a front sectional view of a manual rotary knob device for a sealed structure according to the basic embodiment of the present invention.
Figure 4 is a front cross-sectional view of the manual rotation knob device for a sealed structure according to an embodiment of the present invention and a view showing a moving direction of the rotating plate arm.
Figure 5 is a front sectional view of the manual rotation knob device for a closed structure according to another embodiment of the present invention and a view showing a moving direction of the rotating plate arm.
6 is a cross-sectional view of the manual rotation knob device for a closed structure according to another embodiment of the present invention and a diagram showing the arrangement of the magnet.
FIG. 7 is an exploded view of a portion of the manual rotating knob apparatus for a sealed structure actually manufactured according to the embodiment as shown in FIG. 6.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings. It should be noted that the same elements in the figures are denoted by the same reference signs wherever possible.

1 is a front sectional view of a rotating body insert-type closed structure mechanism capable of automatic rotation.

Figure 2 is a front sectional view of a rotating body insert-type closed structure mechanism capable of rotating for both automatic and manual.

1 and 2 are as described above in the background.

Figure 3 is a front sectional view of a manual rotary knob device for a sealed structure according to the basic embodiment of the present invention.

Referring to FIG. 3, the manual rotating knob device for a closed structure using a magnet according to the present invention includes a cover part 10 and a rotating part 20.

The cover part 10 includes a rotary knob 11, a first rotating plate arm 12 connected to the lower part of the knob 11 by a shaft, and a first magnetic body accommodated in the first rotating plate arm 12. (13). Rotating knob 11 is preferably located at the top of the device according to the invention, it is possible to install in a variety of forms, such as round or rod handle type. The user may operate the rotary knob 11 installed outside the housing 30 of the sealed structure to rotate the rotating body 31 accommodated inside the housing 30. The first rotating plate arm 12 is fixedly coupled to the lower portion of the shaft connected to the knob 11. Therefore, the first rotating plate arm 12 is simultaneously rotated in the same direction as the direction in which the user manipulates the knob 11. Part or all of the first magnetic body 13 is accommodated in the first plate arm. The first magnetic body 13 is formed of one or two magnets, which will be described in detail with reference to FIGS. 4 to 6 in which the manual rotary knob device for the present seal structure actually operates according to the arrangement of the magnets. The magnet may be partially accommodated in the first rotating plate arm 12 to be exposed, or the magnet may be completely accommodated in the plate arm 12. Thus, the strength of the magnetic force may be adjusted within a certain range. Can be. The appropriate degree of magnetic force should be determined according to the use of the manual rotary knob device for a closed structure according to the present invention. The magnet forming the first magnetic body 13 may use various types of magnets, but since it is important to arrange the magnetic poles of the upper and lower sides to be opposite, it may be preferable to install the magnets upright using a circular permanent magnet. In addition, the cover portion 10 may be configured in a form that is accommodated in a separate holder 14, except for the rotary knob 11 that the user must operate directly. This is because not only the wear protection of the apparatus, the ease of storage and transportation, but also the effects of interference and collision prevention by the user's finger, etc. can be brought about during the operation of the apparatus. In addition, by accommodating in the housing 14, it is possible to stably seat the lid 10 to the upper end of the housing 30 of the sealed structure.

The rotating part 20 is disposed spaced apart from the cover part 10 at a position corresponding to the first rotating plate arm 12 at the lower part of the cover part 10, and is disposed on the shaft with the internal rotating body 31. And a second magnetic plate 22 accommodated in the second rotating plate arm 21. The rotating part 20 is entirely formed in the housing 30 of the sealed structure. Inside the housing 30 is provided with an internal rotary body 31 for the user to rotate by operating the rotary knob 11, the internal rotary body 31 is a second rotary plate arm (through the shaft) ( 21, the second rotating plate arm 21 is rotated simultaneously in the same direction as the rotation direction. On the other hand, the second rotating plate arm 21 must be installed to be parallel to the first rotating plate arm 12 at the uppermost side in the housing 30, and the direction in which the second rotating plate arm 21 faces. Substantially corresponds to the direction in which the first rotating plate arm 12 faces. Part or all of the second magnetic body 22 is accommodated in the second plate arm. The second magnetic body 22 is formed of one magnet. Like the first magnetic body 13, the second magnetic body 22 is partially accommodated in the second rotating plate arm 21 to be exposed or the magnet is exposed to the plate arm ( 21) The strength of the magnetic force can be adjusted within a certain range through modification such as being accommodated inside. Since it is important to arrange the magnets forming the second magnetic body 22 so that the magnetic poles on the upper and lower sides thereof are opposite, it is preferable to install the magnets upright using a circular permanent magnet.

