KR200494302Y1 - Digital microscope - Google Patents

Abstract

The disclosed digital microscope includes a microscope body having an image sensor, a connecting cable for energably connecting to a computer, and a pair of main body-side terminals energably connected to the connecting cable, and detachably from the microscope body At least one LED for projecting light to the subject, a pair of module-side terminals energably connected to the at least one LED, and at least one lens for expanding and focusing the image of the subject on the image sensor An objective lens module is provided. A pair of main body-side terminals and a pair of terminals among the pair of module-side terminals are a pair of annular terminals spaced apart from each other in a concentric circle shape, and the other pair of terminals are elastically biased in a protruding direction and spaced apart from each other. It is a pair of protruding terminals. When the objective lens module is coupled to the microscope body, the pair of module-side terminals are energably attached to the pair of body-side terminals.

Description

Digital microscope

The present invention relates to a digital microscope connected to a computer and used so that an enlarged image of a subject can be viewed through a computer monitor.

A microscope is an instrument used to magnify objects that are too small to be seen with the naked eye. Recently, a digital microscope has been developed that does not look at a subject through an eyepiece, but takes an image magnified with an image sensor like a digital camera and sees the magnified object through a computer monitor. Korean Utility Model Publication No. 20-0294068 discloses an example of a digital microscope.

In the case of the digital microscope, one of the objective lenses of various magnifications may be selected and installed in the microscope body, and the LED lighting device is configured to be coupled thereto. However, the configuration in which the objective lens is detachably coupled to the microscope body is not clearly disclosed, and when the objective lens is coupled to the microscope body, it is also possible to determine how power can be supplied to the LED lighting device coupled to the objective lens. none. In addition, since the brightness of the LED cannot be adjusted, it is difficult to see a subject clearly with an appropriate brightness.

Republic of Korea Registered Utility Model Publication No. 20-0294068

The present invention is a digital microscope having at least one lens and an objective lens module having an LED embedded therein, and as long as the objective lens module is detachably coupled to the microscope body, power can be supplied to the LED. Provided is a digital microscope in which a terminal and a terminal of the objective lens module are in reliable contact.

The present invention provides a digital microscope that can control the brightness of the LED.

The present invention provides an image sensor, a connecting cable for energizingly connecting to a computer, and a pair of main body-side terminals energably connected to the connecting cable A microscope body including and an objective lens module having at least one lens that allows the image of the subject to be enlarged and focused on the image sensor, and the pair of main body-side terminals And, among the pair of module-side terminals, one pair of terminals is a pair of annular terminals spaced apart from each other in a concentric circle shape, and the other pair of terminals are elastically biased in a protruding direction and spaced apart from each other. Provided is a digital microscope in which a pair of protrusion-type terminals are provided, and when the objective lens module is coupled to the microscope body, the pair of module-side terminals are in close contact with the pair of body-side terminals so as to be energized.

The microscope body further includes a body housing in which the image sensor is installed, and the objective lens module further includes a module housing in which the at least one LED and the at least one lens are installed, the body housing and a male screw pattern is formed in one of the module housings, and a female screw pattern that meshes with the male screw pattern is formed in the other one, and the module housing is aligned with the main body housing and brought into contact with the main body When the housing is rotated in one direction, the male screw pattern and the female screw pattern are engaged, so that the objective lens module can be detachably coupled to the microscope body.

The main body housing includes a movable barrel detachably coupled to the module housing, and a tubular dial disposed to overlap the outside of the movable barrel, wherein the tubular dial is disposed with respect to the movable barrel. As it rotates, the moving barrel may move in a direction away from the image sensor and in the opposite direction.

