KR20090033595A - Magnification ratio control camera - Google Patents

Abstract

A magnification control camera is provided that the convenience is guaranteed without keeping the magnification control lens. A magnification control camera comprises a magnification control lens unit which automatically controls the magnification to the object material collecting image. The magnification control lens unit includes a lens unit(130) which moves the straight driving direction, a lens unit holder(120) which is combined with the lens unit, and an adjustment knob(110) which is penetrated toward the longitudinal direction. The outer circumference of the lens unit holder is combined in the inner circumference of the adjustment knob.

Description

Scale camera {MAGNIFICATION RATIO CONTROL CAMERA}

The present invention relates to a camera for outputting a captured image to a monitor, and to a magnification control camera capable of automatically adjusting the magnification without replacing the lens and adjusting the brightness of the light emitting diode.

The present invention has a wide range of applications that can be used as an industrial camera, but in the present specification, a skin camera generally used for skin diagnosis will be described as an example.

In general, the skin camera for diagnosing the skin is to enlarge the skin through the camera light is installed to measure the skin, and output the captured image to an output device such as a monitor to check the skin condition with the naked eye of the user The conventional skin camera is divided into a camera body and a lens unit screwed to the camera body, and is used while replacing a plurality of lenses having different magnifications as necessary, and the lens unit to be replaced has light emitting means as a light source. This was installed. Therefore, in order to apply power from the camera body to the light emitting means of the lens portion, a power supply means consisting of a leaf spring and a pin is provided. However, the frequent application of the lens portion causes the problem that the power applying means is broken or contact failure occurs. there was.

On the other hand, in the application number 20-2002-0021686 (Registration No. 20-0291667 "polarized skin diagnostic device", hereinafter referred to as "utility 1"), the light is reflected to a specific area of the skin by using polarized light to receive the reflected light By observing not only the outer surface of the skin but also in the skin to determine the condition of the skin and analyzing the discriminated information, it provides more accurate and convenient skin by providing information such as measures, treatment methods or cosmetics suitable for the user's skin. Provided 'practical 1' such as to manage.

In the 'Practice 1', the front and rear bodies of which the lens is configured can be separately assembled to replace the lens of various magnifications by adjusting the focus while moving the lens forward and backward. To make it possible. In other words, it is a way to adjust the focus while moving the lens in front and rear when photographing the subject using a general optical lens, and to adjust the magnification, the lens must be replaced by separating the body.

However, each time the lens was replaced, 'practical 1' should be removed from the skin, and then the lens should be replaced and photographed by touching the skin again. This was to find and photograph the area to be diagnosed accurately. Not only was it more inconvenient to visit, but the magnification did not match or frequent replacement of the lens was delayed and it was inconvenient from the user's point of view.

In addition, 'practical 1' is to use a plurality of lenses having different magnification, respectively, there was a problem in storage and management.

In addition, since the brightness of the light emitting diode is fixed, the problem is that the captured image is reduced when the reflected light or illuminance of the light emitting diode is too bright.

The present invention has been made to solve the problems of the prior art, the main object of the present invention is a camera for outputting the received image to the monitor, when the magnification adjustment to output the enlarged image is required without automatic replacement of the lens The purpose of the present invention is to provide a magnification control camera capable of controlling the magnification of the lens and taking a picture while adjusting the brightness of the light emitting diode.

In order to achieve the above object, the present invention is a magnification control camera, a camera that converts a received image into an electrical signal and outputs it to a monitor, the magnification of which can automatically adjust the magnification for the object to be collected. It is achieved by providing an adjustment lens unit, characterized in that it further comprises a CCD image processing device for converting the received image into an electrical signal.

Herein, the magnification adjusting lens part further includes a lens part moving in a linear traveling direction, and the magnification is adjusted by the lens part, and the magnification adjusting lens part is a lens part holder to which the lens part is coupled. And an adjustment knob through the longitudinal direction, wherein an outer circumferential surface of the lens unit holder is coupled to an inner circumferential surface of the adjustment knob, and the magnification is adjusted while the lens unit holder is moved in a linear traveling direction.

The magnification adjusting lens unit may further include support pins penetrating both ends of the lens unit holder, and the lens pin holder is moved up and down while being supported by the support pin.

On the other hand, the magnification adjustment lens unit, the adjustment knob is rotatably coupled to the inside through the longitudinal direction; A lens holder which is movably coupled to the inner circumference of the adjustment knob in a longitudinal direction, the central portion of which is penetrated in the longitudinal direction; An outer circumferential surface coupled to an inner circumferential surface of the lens unit holder, the lens unit having a lens therein; And a support pin through which the lens unit holder is formed in the longitudinal direction and fixed at one end and the other end thereof, wherein the adjustment knob of the magnification adjusting lens unit is prevented from sliding during rotation. A plurality of non-slip grooves are formed in the longitudinal direction.