In addition, a rotation drive member 40 such as a motor is coupled to the shaft connecting the second rotation plate arm 21 and the internal rotating body 31 to not only manual rotation according to external force, but also the inside of the closed structure device itself. It is also possible to enable automatic rotation by driving at. As described above in the background art, a mechanism in which any air pressure is input and output by driving the internal rotating body 31 is generally required to rotate through an electric driving force.

Figure 4 is a front cross-sectional view of the manual rotation knob device for a sealed structure according to an embodiment of the present invention and a view showing a moving direction of the rotating plate arm.

Referring to FIG. 4, the first magnetic body 13 and the second magnetic body 22 are respectively provided such that one magnet faces the opposite magnetic poles, and the rotary knob 11 is operated to operate the first magnetic body 13. In this embodiment, the second magnetic body 22 also moves by the attraction force, thereby causing the internal rotor 31 to rotate.

For example, if the S pole of the first magnetic body 13 is disposed downward and the N pole of the second magnetic body 22 is upward, an attractive force is generated between the two magnetic bodies. Therefore, when the user operates the rotary knob 11, the first magnetic plate 22 connected to the knob 11 rotates together and the second magnetic body 22 is applied according to the attraction force with the first magnetic body 13 accommodated therein. Will move simultaneously. As the second rotating plate arm 21 accommodating the second magnetic body 22 moves, the internal rotating body 31 connected to the shaft also finally rotates. Since the driving is performed according to the pulling force generated between the two magnetic bodies, it is possible to operate the rotary knob 11 in any of the right and left directions, it is preferable to apply to the closed structure mechanism to rotate the internal rotor 31 in both directions. Do. In addition, when the manual rotary knob 11 is operated with a strong force, the phenomenon of separation between the magnets of both magnetic bodies may occur, so that the strength of the magnetic force of the magnets in accordance with the rotational force required for the internal rotor 31 It is necessary to adjust the process, the application of the structure is suitable when the torque of the rotor 31 is relatively weak.

Since the rest of the structure is the same as the above-described basic embodiment, the rest of the description will be omitted.

Figure 5 is a front sectional view of the manual rotation knob device for a closed structure according to another embodiment of the present invention and a view showing a moving direction of the rotating plate arm.

Referring to FIG. 5, each of the first magnetic body 13 and the second magnetic body 22 has one magnet, and the lower magnetic pole of the first magnetic body 13 and the upper magnetic pole of the second magnetic body 22 are the same. As the first magnetic body 13 is moved by operating the rotary knob 11, the second magnetic body 22 is pushed in the same direction as the moving direction of the first magnetic body 13 by repulsive force. The structure for causing the internal rotor 31 to rotate is the second embodiment.

For example, if the north pole of the first magnetic body 13 is disposed downward and the north pole of the second magnetic body 22 is disposed upward, repulsive force is generated between the two magnetic bodies. Accordingly, when the user operates the rotary knob 11, the first magnetic plate arm 12 connected with the knob 11 rotates together and the second magnetic body 22 is responsive to the first magnetic body 13 accommodated therein. Is moved in the same direction. As the second rotating plate arm 21 accommodating the second magnetic body 22 moves, the internal rotating body 31 connected to the shaft also finally rotates. Since the drive is driven according to the pushing force, not the pulling force between the two magnetic bodies, it is preferable to apply to the closed structure mechanism to rotate the rotary knob 11 in one direction only. However, the structure can be applied even when the torque of the rotor 31 is stronger than that in the structure of the first embodiment.

In addition, it is possible to further couple an elastic return member 23 such as a spring member to the second rotating plate arm 21. At this time, when the force acting on the rotary knob 11 disappears, the second rotary plate arm 21 is moved to a position opposite to the direction in which the user manipulates the rotary knob 11 by the elastic return member 23. On the contrary, the first magnetic body 13 is returned to its original position by the repulsive force with the second magnetic body 22. By using this principle, when the manual rotation knob 11 of the present invention is not used after being used, it will be possible to automatically return to the initial position.

6 is a cross-sectional view of the manual rotation knob device for a closed structure according to another embodiment of the present invention and a diagram showing the arrangement of the magnet.

Referring to FIG. 6, the first magnetic body 13 is provided in a form in which two magnets having the same direction of magnetic pole arrangement are spaced apart from each other at a predetermined interval, and the second magnetic body 22 has one magnet as the two magnets. The third embodiment has a structure in which the magnetic poles are located near the central axis of the two magnets, and the same magnetic poles as the lower magnetic poles of the first magnetic body 13 are positioned on the upper side.