The pair of main body-side terminals are protrusion-type terminals, the pair of module-side terminals are annular terminals, and the microscope body includes a main body housing in which the pair of protruding terminals are exposed to the outside, the pair A pair of protruding terminal coupling bolts each having a body energably coupled to the protruding terminal of A pair of bolt-connected printed circuit boards (PCBs) respectively energably fixed to the coupling bolts and energably connected to the connection cable, and the pair of protruding terminals, respectively, in a direction protruding to the outside of the main body housing Further comprising a pair of springs that elastically pressurize, when the objective lens module is separated from the microscope body, the head of the pair of protruding terminal coupling bolts and the pair of bolt connection PCBs are connected to the body housing may not protrude so that the pair of protrusion-type terminals are separated from the main body housing.

The pair of body-side terminals is a protrusion terminal, the pair of module-side terminals are annular terminals, and the objective lens module includes a module housing in which the pair of annular terminals are exposed to the outside, the module housing A first module PCB disposed on the inner surface of the module housing, and a pair of annular terminal coupling bolts for energably connecting the pair of annular terminals and the first module PCB so as not to be exposed to the outside of the module housing have.

The objective lens module supports a second module PCB disposed between the first module PCB and the at least one LED in the module housing, and the second module PCB, and the first module PCB and the second module PCB A pair of connecting pins (pins) for energably connecting the , may be further provided, and the terminal of the at least one LED may be energably bonded and fixed to the second module PCB.

The microscope body includes a variable resistance module energably connected to the connection cable and the pair of main body-side terminals, and a resistance adjustment knob coupled to the variable resistance module to change a resistance value of the variable resistance module. (knob) is further provided, and when the resistance adjustment knob is rotated, the size of the resistance value of the variable resistance module is changed to change the luminance of the at least one LED.

In the digital microscope of the present invention, as long as the objective lens module is detachably coupled to the microscope body, the main body side terminal of the microscope body and the module side terminal of the objective lens module are provided so that power can be supplied to the LED of the objective lens module Reliable contact, on the contrary, as long as the objective lens module is separated from the microscope body, the main body side terminal and the module side terminal are non-conductive apart. Therefore, the use of a digital microscope is convenient.

Digital microscope according to a preferred embodiment of the present invention having a variable resistance module and a resistance adjustment knob, by rotating the resistance adjustment knob to properly adjust the brightness of the LED, it is possible to observe the subject clearly with an appropriate brightness. .

1 and 2 are perspective views of a digital microscope according to an embodiment of the present invention, wherein FIG. 1 is a view viewed from above, and FIG. 2 is a view viewed from below.
3 is a cross-sectional view of a digital microscope according to an embodiment of the present invention.
FIG. 4 is an enlarged view of a portion IV of FIG. 3 .
5 is a side view illustrating a state in which a digital microscope is fixed to a cradle according to an embodiment of the present invention.

Hereinafter, a digital microscope according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The terms (terminology) used in this specification are terms used to properly express preferred embodiments of the present invention, which may vary depending on the intention of a user or operator or customs in the field to which the present invention belongs. Accordingly, definitions of these terms should be made based on the content throughout this specification.

1 and 2 are perspective views of a digital microscope according to an embodiment of the present invention, wherein Fig. 1 is a view viewed from above, Fig. 2 is a view viewed from below, and Fig. 3 is a cross-sectional view of a digital microscope according to an embodiment of the present invention. 4 is an enlarged view of the IV part of FIG. 3 , and FIG. 5 is a side view illustrating the digital microscope fixed to the cradle according to an embodiment of the present invention. 1 to 5 together, the digital microscope 10 according to an embodiment of the present invention constitutes a microscope set (1) together with a holder (2) supporting the digital microscope (10).

The digital microscope 10 includes a microscope body 11 and an objective lens module 70 detachably coupled to the microscope body 11 . The microscope body 11 includes a body housing 12 , an image sensor module 60 , a connection cable 66 , and first and second body-side terminals 40 and 50 . do. The body housing 12 includes an intermediate cylinder 16 having a stepped locking protrusion 17 formed on its outer peripheral surface so as to be supported by hanging from the cradle 2, and a cap fixedly coupled to the upper end of the intermediate cylinder 16. ) (13), a cylinder-shaped fixed barrel 20 fixedly coupled to the lower end of the intermediate cylinder 16, and a cylinder-shaped movable barrel arranged to overlap inside the fixed barrel 20 ( 23), a tubular dial (18) disposed to overlap the outside of the movable barrel (23) and the fixed barrel (20), and the movable barrel (23) are fixedly coupled to the lower inner surface of the barrel (23) and a lower end closing member 27 in the shape of a disk. The fixed barrel 20 , the movable barrel 23 , and the tubular dial 18 are arranged on concentric circles about the axis AX of the digital microscope 10 .

