KR200347488Y1 - A microscope - Google Patents

Abstract

The present invention relates to a microscope, and is provided with a solar cell and a secondary battery so that the microscope can be used even where no power source is provided.

That is, the present invention includes a solar panel 110 that generates electromotive force by receiving light at one side of the microscope body 230, and supplies power supplied from the solar panel 110 to supply power to the dimmer. In addition to charging the battery 120 is provided with a power control unit for supplying to the dimmer.

Therefore, the present invention is provided with a solar panel and a secondary battery so that the power can be used to charge and can be used regardless of the use place.

Description

A microscope

The present invention relates to a microscope, and more specifically, to provide a solar cell and a secondary battery, the purpose of the microscope can be used even where the power source is not provided.

In general, the microscope is to magnify at high magnification in observing a plant specimen or a metal specimen, and the lens unit and the sample provided to observe the sample placed on the center portion of the body and the sample placed on the sample stage It is made up of a dimmer to dim it.

On the other hand, the lens unit is composed of an objective lens unit provided on the sample side to enlarge the magnification of the image, and an eyepiece lens unit provided to be inclined toward the observer side so that the viewer can see the image of the sample enlarged by the objective lens unit.

In the conventional microscope provided as described above, the slide plate provided with the sample is placed on the sample stage and the lens unit is lifted and focused to observe the sample. When the mounted sample is a transparent sample such as a plant, By irradiating light from the lower part of the sample, and in the case of a non-transparent sample such as a metal specimen, it is possible to observe the light from the upper part of the sample by the dimmer.

However, when the conventional microscope is to be used as described above, power must be supplied for the operation of the dimmer, so there is a problem that it cannot be used where no external power source is provided.

Accordingly, the present invention has been made to solve the above-described problems, and provided with a solar cell for generating a power source is operated by irradiation of light, and a secondary battery for storing the power supplied through the solar cell.

1 is a perspective view showing a microscope according to the present invention.

2 is a side cross-sectional view of a microscope according to the present invention.

Figure 3 is a cross-sectional perspective view of the detail adjuster according to the present invention.

Figure 4 is a block diagram showing an embodiment according to the present invention.

Figure 5 is a detailed configuration of the overcharge protection showing an embodiment according to the present invention.

Figure 6 is a schematic view showing an embodiment of the boosting unit according to the present invention.

<Description of the symbols for the main parts of the drawings>

110: solar panel

120: secondary battery

130: external power input unit 131: transformer 132: rectifier

140: overcharge protection

141: charging switch element 142: blocking operation element

151 LED lamp 152 Condensing mirror

153: Dimmer switch

161: condenser lens 162: lifting lens body

163: sight adjustment knob

171: charging line 172: battery load line

173: Power Generation Line 174: Jogwang Line

180: booster

181: magnetic induction coil 182: switching capacitor

183: induction transistor 184: ground transistor

185: ground resistance 186: bias resistor

191: imaging device 192: Youngsan signal output unit

210: sample stand

220: lens unit 221: objective lens 222: light tube

230: body

Hereinafter, described in detail by the accompanying drawings as follows.

The present invention is to be used even where no external power source is provided, the lens unit provided to observe the sample placed on the sample stand 210 and the sample stand provided in the central portion of the body 230 ( 220) and a microscope consisting of a dimming lamp for dimming to observe a sample; It is provided with a solar panel 110 to generate an electromotive force by receiving light on one side of the body 230 to enable dimming to the sample of the sample stage 210 without an external input power, the power supplied from the solar panel 110 And a power control unit for charging the secondary battery 120 and supplying it to the dimming lamp. The light irradiated through the dimming lamp on the light intensity between the dimming lamp and the sample placed on the sample stage 210 is lowered from the sample. It includes a condenser lens 161 for condensing the light, and has a light adjuster configured to adjust the irradiation size of the light irradiated to the lower portion of the sample table by the dimming lamp, the light emitted from the dimming lamp The light of the lens unit 220 includes a light reflecting mirror 152 which is formed in a hemispherical shape to prevent diffusion and is condensed around the dimming lamp, and converts and outputs an image signal of the sample image. An image pickup device 191 having an image signal of an image of the sample introduced through the objective lens 221 is provided at 222, and an image of the sample photographed through the image pickup device 191 on one side of the body 230. The video signal output unit 192 converts and outputs a signal to a video device and a computer terminal.