In addition, at least two support pins of the magnification adjusting lens part may be formed.

On the other hand, the camera converts the received image into an electrical signal and outputs to a monitor, comprising: a plurality of light emitting diodes for supplying a light source having a constant illuminance on the surface of the object to be collected; And it is achieved by having a brightness control unit for adjusting the brightness of the plurality of light emitting diodes, wherein, further comprises a microcomputer, the brightness controller is characterized in that the operation of the control of the microcomputer.

In this case, the apparatus may further include a CCD image processing apparatus for converting the received image into an electrical signal.

According to the present invention described above, in the camera outputting the captured image to the monitor, it is possible to automatically adjust the magnification, and to prevent the phenomenon of reducing the image by the reflected light and brightness by adjusting the brightness of the light emitting diode In addition, since there is no inconvenience of having to store the magnification adjusting lens separately, it is easy to manage, and more accurate diagnosis can be performed, and thus the convenience of the user and the user (patient) can be achieved.

In addition, the present invention can be used in a variety of applications in the industrial field to enlarge the photographed subject to output to the monitor.

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

1 is an exploded perspective view of a scaling camera according to the present invention, Figure 2 is a combined perspective view of a scaling camera according to the present invention, Figure 3 is an exploded cross-sectional view of the scaling camera according to the present invention, Figure 4 is a present invention The combined cross-sectional view of the scaling camera according to.

As shown in Figures 1 to 4, the present invention, the scaling camera, in the camera converts the received image into an electrical signal and outputs to the monitor, automatically adjusts the magnification for the target object to collect the image It is provided with a magnification adjusting lens unit 100, and at this time, further comprises a CCD image processing device for converting the received image into an electrical signal. Here, the meaning of the automatic means that the lens knob 120 coupled to the inside of the adjustment knob 110 is rotated in a forward / reverse direction (manual operation) of the adjustment knob 110 to be described in a straight direction (length direction). It means to scale while moving to). In other words, the control knob 110 is manually operated, but the magnification can be adjusted without replacing the lens with a different magnification. In addition, as shown in Figures 1 to 2, the outer peripheral surface of the adjustment knob 110 is provided with a plurality of non-slip groove (H) to prevent sliding in the longitudinal direction.

On the other hand, the magnification control lens unit 100, the magnification is adjusted by the lens unit 130 which is moved in a linear advancing direction, wherein the magnification control lens unit 100, the lens unit 130 is coupled The lens unit holder 120 is coupled to the inner circumferential surface of the adjustment knob 110 which is apertured in the longitudinal direction, and is moved in a straight line direction to adjust the magnification. Herein, the lens coupled to the lens unit 130 uses an electronic lens instead of an optical lens as a zoom lens. As shown in FIG. 1 or FIGS. 3 to 4, the lens unit 130 and the lens unit holder ( The coupling of 120 is by screwing. That is, a male screw portion is formed at one outer circumference of the lens unit 130, and a female screw portion corresponding thereto is formed at one inner circumference of the lens unit holder 120 to be coupled to each other.

At least two support pin insertion holes 121 penetrating from one end to the other end (in the longitudinal direction) are formed at the edge of the lens unit holder 120. The support pin insertion holes 121 may be described below. Pin 140 is fitted. In addition, as shown in FIG. 1, a supporter hole 122 having a predetermined size is formed at the outer circumference of the lens unit holder 120 so that the supporter pins 123 are coupled thereto. It is preferable to combine so as to protrude a predetermined length when combining. As shown in enlarged in FIG. 4, a female screw portion is formed on an inner circumferential surface of the adjusting knob 110, and the supporter pin 123 couples the lens portion holder 120 to the female screw portion of the adjusting knob 110. At the same time, the lens unit holder 120 is moved up and down (straight traveling direction) along the female threaded portion of the adjustment knob 110. That is, the supporter pin 123 serves as a male screw part.

 In addition, the magnification adjusting lens unit 100 is moved up and down while the lens unit holder 120 is supported by the support pins 140 penetrating both ends of the lens unit holder 120. In order to move the lens holder 120 in a linear traveling direction during forward / reverse rotation of 110, the support pin 140 plays a role. That is, if there is no support, the lens unit holder 120 is rotated together at every forward / reverse rotation of the adjustment knob 110 and thus cannot move in a straight line direction. Thus, as shown in Figure 4, the support pin 140 is inserted into the support pin insertion hole 121 of the lens unit holder 120, the support pin fitting hole of the third body portion 30 to be described below ( One end is coupled to the 32, and the other end is coupled to the support pin coupling hole 42 of the fourth body portion 40 to be described below to serve as a support. In addition, the support pin serves as a connection line of the (+) / (-) terminal, which will be described below.