The movable barrel 23 has a coupling protrusion 24 protruding in the radial direction of the axis line AX on its outer peripheral surface. A plurality of guide slots 21 extending parallel to the axis line AX and penetrating the inner and outer circumferential surfaces of the fixed barrel 20 are formed in the fixed barrel 20 . The plurality of connecting protrusions 24 are fitted one by one into the plurality of guide slots 21 . A plurality of spiral grooves 19 extending along a spiral orbit are formed on the inner circumferential surface of the tubular dial 18 . Ends of the plurality of connecting protrusions 24 pass through the plurality of guide slots 21 and are fitted into the plurality of spiral grooves 19 one by one.

With this configuration, when the user of the digital microscope 10 rotates the tubular dial 18 about the axis AX, the movable barrel 23 moves with respect to the fixed barrel 20 according to the rotation direction. It moves in the protruding direction, that is, it moves downward, or it moves in the retracted direction, that is, it moves upward. The distance the moving barrel 23 moves downward or upward is proportional to the rotation angle of the tubular dial 18 . When the movable barrel 23 moves in a direction in which it protrudes with respect to the fixed barrel 20, it moves away from the image sensor 61 to be described later, resulting in a zoom-in effect in which the subject is enlarged close, and vice versa. When the movable barrel 23 moves in a contracting direction with respect to the fixed barrel 20 , it approaches the image sensor 61 , thereby causing a zoom-out effect in which the subject moves away and appears smaller.

The image sensor module 60 is installed inside the main body housing 12 , specifically, inside the intermediate cylinder 16 . The image sensor module 60 includes an image sensor 61 disposed on the axis AX, and an image sensor printed circuit board (PCB) 62 on which the image sensor 61 is energably mounted. do. When an image of a subject (not shown) placed under the digital microscope 10 is formed on the image sensor 60 , an electrical signal corresponding to the image of the subject from the image sensor 61 , that is, an image signal is created

The connecting cable 66 is for connecting to a computer so as to be energized, and one end is fixed to a cable adapter 65 installed in the cap 13 . Although not shown, the connection cable 66 may include a USB port at the other end. The image signal generated by the image sensor 61 is transmitted to the computer through the connection cable 66 through a wired communication method, and an image corresponding to the image signal is displayed on the monitor of the computer. In addition, power (not shown) for turning on the plurality of LEDs 96 of the objective lens module 70 is supplied from the computer to the digital microscope 10 through the connection cable 66 .

A variable resistance module 63 operably connected to the cable adapter 65 and the first and second body-side terminals 40 and 50 is installed inside the cap 13 , and A resistance adjusting knob 64 protruding to the outside is coupled to the rotating protrusion provided in the variable resistance module 63 . When the user of the digital microscope 10 holds and turns the resistance adjustment knob 64 , the size of the resistance value of the variable resistance module 63 may be changed. When the objective lens module 70 is coupled to the microscope body 11 , the variable resistance module 63 is electrically connected to the connection cable 66 and a plurality of LEDs 96 to be described later. Accordingly, when the resistance adjustment knob 64 is rotated by the user, the size of the resistance value of the variable resistance module 63 is changed so that the luminance of the light projected from the plurality of LEDs 96 is increased. is changed As such, the user can properly adjust the luminance of the plurality of LEDs 96 by rotating the resistance adjustment knob 64, so that a subject (not shown) can be clearly observed with appropriate brightness.