Here, the dimming lamp is composed of an LED lamp 151, the power control unit to the charging line 171 and the secondary battery 120 to supply the power of the solar panel 110 to the secondary battery to charge. The battery load line 172 to supply the charged power to the light control device, the power generation line 173 to supply the power of the solar panel 110 directly to the light control device, and for the lighting control of the light control device The dimming switch 153 is provided, the overcharge preventing unit 140 provided in the charging line 171 to prevent the overcharge of the secondary battery 120, and a plurality of the current is prevented from flowing back in each line It can be implemented by the diode of.

On the other hand, the overcharge preventing unit 140 is provided with a charging switch element 141 on the charging line 171 that the power of the solar panel 110 and the external power input unit 130 is input to the secondary battery 120, When the power is received through a bias resistor having a resistance value greater than the internal resistance value of the secondary battery 120, the charging switch device 141 is turned off when the internal resistance value increases due to the overcharging of the secondary battery 120. As the blocking operation element 142, a preferred embodiment thereof, the charging switch element 141 is composed of a charging transistor, the blocking operation element 142 is applied to the base of the charging transistor constituting the charging switch element 141 It can be implemented by configuring a blocking operation transistor that is connected to the power supply to be grounded off.

In addition, in the embodiment of the present invention, it can be carried out by having an external power input unit 130 to supply the secondary battery 120 to the charging and dimming device using an AC power supplied from the outside, The external power input unit 130 includes a power transformer 131 for reducing the input power and a rectifying unit 132 for rectifying the AC power input through the power transformer 131.

In addition, the sight adjuster can be made by adjusting the distance to the dimming lamp by raising and lowering the condenser lens 161, the view adjustment knob (163) provided by the tubular body on the upper portion of the dimming lamp to be rotatable. And a guide portion constrained to the guide hole of the body 230 on the side so as to be screwed inside the sight adjusting knob 163 only to move up and down according to the rotation, and constraining the condenser lens 161 therein. The lifting lens body 162 can be implemented.

In addition, the secondary battery 120 to maximize the amount of charging current by connecting the secondary battery 120 having a voltage of 1.2 ~ 1.5V of the present invention in parallel to the secondary battery 120 to turn on the LED lamp 151 operated at 3.5V or more And a booster 180 configured as a magnetic induction oscillator to boost the voltage of the secondary battery of 1.2 to 1.5V connected in parallel between the LED lamp and the LED lamp. A magnetic induction coil 181 provided between the 310 and the secondary battery 200, a switching capacitor 182 connected to the magnetic induction coil 181 and grounded through a grounding resistor 185, and the switching The ground resistance 185 and the base terminal connected to the capacitor 182 are connected and operated by the discharge current of the switching capacitor 182 to cut off the power supply from the secondary battery 200 to the magnetic induction coil 181. An induction transistor 183 for generating a magnetic induction electricity of 2V, and the induction A base power when supplied through the transistor 183, a bias resistor 186 to the power supply through the ground is constituted by transistors 184 to ground the current discharged from the switched capacitor (182).

In the configuration of the microscope as described above is provided with a solar panel 110 for generating an electromotive force by receiving light on one side of the body 230 to enable dimming with a sample of the sample stage 210 without an external input power, It is provided with a power control unit that charges the power supplied from the panel 110 to the secondary battery 120 and supplies to the dimming lamp, the dimming lamp on the light intensity between the dimming lamp and the sample placed on the sample stage 210. And a condenser lens 161 for condensing the light irradiated through the sample to the lower part of the sample, and having a light conditioner configured to adjust an irradiation size of the light irradiated to the lower part of the sample table by the dimming lamp. And a light reflecting mirror 152 formed in a hemispherical shape to prevent light diffusion from the light dimming lamp and to collect light, and to surround the light dimming lamp. An image pickup device 191 for converting an image signal of the sample introduced through the objective lens 221 into the light tube 222 of the lens unit 220 so as to output an arc, and one side of the body 230. The present invention has a video signal output unit 192 for converting and outputting an image signal of a sample photographed through the imaging device 191 to an image device and a computer terminal. 110 to generate electricity by the light energy to be charged and stored in the secondary battery 120.

As described above, when the lighting device is turned on by operating the dimming switch 153 to observe the sample by using the present invention in which electric energy is charged and stored in the secondary battery 120, the secondary battery is not inputted without additional external power. It is to be turned on by the power charged in the battery 120.

On the other hand, when observing a sample using the present invention to output the photographed image to an image device or a computer terminal, by connecting the signal cable to the Youngsan signal output unit 192 through a computer terminal such as an image device and a computer The image of the sample taken can be displayed.

In addition, when the light adjuster rotates the light adjusting knob 163, the condensing lens 161 is lifted to adjust the size of the light ancestor to the lower portion of the sample, so the light irradiated through the LED lamp 151 according to the size of the sample. Can be used to adjust the sight of.

