KR101421438B1 - Knob for driving stand of microscope - Google Patents

Abstract

Disclosed is a knob for driving the stand of a microscope having a locking device for vertically driving the stand of a confocal microscope on which observation equipment is mounted and allowing the stand to drive in a specific direction as and when necessary. The knob for driving the stand of a microscope comprises a driving shaft rotating in clockwise and counterclockwise directions to vertically move the stand of the microscope, and a locking device for restricting the rotation of the driving shaft to make the stand of the microscope move upward. The locking device comprises a fixed roller guide separated from the driving shaft at a predetermined gap; rollers positioned in a space between the driving shaft and the fixed roller guide; a roller positioning part positioned between the driving shaft and the fixed roller guide to change the position of the rollers; and a switch part for rotating the roller positioning part. The space between the fixed roller guide and the driving shaft is formed of a separation space formed to freely rotate the rollers when the fixed roller guide and the driving shaft are separated from each other and a wedge space formed to fit the rollers when the space between the fixed roller guide and the driving shaft is narrowed. The rollers are positioned in the separation space or the wedge space by being pushed out from the space between the fixed roller guide and the driving shaft when the roller positioning part rotates.

Description

[0001] The present invention relates to a knob for driving a microscope,

The present invention relates to a microscope stand driving knob, and more particularly, to a microscope stand driving knob having a locking device for moving a stand of a confocal microscope equipped with observation equipment up and down, .

The microscope is a mechanism for enlarging and observing a sample. Conventionally, a conventional microscope for observing a sample with the naked eye is mainly used by using a lens barrel equipped with an objective lens and an eyepiece lens. In recent years, however, A digital microscope for mounting a digital camera (photodetector) and a display device together with an eyepiece portion or an eyepiece portion and obtaining an enlarged digital image of the sample is widely used. In addition, as a microscope for observing three-dimensional microstructures of cells, parts, and the like, a pinhole is provided on the path of light from the sample to the photodetector through the objective lens, and light passing through a specific cross- A confocal microscope for obtaining a stereoscopic image of a sample by observing the sample while moving the pinhole in parallel with the thickness direction of the sample is also developed and used .

1 is a view showing an external structure of a conventional confocal microscope. 1, a conventional confocal microscope includes a base 10 on which a sample is placed, a stationary stand 12 fixed to one side of the base 10, A movable stand 14 mounted to be movable up and down; a lens barrel 20 supported by the movable stand 14 and moving up and down together with the movable stand 14; An objective lens unit 22 mounted on the movable stand 14 to generate an enlarged image of the sample and a stand driving knob 16 for adjusting the height of the lens barrel unit 20 by moving the movable stand 14 up and down . An enlarged image of the sample obtained from the barrel unit 20 is displayed on a separate image display device (not shown) or transferred to a separate control unit. In such an electron microscope such as a confocal microscope or a digital microscope, various optical and electrical devices, including the objective lens section 22, are mounted on the lens barrel unit 20 according to the characteristics of the microscope, The weight of the phosphorus-containing unit 20 gradually increases. Therefore, in order to adjust the distance between the sample and the objective lens unit 22, a considerable amount of force is required to move the lens barrel unit 20 up and down (z-axis movement) A weight equalizing method has been used in which springs are provided on the fixed stand 12 and the movable stand 14 to reduce the influence of the weight of the lens barrel unit 20 when the lens barrel unit 20 is moved up and down See Patent Application 10-2013-0006871). However, even if the weight equalizing method is used, when the barrel unit 20 is moved in the vertical direction by rotating the stand driving knob 16, the weight (self weight) of the barrel unit 20 or the user's carelessness When the objective lens unit 22 of the barrel unit 20 and the sample placed on the base 10 collide with each other.

SUMMARY OF THE INVENTION An object of the present invention is to provide a microscope stand drive knob capable of driving a microscope stand up and down and, if necessary, driving only in an upward direction.

Another object of the present invention is to provide a microscope stand driving knob which can fix the barrel unit at a predetermined position so as to prevent the barrel unit from unintentionally falling due to the weight of the barrel unit or the user's carelessness.

It is still another object of the present invention to provide a microscope stand drive knob that can prevent the descent of a heavy barrel unit without using excessive force.