A hollow 28 extending along the axis AX is formed in the center of the lower closing member 27 , and an IR filter 59 is installed to close the hollow 28 . The IR filter 59 is a filter that blocks infrared rays from being incident on the image sensor 61 .

As described above, the first and second main body-side terminals 40 and 50 are electrically connected to the connection cable 66 , and are installed on the lower end closing member 27 to be spaced apart from each other. The first and second body-side terminals 40 and 50 are respectively installed on the lower closure member 27 to be exposed to the outside, specifically downward, of the lower closure member 27, and are disposed in a downwardly protruding direction. It is a protruding terminal with an elastic bias. The first and second body-side terminals 40 and 50 are elastically protruded downwards and are energably connected to the connecting cable 66, so that the microscope body 11 is coupled to the first and second protruding terminal bolts (bolts). ) 46 , 56 , first and second bolted connection PCBs 47 , 57 , and first and second springs 45 , 55 .

First and second terminal installation through-holes 30 and 35 penetrating the lower end closing member 27 in the thickness direction so that the first and second main body side terminals 40 and 50 are installed in the lower closing member 27 . ) is formed. Each of the terminal mounting through-holes 30 and 35 has lower inner diameter portions 31 and 36 having relatively large inner diameters and upper inner diameter portions 32 and 37 having relatively small inner diameters. A stepped stepped surface is formed between the lower inner diameter portions 31 and 36 and the upper inner diameter portions 32 and 37 due to the inner diameter difference.

The first and second body-side terminals 40 and 50 are formed of, for example, a metal material such as copper (Cu) or a copper alloy, and have substantially cylindrical lower ends fitted to the lower inner diameter portions 31 and 36, respectively. 41 , 51 , and upper ends 42 and 52 having a substantially cylindrical shape having a smaller diameter than the lower ends 41 and 51 . The upper end portions 42 and 52 are fitted to the upper inner diameter portions 32 and 37, but the lower portions 41 and 51 have a diameter greater than the inner diameter of the upper inner diameter portions 32 and 27, so that the upper inner diameter portion ( 32, 37) cannot be fitted. A stepped surface is formed between the upper end portions 42 and 52 and the lower end portions 41 and 51 due to a difference in diameter. A female screw pattern is formed on the inner circumferential surface of the upper end portions 42 and 52 .

The first and second protruding terminal coupling bolts 46 and 56 are formed of a metal material, and have heads 46a and 56a and bodies 46b and 56b, respectively. A male screw pattern that meshes with the female screw pattern of the inner peripheral surfaces of the upper ends 42 and 52 of the first and second body-side terminals 40 and 50 is formed on the bodies 46b and 56b. The body (46b, 56b) is connected to the upper end (42, 52) of the first and second body-side terminals (40, 50) through the upper inner diameter portion (32, 37) from the upper side of the lower closing member (27). It is inserted and fastened to the upper ends (42, 52). Accordingly, the first and second protruding terminal coupling bolts 46 and 56 are energably coupled to the first and second protruding terminals 40 and 50 .

The heads 46a and 56a of the first and second protruding terminal coupling bolts 46 and 56 have a larger diameter than the inner diameter of the upper inner diameter portions 32 and 37, and are inserted into the upper inner diameter portions 32 and 37. The inner side of the main body housing 12, specifically, the upper side of the lower closing member 27 protrudes. The first and second bolt connection PCBs 47 and 57 are energably fixed to the first and second protruding terminal coupling bolts 46 and 56, respectively, and are energably connected to the connection cable 66, respectively. In other words, the first and second bolt connection PCBs 47 and 57 are threaded and fixed to the first and second protruding terminal coupling bolts 46 and 56, and the first and second protruding terminal coupling bolts The heads 46a and 56a of (46, 56) and the terminals (not shown) of the first and second bolt connection PCBs 47 and 57 are kept in contact so as not to be spaced apart from each other.

