KR890000991Y1 - Instrumints for examining the eyes - Google Patents

Abstract

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Description

Vision meter

Figure 1 is a side view showing a cut off part of the present invention.

2 is a perspective view showing a state in which the main part of the present invention is disassembled.

3 is a cross-sectional view showing a state in which a lens is installed in the viewing tube.

4 is an enlarged longitudinal sectional view showing a state in which the lens fixing plate is assembled to the see-through tube.

5 is a circuit diagram showing a frequency measurement digital circuit.

6 is a diagram showing a part of frequency display according to lens selection as an example.

7 is a circuit diagram showing a drive circuit for astigmatism measurement and a digital display configuration.

* Explanation of symbols for main parts of the drawings

5: rotating plate 5a: reset pin

6: see-through tube 8: lens fixing plate

8a: Fixing groove 8´: Marking hole

9: lens 10: stopball

11: spring 12: sensing piece

13 sensor 14 7 segment indicator

15: hexadecimal decoder 16: decimal counter

17: 7-segment decoder 18: reset sensor

19: monostable circuit 20: oscillator

21: stepping drive 22: divider

23: decimal counter

The present invention is designed to allow accurate and rapid visual acuity measurement by displaying all measurement results digitally at the same time as angle display and degree of astigmatism as well as frequency measurement and hyperopia and myopia to users who need visual acuity.

The inspection machine used in the past usually changes the optometry display screen or shifts the distance by a mechanical primitive method so that the position is represented by an electronic contact method and separate astigmatism measurement requires a lot of optometry time. At the same time, it was impossible to accurately measure the eyesight by measuring only the approximate degree due to lack of accuracy, and there was a problem that a person who had no professional knowledge could not handle this because of frequent malfunctions and difficult operation methods.

In order to solve this problem, all the screens are shifted to the motor drive, the perspective lens is rotated, and the astigmatism angle is measured together in the main body when the switch is simply pressed to solve the problem. This will be described in detail with reference to the accompanying drawings.

A screen P having various optometry marks in the main body 1 is formed in the base 2 so as to be converted to the motor M ₁ , and then screwed together with the screw 3 of the stationary motor M ₂ together with the base 2. Supporting the screen P to be rotated forward and backward to rotate the viewing tube 6 together to the center of one side of the rotary plate 5 connected to the belt 4 of the main motor M ₃ . It is supported to flow to the tube (7).

At the distal end of the see-through tube 6, an assembling hole 6 'is formed so that the lens fixing plate 8 can be inserted from the side so that the lens 9 fitted with different powers at regular intervals is aligned with the see-through hole 6˝. When the stop ball 10 is in contact with the fixing groove (8a) by the elasticity of the spring 11, the role of the stop ball 10 is fixed directly below the lens (9) formed in the lens fixing plate (8). The groove 8a is recessed to accurately stop the position coinciding with the see-through hole 6 as the stop ball 10 and to prevent it from being dislodged. Perforation) detects that the sensor 13, which operates as an infrared transistor, inside the sensing piece 12 blocks or passes infrared light, generates it as a signal, and then displays the frequency of each lens 9 on the digital display. To be able.

Inside the sensing piece 12 is composed of an infrared diode (D ₁ ) (D ₂ ) (D ₃ ) (D ₄ ) is blocked or transmitted by the display hole (8 ′) to intercept or pass the infrared light is interrupted. And then the infrared transistors TR ₁ (TR ₂ ) (TR ₃ ) (TR ₄ ) detect this and pass the amplifier IC ₁ (IC ₂ ) and then the amplified signal is converted into binary code in the hexadecimal decoder 16. It converts the signal into hexadecimal number, inputs from the NAND gate (I ₁ ) (I ₂ ) (I ₃ ) (I ₄ ) corresponding to the magnetic code, and converts the “L” and “H” signals to connect the decimal counter. 16 and the 7 segment decoder 17 and the 7 segment indicator 14 respectively pass through the corresponding signal is displayed digitally, as an example, as shown in Figure 3 of the accompanying drawings, the fourth from the left When viewing the screen (P) through the lens (9) of the most suitable magnetic power, the indication hole (8´) blocks only the fourth infrared diode (D ₄ ) from the left In this case, the output of the infrared transistor TR ₁ (TR ₂ ) (TR ₃ ) becomes “L” and only the fourth infrared transistor TR ₃ is output of “H” so that the hexadecimal decoder 15 has a 0001 binary system. The display numeric input is converted to hexadecimal, so that the numeric output of 1 is selected as "L" for pin 2 of selection 1-17 and the remainder as "H".

Therefore, the corresponding pin 2 is connected to the NAND gate (I ₄ ) and outputted as “H” to be displayed on the 7 segment indicator 14 through the 7 segment decoder 17 according to the 8421BCD code input method. If the most suitable power lens is selected, the corresponding power can be converted to digital as 0.25 as shown in the diagram of FIG. 5.