According to an aspect of the present invention, there is provided a microscope comprising: a drive shaft that rotates clockwise and counterclockwise to move a microscope stand in a vertical direction; And a locking device for restricting rotation of the driving shaft so that the microscope stand moves only in an upper direction, wherein the locking device comprises: (a) a fixed roller guide positioned at a predetermined distance from the driving shaft; (b) A roller positioned in the space between the driving shaft and the fixing roller guide, (c) a roller position adjusting unit positioned between the driving shaft and the fixing roller guide to change the position of the roller, and (d) Wherein a space between the fixing roller guide and the driving shaft is formed by a space between the fixing roller guide and the driving shaft so that the roller rotates freely and a space between the fixing roller guide and the driving shaft for fixing the roller, And the wedge space narrows. When the roller position adjusting unit is rotated, the fixing roller guide And the roller is pushed in the space between the drive shaft and the drive shaft so that the roller is positioned in the spaced space or wedge space.

The microscope stand driving knob according to the present invention drives the microscope stand up and down and, if necessary, the microscope stand is driven only in the upward direction, so that the barrel unit unintentionally descends due to the weight of the barrel unit or the user's carelessness Can be prevented. Further, the microscope stand driving knob according to the present invention can prevent the descent of the heavy barrel unit without using excessive force.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows an external structure of a conventional confocal microscope. Fig.
FIGS. 2A, 2B, and 2C are a front perspective view, a rear perspective view, and an inner rear perspective view, respectively, showing a structure of a microscope stand driving knob according to an embodiment of the present invention;
FIG. 3 is a cross-sectional view taken along the line AA in FIG. 2B, illustrating the structure and function of the locking device of the microscope stand driving knob according to the embodiment of the present invention.
FIG. 4 is a front view for explaining the structure and operation of a switch unit used in a microscope stand driving knob according to an embodiment of the present invention; FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The microscope stand driving knob 16 according to the present invention is for driving the microscope stand in the vertical direction and is mounted on the fixed stand 12 of the microscope as shown in Fig. And the movable stand 14 in the vertical direction. FIGS. 2A, 2B, and 2C are a front perspective view, a rear perspective view, and an inner rear perspective view, respectively, showing a structure of the microscope stand driving knob 16 according to an embodiment of the present invention. 2A to 2C, the microscope stand driving knob 16 according to the present invention includes a driving shaft 30 that rotates clockwise and counterclockwise to move the microscope stand in the vertical direction, And a lock device 40 for restricting the rotation of the drive shaft 30 so as to move only in the upward direction.

A gear 32 for transmitting the rotational force of the drive shaft 30 to the microscope stand 14 (see FIG. 1) and the lens barrel unit 20 is provided at one end of the drive shaft 30, A spur gear is mounted and another end 34 of the drive shaft 30 is fitted with a handle (not shown) for rotating the drive shaft 30. When the user rotates the handle in the clockwise direction or the counterclockwise direction and rotates the drive shaft 30 and the gear 32, the stand gears coupled with the gear 32 move in the vertical direction. The gear 32 and the microscope stand may be coupled through a weight equalization device as disclosed in Applicant's patent application 10-2013-0006871, the entire contents of which are incorporated herein by reference.

FIG. 3 is a cross-sectional view taken along the line AA of FIG. 2B, illustrating the structure and function of the locking device 40 of the microscope stand driving knob 16 according to an embodiment of the present invention. 3, A shows a state in which the locking device 40 is open, and B shows a state in which the locking device 40 is locked. As shown in FIGS. 2A to 2C and FIG. 3, the locking device 40 includes a fixing roller guide 50 positioned at a predetermined distance from the driving shaft 30, A roller position adjusting unit 70 positioned between the driving shaft 30 and the fixing roller guide 50 to change the position of the roller 60, And a switch unit 80 for rotating the roller position adjusting unit 70. 2B is a rear perspective view of the driving knob 16 excluding the switch unit 80 and FIG. 2C is a rear perspective view showing the fixing roller guide 50 and the switch unit 80. FIG.