The first and second springs 45 and 55 are inserted into the first and second terminal installation through-holes 30 and 35 to connect the first and second protruding terminals 40 and 50 to the outside of the body housing 12, Specifically, it elastically presses in a direction to protrude downward of the lower end closing member 27 . Specifically, the upper ends of the first and second springs 45 and 55 are supported on the stepped surface between the lower inner diameter portions 31 and 36 and the upper inner diameter portions 32 and 37, and the first and second springs The lower ends of (45, 55) are supported on the stepped surface between the upper ends (42, 52) and the lower ends (41, 51).

When the objective lens module 70 is separated from the microscope body 11, it is elastically pressed by the first and second springs 45 and 55 so that the first and second protruding terminals 40 and 50 The lower ends 41 , 51 project below the lower closure member 27 . However, the heads 46a and 56a of the first and second protruding terminal coupling bolts 46 and 56 and the first and second bolt connection PCBs 47 and 57 are formed through the first and second terminal installation through holes 30 . The first and second protruding terminals 40 and 50 do not protrude so as to be separated from the main body housing 12 . In other words, the heads 46a and 56a and the first and second bolt connection PCBs 47 and 57 serve as stoppers to prevent excessive protrusion of the first and second protruding terminals 40 and 50 . .

The objective lens module 70 includes a module housing 71 , a lens assembly 92 , a plurality of LEDs 96 , a diffusion plate 98 , and first and second module-side terminals 81 and 82 . to provide The module housing 71 includes a first module housing member 72 in the shape of a ring inclined to decrease in diameter as it goes down, a second module housing member 75 in the shape of a pipe having a constant diameter, and the second A disk-shaped top closing member 78 fixedly coupled to the top inner surface of the module housing member 75 is provided.

A female screw pattern is formed on an upper inner peripheral surface of the first module housing member 72 , and a male screw meshing with the female screw pattern of the first module housing member 72 is formed on an outer peripheral surface of the second module housing member 75 . A pattern is formed. Accordingly, the upper end of the first module housing member 72 is aligned with the lower end of the second module housing member 75 and the first module housing member 72 is pressed against the second module housing member 75 . direction, the first module housing member 72 is detachably coupled to the second module housing member 75 while the female screw pattern and the male screw pattern are engaged.

A male screw pattern 76 is formed on the upper outer peripheral surface of the second module housing member 75 , and a female screw pattern 25 that meshes with the male screw pattern 76 is formed on the lower inner peripheral surface of the movable barrel 23 . is formed Accordingly, the lower end of the movable barrel 23 and the upper end of the second module housing member 75 are aligned in a line along the axis AX and brought into contact, and the module housing 71 is attached to the main body housing 12 . When rotated in one direction, the male screw pattern 76 and the female screw pattern 25 are engaged, and the objective lens module 70 is detachably coupled to the microscope body 11 . On the other hand, unlike the embodiment of the present invention shown in FIGS. 1 to 3 , a male screw pattern may be formed in the main body housing 12 and a female screw pattern corresponding to the male screw pattern may be formed in the module housing 71 . have.

The lens assembly 92 is installed inside the module housing 71 . Specifically, a hollow 79 extending along the axis AX is formed in the center of the upper closing member 78 , and the lens assembly 92 is fitted to the inner circumferential surface of the hollow 79 . The lens assembly 92 includes a plurality of lenses arranged in a line along the axis AX, a barrel in which the plurality of lenses are supported on an inner circumferential surface, and a plurality of retainers for maintaining a constant distance between the plurality of lenses. (retainer) is provided. The outer circumferential surface of the barrel is fixedly coupled to the inner circumferential surface of the hollow 79 . The plurality of lenses are arranged so that an image of a subject (not shown) placed under the digital microscope 10, specifically, under the objective lens module 70, is enlarged and formed on the image sensor 61 at a preset magnification. do.

The magnification of the lens assembly 92 may vary according to the number, type, arrangement order, and spacing of the plurality of lenses. A user of the digital microscope 10 is provided with a plurality of objective lens modules 70 provided with lens assemblies 92 having different magnifications, and a lens assembly 92 of optimal magnification for observing a subject. One provided objective lens module 70 may be selected and coupled to the microscope body 11 . For example, the magnification of the lens assembly 92 may be 250 times, 500 times, or 1000 times.