And when measuring astigmatism, the angle corresponding to astigmatism should be measured. Astigmatism means that the object is blurred only at a certain inclined part that is not horizontal when the object is viewed. It is necessary to fix the astigmatism axis because it is necessary to fix only a part of the spectacle when the spectacle is generated so that the phenomenon can be seen. These measurement methods are as follows.

That is, the lens 9, which is best seen by the optometrist by the above-described method, is selected and immediately connected to the power source for measurement from the origin, and then connected to the gate I ₆ through the monostable 30 by the condenser C ₂ . The output of the gate I ₄ to “H” becomes zero by the RS flip-flop, and when the reset pin 5a is separated from the reset sensor 18, it is not the starting point of the optometry, and at this time, the infrared transistor TR ₅₎ the gate so that the output is a set state by the "L" so as through a monostable circuit 19 the output of the gate (I ₈₎ is set to "H" resistor (R ₁₎ and a capacitor (C ₁₎ of the ( The output of I ₁₃ is maintained at “L” and the output of gate I ₁₂ is maintained at “H”, respectively, and the pulse generated from the oscillator 20 finally passes through the gate I ₁₅ through the gate I ₁₄ . via connected to the belt 4 so as to rapidly rotate the coarse motor (M ₉₎ by operating the stepping drive unit 21 times the copper (5) When the sight tube 6 is in the home position, the reset pin 5a blocks the reset sensor 18. Thus, the reset sensor 18 blocks the infrared rays so that the reset pin 18a blocks the infrared ray. The output of the gate (I ₁₀ ) becomes “L” and the main motor (M ₃ ) stops, thus preparing for astigmatism measurement.

In this preparation state, when the optometrist presses the measurement switch SW ₁ , the a contact point becomes “L” and the b contact point becomes “H” so that the output of the gate I ₇ becomes “H” and the gate I ₁₁ . Open the door to the input of the oscillator 20, the pulse signal generated by passing through the divider 22 is slowed down so that you can see the screen (P) for a certain time again the next signal (I ₁₁ ) (I ₁₂ ) When the signal divided into the main motor (M ₃ ) via (I ₁₃ ) arrives, the see-through tube (6), the lens fixing plate (8), and the lens (9) rotated together with the rotating plate (5) at regular intervals. At the same time, it rotates by a certain angle, and the output pulse of the gate I ₁₁ is input to the decimal counter 23 and the hexadecimal counter 24, so that the angle to the astigmatism display digital 26 is passed through the 7 segment decoder 25. Is displayed and the pulse inputted to the hexadecimal counter 24 passes through the hexadecimal decoder 27 to emit 18 lights on each angular display screen. Check the digital number and axis display in the state where the optometry is disappearing from the specific part by turning on the graphic of the rotation angle on the axis display device 28 made of diode (LED). If you can measure the correct astigmatism angle.

The optometry of the hyperopia and myopia drives the stationary motor (M ₂ ) to rotate the screw (3), and the base (2) on which the screen (P) is formed is moved forwards and backwards through the viewing tube (6). By measuring the position where the screen P appearing in the lens 9 and the magnification lens 29 is best seen, myopia and hyperopia can be detected.

As described above, the present invention can not only accurately measure the power and angle of astigmatism axis, hyperopia and myopia of the optometrist, but also display it digitally, and can be used by anyone who has no professional knowledge because of its simple handling and easy reading. It is a useful design.

Claims (1)

A lens fixing plate 8 having a uniformly spaced lens 9 is inserted into the assembling hole 6 ′ of the see-through tube 6, and the fixing groove 8a is interrupted by a stop ball 10 that is installed with a spring 11. And infrared rays transmitted from the infrared diodes (D ₁ ), (D ₂ ), (D ₃ ), (D ₄ ) to the sensing unit (12) by the display holes (8 ') perforated in the lens fixing plate (8) for each frequency. The signal sensed by TR ₁ ) (TR ₂ ) (TR ₃ ) (TR ₄ ) is amplified by the amplifier IC1 (IC2) to the hexadecimal decoder 15 and the NAND gate I ₁ (I ₂ ) (I ₃ ). ) (I was converted to _four) decimal counter 16, 7 gegeu garment decoder 17, and 7 after passing through the segment indicator 14, respectively, and to display a digital measurement switch (SW _1), the gate (I when switching ₇ ) A pulse signal generated by the oscillator 20 through (I ₁₁ ) is passed to the main motor M ₃ connected to the gate I ₁₁ (I ₁₂ ) (I ₁₅ ). When the lens 9 of the dispensed lens fixing plate 8 is rotated, the output pulse of the gate I ₁₁ The pulses inputted to the decimal counter 23 and the hexadecimal counter 24 and angled to the 7-segment decoder 25 and the astigmatic axis digital 26 and input to the hexadecimal counter 24 are inputted to the hexadecimal decoder 27. Eye light measuring device characterized in that the light emitting diode (LED) of the axis display device 28 is turned on to display the power and astigmatism.