For example, if both magnets of the first magnetic body 13 have the N pole facing downward and the N pole of the second magnetic body 22 facing upward, the user may move the rotatable knob 11. When the first rotary plate arm 12 connected to the knob 11 is rotated together, the second magnetic body 22 is pushed and moved in the same direction according to the repulsive force with the first magnetic body 13 accommodated therein. As the second rotating plate arm 21 accommodating the second magnetic body 22 moves, the internal rotating body 31 connected to the shaft also finally rotates. It is driven by the pushing force rather than the pulling force between the two magnetic bodies, but since the first magnetic body 13 is composed of two magnets spaced to both sides, the operation of the rotary knob 11 in either of the right and left directions is impossible. Thus, the present invention is also applicable to a closed structure device that requires the internal rotor 31 to rotate bidirectionally. In addition, even when the user does not operate the manual rotation knob 11 of the present invention, the position of the second magnetic body 22 is always located near the central axis of the two magnets of the first magnetic body 13, and both magnetic bodies The structure has the advantage of low probability of deviation of the alignment between the magnets. In addition, as can be seen in the direction of the magnetic force line shown in Figure 6, the attraction force between the central axis of the two magnets of the first magnetic body 13 and the central axis of the second magnetic body 22, the pulling force of both magnetic bodies Alternatively, it is possible to induce a stronger rotational force than in the case of the first and second embodiments operating only by the pushing force.

FIG. 7 is an exploded view of a portion of the manual rotating knob apparatus for a sealed structure actually manufactured according to the embodiment as shown in FIG. 6.

Referring to FIG. 7, the manual rotating knob apparatus for a sealed structure using a magnet manufactured in actuality was configured in the same manner as in the third embodiment. The remaining portion except for (11) is accommodated in a circular container 14. Two magnets are all accommodated in the first rotating plate arm 12 at predetermined intervals, and one magnet is partially accommodated in the second rotating plate arm 21 to expose an upper portion thereof. In addition, in the case of the actual product shown in FIG. 7, since only 90 degrees of bidirectional rotation is required, the stopper 15 of the cover portion 10 includes the stop plates 15 at both ends of the first plate arm. In other words, even if the rotary knob 11 is turned with a strong force, it is prevented from rotating over a predetermined section. At this time, the arrangement of the stop plate 15 can be modified depending on the use of the sealing structure mechanism and the required rotation range of the internal rotating body 31.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims should include all such modifications and changes as fall within the scope of the present invention.

10: cover 11: rotary knob
12 first rotating plate arm 13 first magnetic material
14: housing 15: stop plate
20: rotating portion 21: second rotating plate arm
22: second magnetic body 23: elastic return member
30 housing 31 internal rotating body
40: rotation drive member

Claims (6)

In the manual rotary knob device for a closed structure for operating a rotary knob located outside the housing of the closed structure, the rotating body accommodated in the housing,
A cover part including the rotatable knob, a first rotation plate arm axially connected to a lower portion of the knob, and a first magnetic body accommodated in the first rotation plate arm; And
A second rotating plate arm disposed at a position corresponding to the first rotating plate arm at a lower portion of the cover part and spaced apart from the cover part, the second rotating plate arm being connected to the internal rotating body by a shaft; Manual rotating knob device for a closed structure using a magnet, characterized in that it comprises a rotating portion containing a magnetic material.
The method of claim 1,
Manual rotating knob device for a closed structure using a magnet, characterized in that the rotating drive member is coupled to the shaft connected to the internal rotating body to enable automatic rotation.
The method of claim 1,
The first magnetic body and the second magnetic body are each provided with one magnet facing each other opposite magnetic poles,
The internal rotary body rotates as the second magnetic body moves by the attraction force as the first magnetic body is moved by operating the rotary knob.
The method of claim 1,
Each of the first magnetic body and the second magnetic body has one magnet installed such that the lower magnetic pole of the first magnetic body and the upper magnetic pole of the second magnetic body are the same.
As the first magnetic material is moved by operating the rotary knob, the second magnetic material is pushed in the same direction as the direction of movement of the first magnetic material by repulsive force, characterized in that the internal rotating body rotates. Structural manual rotary knob device.
5. The method of claim 4,
The second rotating plate arm is provided with an elastic return member so that when no force is applied to the rotating knob, the second rotating plate arm moves to a position opposite to the direction in which the user operates the rotating knob. And, while the first magnetic body is pushed by the repulsive force with the second magnetic body, the rotary knob automatically returns to the initial position.
The method of claim 1,
The first magnetic body is provided in a form in which two magnets having the same direction of magnetic pole arrangement are spaced laterally at predetermined intervals,
The second magnetic body is a manual rotation knob device for a closed structure, characterized in that one magnet is located near the central axis of the two magnets, the same magnetic pole of the lower magnetic pole of the first magnetic body is located on the upper side.

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