In addition, although not shown, a screw thread (male screw part) is formed on the outer circumferential surface of the lens unit holder 120 instead of the supporter hole 122 and the supporter pin 123, or the female screw part of the adjusting knob 110 is connected to the female screw part. The lens unit 130 may be manufactured to be sized to be coupled to the inner circumferential surface of the adjustment knob 110 and may be directly coupled to the inner circumferential surface of the adjustment knob 110 without being inserted into the lens unit holder 120. At this time, it is preferable to form a support pin insertion hole 121 through which one end of the other end is inserted into the lens holder 120 so that the support pin 140 is fitted. That is, the lens unit 130 and the lens unit holder 120 will be manufactured integrally.

On the other hand, the camera converts the received image into an electrical signal and outputs to a monitor, comprising: a plurality of light emitting diodes 211 for supplying a light source having a constant illuminance on the surface of the object to be collected; And a brightness adjusting unit 200 for adjusting brightness of the plurality of light emitting diodes 211, wherein the microcomputer 220 is further provided, and the brightness adjusting unit 200 controls the microcomputer 220. It works by First, the names of the parts illustrated in FIG. 1 or FIGS. 3 to 4 and the same will be described below.

First, the body portion in which the magnification adjusting lens part 100 and the brightness adjusting part 200 are installed is composed of first to fifth body parts 10, 20, 30, 40, and 50. A light emitting diode sensor, a CCD board, a DSP board, a microcomputer board, and a power board are embedded, and a plurality of control buttons 221 and a power input unit 222 are formed at one end of the microcomputer (the first body unit 10). One side of 220 is inserted and the other side is inserted into the second body 20. Here, the first body part 10 is formed by opening the other end, as shown in Figure 1, the control button fitting hole 11 and the power input unit fitting hole 12 of a predetermined size is formed at one end. And stepped on the other outer periphery is formed. In addition, the second body portion 20 is formed through the interior, one step is formed on one inner peripheral edge and the other outer peripheral edge, at least two coupling holes (CH) of a predetermined size is formed on one side.

In addition, the third body portion 30 is formed through the inside of the longitudinal hole, as shown in Figures 3 to 4, the first coupling step 31 having a support pin fitting hole 32 in the lower end inside ) Is formed.

In addition, the fourth body portion 40 is formed through the inner side in the longitudinal direction, as shown in Figure 1 or 3 to 4, the support pin coupling hole 42 and the fixing pin fitting hole in the lower end A second coupling step 41 having a 43 is formed, and one side of the outer circumferential surface of the fourth body portion 40 is formed to be opened to a predetermined size. In addition, the stepped portion is formed on the outer periphery of one side of the fourth body portion 40 and the other side is formed to taper toward the other end.

On the other hand, the fifth body portion 50 is formed through the inner side in the longitudinal direction, tapered toward the other side.

Looking at the coupling method of each component with reference to Figures 1 to 4 as follows.

1) Combine one side of the microcomputer 220 with the first body portion 10. (At this time, the control button 221 and the power input unit 222 is a control button fitting groove of the first body portion 10 ( 11) and a predetermined length is protruded and coupled to the power input fitting groove 12.)

2) The other side of the microcomputer 220 is inserted into the second body 20.

3) The stepped portion of the first body portion 10 is coupled to the stepped portion of the inner circumference of the second body portion 20.

4) The stepped portion of the outer circumference of the second body portion 20 is coupled to one side of the third body portion 30.

5) The light emitting diode board 210 is coupled to the other inner peripheral edge of the fourth body portion 40 and the board in the fixing pin fitting hole 43 of the second coupling step 41 of the fourth body portion 40 Combining the fixing pin (BP) is fixed to the light emitting diode board 210.

6) The lens unit 130 is coupled to the lens unit holder 120 and the supporter pin 123 is coupled to the supporter hole 122 of the lens unit holder 120 to protrude a predetermined length.

6) The lens unit holder 120 is coupled to the inner circumferential surface of the adjustment knob 110. (At this time, the supporter pin 123 coupled to protrude a predetermined length to the thread formed on the inner circumferential surface of the adjustment knob 110. Combined and moved in the longitudinal direction.)

7) The adjustment knob 110 coupled to the lens unit holder 120 is inserted into the fourth body portion 40. (At this time, the adjustment knob 110 is the second of the fourth body portion 40). It is supported by the engaging step 41.)

8) One end of the support pin 140 is inserted into the support pin coupling hole 42 of the second coupling step 41, and one side outer peripheral step of the fourth body part 40 is connected to the third body part. It is coupled to the other inner circumferential step of (30). (At this time, the other end of the support pin 140 is coupled to and fixed to the support pin fitting hole 32 of the first coupling step (31).)