The plurality of LEDs 96 project light onto the subject so that the subject (not shown) placed under the objective lens module 70 can be seen brightly and clearly. A plurality of LEDs 96 are disposed around the lower end of the lens assembly 92 inside the module housing 71 . The diffusion plate 98 is an annular member in which a through hole is formed on the axis AX, and is made of, for example, a transparent plastic such as an acrylic resin. The diffusion plate 98 is fixedly supported on the inner peripheral surface of the lower end of the first module housing member 72 . Light projected from the plurality of LEDs 96 is diffused while passing through the diffusion plate 98 , and is uniformly emitted through the entire area of the diffusion plate 98 , and It is not emitted because it is concentrated in some areas.

The first and second module-side terminals 81 and 82 are a pair of annular terminals spaced apart from each other in a concentric circle shape centered on the axis AX, for example, copper (Cu) or copper alloy. It is formed of a metal material. The first and second module-side terminals 81 and 82 are fixedly installed on the top closing member 78 so as to be exposed to the outside of the module housing 71 , specifically, to be exposed to the upper side of the top closing member 78 . do. The first and second module-side terminals 81 and 82 are electrically connected to the plurality of LEDs 96 .

In other words, the first module PCB 86 is disposed on the inner surface of the module housing 71, specifically, on the lower surface of the top closing member 78, and a pair of annular terminal coupling bolts (not shown) formed of a metal material. ) connects the first and second annular terminals 81 and 82 and the first module PCB 86 so as to be energized. The first module PCB 86 is formed in an annular shape so that the lens assembly 92 passes therethrough. The body of one of the pair of annular terminal coupling bolts extends parallel to the axis line AX and passes through the first module PCB 86 and the top closing member 78 and is fastened to the first annular terminal 81 The body of the other one of the pair of annular terminal coupling bolts extends parallel to the axis line AX and penetrates the first module PCB 86 and the top closing member 78 to penetrate the second annular terminal 82 is signed on

A male screw pattern is formed on the outer peripheral surface of the body of the pair of annular terminal coupling bolts, respectively, and the body of the pair of annular terminal coupling bolts is fitted on lower surfaces of the first and second annular terminals 81 and 82 A bolt fastening groove is formed, and a female screw pattern engaged with the male screw pattern of the pair of annular terminal coupling bolts is formed on an inner circumferential surface of the bolt fastening groove. However, the body of the pair of annular terminal coupling bolts is not exposed to the outside of the module housing 71 through the first and second annular terminals 81 and 82 .

The first module PCB 86 has a first terminal and a second terminal spaced apart from each other. The head of the one annular terminal coupling bolt is in close contact with the first terminal (not shown) of the first module PCB 86 , and the head of the other annular terminal coupling bolt is the head of the first module PCB 86 . It is in close contact with the second terminal.

A second module PCB 88 is disposed between the first module PCB 86 and the plurality of LEDs 96 inside the module housing 71 . Like the first module PCB 86 , the second module PCB 88 is formed in an annular shape so that the lens assembly 92 passes therethrough. A pair of connecting pins 84 formed of a metal material supports the second module PCB 88 and electrically connects the first module PCB 86 and the second module PCB 88 to each other. Specifically, the upper ends of the pair of connecting pins 84 penetrate the first module PCB 86 and are inserted and fixed to the upper end closing member 78 . A male screw pattern is formed on the outer peripheral surface of the upper end of the pair of connecting pins 84 , and a female screw pattern that meshes with the male screw pattern of the pair of connecting pins 84 on the lower surface of the upper closing member 78 . A pair of connecting pin fastening grooves formed on the inner circumferential surface are formed.