Therefore, the present invention is provided with a solar panel and a secondary battery so that the power can be used to charge and can be used regardless of the use place.

In addition, since the image pickup device and the image signal output unit are provided, the captured image of the sample can be displayed through a computer terminal such as an image device and a computer.

In addition, since the dimming lamp is configured as an LED lamp and equipped with a sight controller, power consumption is minimized, and it is very useful to freely adjust the sight according to the size of the sample.

Claims (4)

In the microscope consisting of a sample stage 210 provided at the central portion of the body 230, a lens unit 220 provided to observe the sample placed on the sample stage and a dimming lamp for dimming the sample. In; It is provided with a solar panel 110 to generate an electromotive force by receiving light on one side of the body 230 to enable dimming to the sample of the sample stage 210 without an external input power, the power supplied from the solar panel 110 And a power control unit for charging the secondary battery 120 and supplying it to the dimming lamp. The light irradiated through the dimming lamp on the light intensity between the dimming lamp and the sample placed on the sample stage 210 is lowered from the sample. It includes a condenser lens 161 for condensing the light, and has a light adjuster configured to adjust the irradiation size of the light irradiated to the lower portion of the sample table by the dimming lamp, the light emitted from the dimming lamp The light of the lens unit 220 includes a light reflecting mirror 152 which is formed in a hemispherical shape to prevent diffusion and is condensed around the dimming lamp, and converts and outputs an image signal of the sample image. An image pickup device 191 having an image signal of an image of the sample introduced through the objective lens 221 is provided at 222, and an image of the sample photographed through the image pickup device 191 on one side of the body 230. And a video signal output unit (192) for converting and outputting a signal to a video device and a computer terminal. The method of claim 1; The dimming lamp is composed of an LED lamp 151, the power control unit is charged in the charging line 171 and the secondary battery 120 to supply the power of the solar panel 110 to the secondary battery to charge The battery load line 172 to supply power to the dimmer, the power generation line 173 to supply the power of the solar panel 110 directly to the dimmer, and the light control device is provided for the lighting control The dimming switch 153, the overcharge preventing unit 140 provided in the charging line 171 to prevent overcharging of the secondary battery 120, and a plurality of diodes provided to prevent current backflow in each line. But with The overcharge preventing unit 140 includes a charging switch element 141 on the charging line 171 through which the power of the solar panel 110 and the external power input unit 130 is input to the secondary battery 120. Blocking operation for turning off the charging switch element 141 when the power is received through a bias resistor having a resistance value greater than the internal resistance value of the battery 120 and the internal resistance value increases due to the overcharging of the secondary battery 120. In one preferred embodiment, the charging switch element 141 is configured as a charging transistor, and the blocking operation element 142 is a base applied power source of the charging transistor constituting the charging switch element 141. A microscope comprising a blocking operation transistor which is connected by being grounded to be turned off. The method of any one of claims 1 to 2; The sight adjuster is made of a tubular body in the upper portion of the dimming lamp and provided with a rotatable tilt adjustment knob 163 and a screw on the inner side of the sight adjustment knob 163, so as to only move up and down in accordance with the rotation of the body on the side And a lifting lens body 162 having a condensing lens 161 constrained therein by forming a guide portion constrained by the guide sphere of 230, By connecting the secondary battery 120 having a voltage of 1.2 ~ 1.5V in parallel to maximize the amount of charging current and to light the LED lamp 151 operating at 3.5V or more between the secondary battery 120 and the LED lamp It is provided with a boosting unit 180 consisting of a magnetic induction oscillation unit to boost the voltage of the secondary battery of 1.2 ~ 1.5V connected in parallel, The magnetic induction oscillation unit is connected to the magnetic induction coil 181 provided between the LED lamp 310 and the secondary battery 200, and the magnetic induction coil 181, the switching capacitor is grounded through the grounding resistor 185 182, the ground resistor 185 connected to the switching capacitor 182, and the base terminal are connected to each other, and operated by the discharge current of the switching capacitor 182 to operate the magnetic induction coil 181 in the secondary battery 200. The power supply to the furnace is cut off so that the induction transistor 183 generating 2V magnetic induction electricity and the power supplied through the induction transistor 183 are supplied with the base power through the bias resistor 186, and the switching capacitor ( And a ground transistor 184 for grounding the current discharged at 182. The method of any one of claims 1 to 2; Microscope comprising an external power input unit 130 for supplying the secondary battery 120 to the charging and dimming device using an AC power supplied from the outside.