3, the fixing roller guide 50 and the driving shaft 30 are spaced apart from each other by a predetermined distance, and a roller (not shown) is inserted into a space between the fixing roller guide 50 and the driving shaft 30 60 are located. The space between the fixing roller guide 50 and the driving shaft 30 is formed by a space 52 spaced apart from the driving roller 30 and the fixing roller guide 50 so that the roller 60 freely rotates, And a wedge space 54 in which the gap between the fixing roller guide 50 and the drive shaft 30 is narrowed so as to be fitted and fixed. The space between the fixing roller guide 50 and the driving shaft 30 is separated from the spacing space 52 in which the roller 60 freely rotates and the fixing roller guide 50 and the driving shaft 30, The distance between the rollers 60 gradually decreases to form the wedge space 54 in which the roller 60 can not rotate. As shown in FIGS. 2A, 2C and 3, the roller position adjusting portion 70 includes a movement guide 72 to which the roller 60 is rotatably fitted and the movement guide 72, And a movement guide fixing plate 74 that rotates in accordance with the operation of the unit 80. In this case, when the roller position adjusting unit 70, specifically, the movement guide fixing plate 74 is rotated, the movement guide 72 is moved in the space between the fixing roller guide 50 and the drive shaft 30, (60) to move the roller (60) into the spacing space (52) or the wedge space (54). The roller 60 is inserted into the wedge space 54 and serves as a wedge for rotating the drive shaft 30 in only one direction. For example, the roller 60 may have a width of 1 to 8, 1 to 4, and a movement guide 72 in which the roller 60 is inserted is also formed in the same number as the roller 60 (see FIG. 3).

Next, the operation of the microscope stand drive knob 16 according to the present invention will be described with reference to Figs. 2A to 2C and Fig. The roller 60 is positioned in the spacing space 52 between the fixing roller guide 50 and the driving shaft 30 in a state in which the locking device 40 is open The drive shaft 30 rotates freely in a clockwise or counterclockwise direction without being influenced by the roller 60 because the roller 60 freely rotates in the drive shaft 52. [ Therefore, by rotating the drive shaft 30 clockwise or counterclockwise, the lens barrel unit 20 and the movable stand 14 can freely move in the vertical direction. In this state, when the user rotates the switch portion 80 in the counterclockwise direction and rotates the roller position adjusting portion 70 clockwise (see the arrow in FIG. 2A) The inserted roller 60 moves from the spacing space 52 between the fixing roller guide 50 and the drive shaft 30 to the wedge space 54 and the gap between the fixing roller guide 50 and the driving shaft 30 (Fig. 3B). When the drive shaft 30 is turned clockwise in a state where the roller 60 is sandwiched between the fixed roller guide 50 and the drive shaft 30, the wedge is inserted into the fixed roller guide 50 The roller 60 is more strongly fitted between the drive shafts 30 and the clockwise rotation of the drive shaft 30 is suppressed. When the drive shaft 30 is rotated in the counterclockwise direction, even if the roller 60 is positioned in the wedge space 54, the wedge is pulled out, that is, The driving shaft 30 can rotate freely in a counterclockwise direction because the roller 60 moves or rotates in a direction in which a space between the driving shaft 30 and the driving shaft 30 is widened. Thus, by positioning the roller 60 in the spacing space 52 or the wedge space 54, the user can freely rotate the drive shaft 30 clockwise or counterclockwise, . Thus, with the locking device 40 open (A, unlocked state of FIG. 3), the microscope stand drive knob 16 is freely rotatable in both directions. 3), the drive knob 16 can rotate only in the counterclockwise direction, so that the drive knob 16 is rotated in the counterclockwise direction, The distance between the objective lens 22 and the sample can be adjusted to be large, but the objective lens 22 can not be moved in the opposite direction. 3B), when the user rotates the switch unit 80 in the clockwise direction, the roller 60 is rotated in the opposite direction to the above-described state, The drive shaft 30 moves freely in the clockwise or counterclockwise direction from the wedge space 54 between the drive shaft 30 and the spacing space 52 (FIG. 3A).

Next, an example of the structure of the switch unit 80 for rotating the roller position adjusting unit 70 will be described. 4 is a front view for explaining the structure and operation of the switch unit 80 used in the microscope stand drive knob 16 according to an embodiment of the present invention. In Fig. 4, A shows a state in which the locking device 40 is open, and B shows a state in which the locking device 40 is locked. 2A and 4, the switch unit 80 is rotatably coupled to one end of the fixed roller guide 50 through a rotary shaft 82a, and one end of the switch unit 80 is connected to the roller position adjusting unit 70, A rotary plate 84 coupled to the other end of the lever 82 to rotate the lever 82 and a rotary plate 84 coupled to the rotary plate 84, And an adjustment switch 86 for rotating the switch 84. It is preferable that the adjustment switch 86 is formed with a recessed portion 86a on the outer circumferential surface so as to be easily grasped by the user. Since the lever 82 is coupled to the fixing roller guide 50 through the rotating shaft 82a, the rotational movement of the adjusting switch 86 and the rotating plate 84 is performed through the lever movement of the lever 82, And is transmitted to the roller position adjusting unit 70. A rotary plate guide 84a for limiting a movement locus of the rotary plate 84 is formed at one end of the rotary plate 84. A rotary plate guide protrusion 56 is formed on the fixing roller guide 50, The movement locus of the rotary plate 84 relative to the fixed roller guide 50 can be limited by moving the rotary plate guide protrusion 56 inserted in the rotary plate guide 84a.