The lower end of the pair of connecting pins 84 penetrates through the second module PCB 88 and is coupled to the lower end of the pair of connecting pins 84 by a pair of fastening bolts 90 . It is in close contact with the module PCB (88) so as to be energized. Each connecting pin 84 has a stepped surface between its upper end and a lower end having a larger diameter than the upper end. The step surface of the pair of connection pins 84 is in close contact with the first module PCB 86 so that the pair of connection pins 84 are in contact with the first module PCB 86 so as to be energized. Terminals 97 of the plurality of LEDs 96 are energably bonded and fixed to the second module PCB 88 .

With this configuration, the objective lens module 70 is axially aligned with respect to the microscope body 11 so that the male screw pattern 76 of the module housing 71 is in contact with the female screw pattern 25 of the microscope body 11 . When aligned along (AX) and rotating the objective lens module 70 in one direction with respect to the microscope body 11, the male screw pattern 76 meshes with the female screw pattern 25, and the module housing ( The upper end of the movable barrel 23 is inserted into the lower end of the 71 , and the objective lens module 70 is detachably coupled to the microscope body 11 .

When the objective lens module 70 is completely coupled to the microscope body 11 by rotating the objective lens module 70 with respect to the microscope body 11 until it is no longer rotated, as shown in FIGS. 3 and 4 , Similarly, the first and second main body-side terminals 40 and 50 are retracted upward to be elastically restored in a state in which they are in close contact with the first and second module-side terminals 81 and 82 . Accordingly, the first and second module-side terminals 81 and 82 are energably attached to the first and second main body-side terminals 40 and 50, and the power supplied through the connection cable 66 is applied. By this, the plurality of LEDs 96 are in a state in which they can be turned on. Since the first and second body-side terminals 40 and 50 are elastically pressed in a downwardly protruding direction by the first and second springs 45 and 55, the objective lens module 70 is connected to the microscope body 11 . The first and second body-side terminals 40 and 50 are reliably contacted with the first and second module-side terminals 81 and 82 as long as they are coupled to each other.

The holder 2 includes a base 3 supported on a flat floor, a pillar 5 fixed to the base 3 and extending upward, and the pillar 5 so as to be able to move up and down along the pillar 5 . A lifting block 6 coupled to 5), a fixing screw 7 for fixing the lifting block 6 to the column 5, and a lifting block 6 movably coupled to the lifting block 6 A support bracket (8) and a support bracket lifting/lowering adjustment dial (9) for finely raising and lowering the support bracket (8) with respect to the lifting block (6) is provided. The main body housing 12 is fitted to the support bracket 8 and the stepped locking jaw 17 of the main body housing 12 is caught on the support bracket 8, so that the digital microscope 10 is connected to the support bracket 8 ) and supported by hanging

A table 4 on which a subject (not shown) is placed is supported on the base 3 . The table 4 is arranged under the digital microscope 10 . The user of the digital microscope 10 elevates the lifting block 6 along the column 5 and tightens the fixing screw 7 at a constant height to approximately adjust the focal length between the digital microscope 10 and the subject. and finely adjusting the focal length between the digital microscope 10 and the subject by turning the support bracket elevating adjustment dial 9 to elevate the support bracket 8 with respect to the elevating block 6 finely. have.

On the other hand, the user of the digital microscope 10 may observe the subject by removing it from the support bracket 8 of the digital microscope 10 and holding it directly, and then approaching the lower end of the objective lens module 70 to the subject. In this way, for example, it is possible to observe a subject that cannot be placed on the table 4 separately, such as skin, hair, animals and plants.

The digital microscope 10 includes the microscope body so that power can be supplied to the LED 96 of the objective lens module 70 as long as the objective lens module 70 is detachably coupled to the microscope body 11. The first and second main body-side terminals 40 and 50 of 11) and the first and second module-side terminals 81 and 82 of the objective lens module 70 are in reliable contact, and conversely, the objective lens module ( As long as 70) is separated from the microscope body 11, the first and second main body-side terminals 40 and 50 and the first and second module-side terminals 81 and 82 are spaced apart from each other in a non-conductive manner. Therefore, the use of the digital microscope 10 is convenient.