9) Here, although not shown, the connecting line connected to the (+) / (-) terminal is connected to the other end of the support pin 140, the one end of the support pin 140, the light emitting the lower portion of the microcomputer 220 (-) / (+) Terminal of the diode board 210 is connected. (So, the support pin 140 serves as a support and at the same time (+) / (-) terminal connecting line.)

10) When the first to the fourth body portion 10, 20, 30, 40 is coupled as shown in Figure 1, by fixing the fixing screw (FV) in the coupling hole (CH), the coupling groove 44 It is preferable to form and combine each).

11) The fifth body portion 50 is coupled to the other inner circumference of the fourth body portion 40 (as shown in FIGS. 3 to 4, in the other side of the fourth body portion 40). A female screw portion is formed at the periphery and a male screw portion is formed at the outer periphery of one side of the fifth body portion 50 to be mutually coupled.)

12) Operate using the control button 221. (The control button 221 is provided with a power and a light emitting diode 211 brightness adjustment button.)

13) The magnification is adjusted by rotating the control knob 110 exposed to one side opening of the outer circumferential surface of the fourth body part 40 in the forward / reverse direction.

▶ The power input unit 222 is connected to a power line and a monitor connection terminal for applying power, although not shown.

While the present invention has been illustrated and described with respect to preferred embodiments, the invention is not limited to the above-described embodiments, and is commonly used in the field of the invention without departing from the spirit of the invention as claimed in the claims. Anyone with a variety of variations will be possible.

1 is an exploded perspective view of a scaling camera according to the present invention;

2 is a combined perspective view of a scaling camera according to the present invention;

3 is an exploded cross-sectional view of a scaling camera according to the present invention;

Figure 4 is a combined cross-sectional view of the scaling camera according to the present invention.

<Description of Symbols for Major Parts of Drawings>

10: first body part 11: control button insertion hole

12: power input hole

20: second body part

30: third body portion 31: the first coupling step

32: support plate fitting hole 33: groove

40: fourth body 41: second coupling step

42: support pin coupling hole 43: fixing plate fitting hole

44: coupling groove

50: fifth body part

100: magnification adjustment lens

110: adjusting knob 120: lens holder

121: support pin insertion hole 122: supporter hole

123: supporter pin

130 lens unit 140 support pin

200: brightness control

210: light emitting diode board 211: light emitting diode

212: board fixing hole

220: microcomputer 221: control button

222: power input unit

CH: Coupling Hole

FV: Fixing screw

BP: Board Fixing Pin

H: Non-slip groove

Claims (11)

In the camera converting the received image into an electrical signal and output to the monitor, Magnification camera characterized in that it comprises a magnification adjusting lens unit that can automatically adjust the magnification for the object to be collected. The method of claim 1, wherein the magnification adjusting lens unit, And a lens unit moved in a straight line direction, wherein the magnification is adjusted by the lens unit. The method of claim 2, wherein the magnification adjusting lens unit, The lens unit is further provided with a lens holder coupled to the lens unit and the adjustment knob through the longitudinal direction, the outer peripheral surface of the lens unit holder is coupled to the inner peripheral surface of the adjustment knob to adjust the magnification while the lens unit holder is moved in a straight line direction. Scale camera, characterized in that. The method of claim 3, wherein the magnification adjusting lens unit, And a support pin penetrating both ends of the lens unit holder, the lens unit holder being moved up and down while being supported by the support pin. In the camera converting the received image into an electrical signal and output to the monitor, A plurality of light emitting diodes for supplying a light source having a constant illuminance to the surface of the object to be collected; And Magnification control camera comprising a brightness control unit for adjusting the brightness of the plurality of light emitting diodes. The method of claim 5, further comprising a microcomputer, The brightness control unit is a magnification control camera, characterized in that to operate under the control of the microcomputer. The method according to claim 1 or 5, And a charge coupled device (CCD) image processing device for converting the received image into an electrical signal. The method according to claim 1 or 5, wherein the target object, Scale camera characterized in that the human skin. The method of claim 1, wherein the magnification adjusting lens unit, A control knob through which the inside is longitudinally rotated and rotatably coupled; A lens holder which is movably coupled to the inner circumference of the adjustment knob in a longitudinal direction, the central portion of which is penetrated in the longitudinal direction; An outer circumferential surface coupled to an inner circumferential surface of the lens unit holder, the lens unit having a lens therein; And A support pin through which the lens unit holder is formed in the longitudinal direction and fixed at one end and the other end; Scale camera, characterized in that consisting of. The adjustment knob of claim 9, wherein Magnification control camera characterized in that a plurality of non-slip grooves are formed in the longitudinal direction to prevent sliding during rotation. The support pin of claim 9, wherein At least two scaling cameras characterized in that formed.

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