The operation of the switch unit 80 will be described with reference to Figs. When the lock switch 40 is open (FIG. 4A), when the control switch 86 is rotated counterclockwise, the rotary plate 84 is also rotated counterclockwise along the control switch 86 , The lever 82 also rotates counterclockwise about the rotary shaft 82a. Therefore, the roller position adjusting unit 70 coupled to one end of the lever 82 rotates in the clockwise direction, thereby switching the locking device 40 to the locked state (FIG. 4B, FIG. 2A). 4, the moving direction of the roller 60 can be changed according to the shape of the rotary plate guide 84a and the lever 82 formed on the rotary plate 84 . 4, when the rotary plate guide 84a and the lever 82 are formed, the roller 60 moves from the spacing space 52 to the wedge space 54 in the clockwise direction, The rotation of the drive shaft 30 in the clockwise direction can be prevented (see Fig. 3).

On the other hand, if the shape of the lever 82 is reversed and the shape of the rotary plate guide 84a is changed so that the roller position adjuster 70 rotates in the counterclockwise direction, The roller 60 moves to the wedge space 54 in the clockwise direction (see FIG. 3) to prevent the rotation of the drive shaft 30 in the counterclockwise direction in the locked state, and to allow the clockwise rotation. Therefore, in the locked state, the rotation direction of the drive shaft 30 can be appropriately changed according to the drive mechanism of the stand and the like.

The microscope stand driving knob according to the present invention can be used not only by turning the knob of the locking device 40 by the force and locking the locking device 40 but by using the switch part 80, 60, the locking device 40 is locked in a wedge manner. Therefore, in the microscope stand drive knob according to the present invention, the downward movement of the heavy barrel unit 20 can be prevented without applying excessive force. The microscope stand driving knob according to the present invention is particularly useful for driving the barrel unit 20 of a confocal microscope in which the weight of the barrel unit 20 is heavy.

Claims (6)

A drive shaft that rotates clockwise and counterclockwise to move the microscope stand vertically; And a locking device for restricting rotation of the driving shaft so that the microscope stand moves only in an upward direction,
(B) a roller located in a space between the drive shaft and the fixed roller guide, (c) a roller disposed between the drive shaft and the fixed roller guide, And (d) a switch unit for rotating the roller position adjusting unit, wherein the roller position adjusting unit adjusts the position of the roller,
The space between the fixed roller guide and the drive shaft is formed by a spaced space in which the fixed roller guide and the drive shaft are separated from each other so that the roller is freely rotatable and a wedge space in which the interval between the fixed roller guide and the drive shaft is narrowed Wherein when the roller positioning portion is rotated, the roller is pushed in the space between the fixing roller guide and the driving shaft to position the roller in the spacing space or the wedge space. The microscope stand driving knob according to claim 1, wherein a gear for transmitting the rotational force of the drive shaft to the microscope stand and the lens barrel unit is mounted to one end of the drive shaft, and a handle for rotating the drive shaft is mounted to the other end of the drive shaft. . The method according to claim 1, wherein the space between the fixed roller guide and the drive shaft gradually decreases from the spacing space in which the roller freely rotates, between the fixed roller guide and the drive shaft, Thereby forming a wedge space. The microscope stand driving knob as set forth in claim 1, wherein the roller position adjusting portion comprises a movement guide in which the roller is rotatably fitted, and a movement guide fixing plate mounted with the movement guide and rotating according to an operation of the switch portion. [5] The apparatus according to claim 4, wherein the switch unit comprises: a lever rotatably coupled to one end of the fixed roller guide through a rotating shaft, one end of which is coupled to the moving guide fixing plate of the roller position adjusting unit, And a control switch coupled to the rotation plate to rotate the rotation plate. [6] The apparatus according to claim 5, wherein a rotary plate guide for limiting the movement locus of the rotary plate is formed at one end of the rotary plate, the rotary plate guide protrusion is formed on the fixed roller guide, , And limits the movement trajectory of the rotary plate (84) relative to the fixed roller guide.

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