On the other hand, in the embodiment of the present invention shown in Figs. 1 to 4, the first and second main body-side terminals 40 and 50 are protruding terminals, and the first and second module-side terminals 81 and 82 are annular. Alternatively, the first and second main body-side terminals may be annular terminals, and the first and second module-side terminals may be protruding terminals.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true protection scope of the present invention should be determined only by the attached utility model registration claims.

2: cradle 10: digital microscope
11: microscope body 40, 50: body side terminal
70: objective lens module 81, 82: module side terminal
92: lens assembly 96: LED

Claims (7)

A microscope having an image sensor, a connection cable for energably connecting to a computer, and a pair of main body-side terminals energably connected to the connection cable main body; and at least one light emitting diode (LED) that is detachably coupled to the microscope body and projects light to a subject, a pair of module-side terminals energably connected to the at least one LED; and an objective lens module having at least one lens that enlarges and forms the image of the subject on the image sensor,
The pair of main body-side terminals and one of the pair of module-side terminals are a pair of annular terminals spaced apart from each other in a concentric circle shape, and the other pair of terminals are elastically biased in a protruding direction. (elastic bias) and a pair of protruding terminals spaced apart from each other,
When the objective lens module is coupled to the microscope body, the pair of module-side terminals are in close contact with the pair of body-side terminals to be energized,
The pair of main body-side terminals are protrusion-shaped terminals, and the pair of module-side terminals are ring-shaped terminals,
The microscope body includes a main housing in which the pair of protruding terminals are exposed to the outside, a body energably coupled to the pair of protruding terminals, and a head protruding to the inside of the main housing ( a pair of protruding terminal coupling bolts each having a head), a pair of bolt connection PCBs ( printed circuit board), and a pair of springs for elastically pressing the pair of protruding terminals in a direction protruding to the outside of the body housing, respectively,
When the objective lens module is separated from the microscope body, the head of the pair of protruding terminal coupling bolts and the pair of bolt connection PCBs do not penetrate through the body housing, so that the pair of protruding terminals are connected to the body housing A digital microscope, characterized in that it does not protrude so as to separate from it. According to claim 1,
The microscope body further includes a body housing in which the image sensor is installed,
The objective lens module further includes a module housing in which the at least one LED and the at least one lens are installed,
A male screw pattern is formed on one of the body housing and the module housing, and a female screw pattern that meshes with the male screw pattern is formed on the other,
When the module housing is aligned with and brought into contact with the main body housing and rotated in one direction with respect to the main body housing, the male screw pattern and the female screw pattern are meshed so that the objective lens module is detachably coupled to the microscope body digital microscope. 3. The method of claim 2,
The main body housing includes a movable barrel detachably coupled to the module housing, and a tubular dial disposed to overlap the outside of the movable barrel,
The digital microscope according to claim 1, wherein as the tubular dial rotates with respect to the movable barrel, the movable barrel moves away from the image sensor and in the opposite direction. delete According to claim 1,
The objective lens module includes a module housing in which the pair of annular terminals are exposed to the outside, a first module PCB disposed on the inner surface of the module housing, and a pair of the module housing so as not to be exposed to the outside of the module housing. A digital microscope comprising a pair of annular terminal coupling bolts for energably connecting the annular terminal and the first module PCB. 6. The method of claim 5,
The objective lens module supports a second module PCB disposed between the first module PCB and the at least one LED in the module housing, and the second module PCB, and includes the first module PCB and the second module PCB Further comprising a pair of connecting pins (pin) for connecting the energizable,
A digital microscope, characterized in that the terminal of the at least one LED is bonded and fixed to the second module PCB so as to be energized. According to claim 1,
The microscope body includes a variable resistance module energably connected to the connection cable and the pair of main body-side terminals, and a resistance adjustment knob coupled to the variable resistance module to change a resistance value of the variable resistance module. (knob) is further provided,
When the resistance adjustment knob is rotated, the size of the resistance value of the variable resistance module is changed to change the luminance of the at least one LED.

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