KR200419786Y1 - Measurement device for acceleration of gravity - Google Patents

Abstract

The present invention can measure the acceleration of gravity from a free falling measurement object without being affected by the recording paper or air resistance, and the gravity acceleration measuring device that measures the acceleration of gravity as the accurate falling distance and falling time are measured by the laser beam. It is about.

The present invention is formed of a cylindrical container member, the measuring object 1100 is formed so as to fall inside, the lower portion of the container measuring vessel portion 700 is formed with a lower portion 710 which is an outlet for taking out the dropped object The sensing and display unit 200 is formed on the inner and outer surfaces of the measuring container 700 in the longitudinal direction, and is configured to detect the falling motion of the measuring object 1100 through a laser beam and display the measurement result. The present invention relates to a gravity acceleration measuring device including a control part 500 formed on an outer surface in a longitudinal direction of the measuring container part 700 and configured to control the sensing and display part 200.

Gravitational acceleration, measurement

Description

Gravity acceleration measuring device {Measurement device for acceleration of gravity}

1 is a perspective view of the present invention gravity acceleration measuring apparatus.

2A to 2D are schematic diagrams showing a state in which the sensing and display unit 200, which is a component of the present invention, is subjected to gravity acceleration measurement.

3A to 3B are schematic views showing a vacuum device 760 that is a component of the present invention's gravity acceleration measuring device.

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

100: cover 120: object clamp

150: rubber plate 200: detection and display unit

210: laser emitter 220: laser detector

250: measurement result display unit 500: control unit

510: switch unit 520: control panel

600: vacuum apparatus

700: measuring vessel 710: lower section

720: inclined bottom portion 760: vacuum device portion

1100: measuring object 1500: vacuum cleaner

The present invention relates to a gravity acceleration measuring device.

The present invention is formed of a cylindrical container member, the measuring object 1100 is formed so as to fall inside, the lower portion of the container measuring vessel portion 700 is formed with a lower portion 710 which is an outlet for taking out the dropped object The sensing and display unit 200 is formed on the inner and outer surfaces of the measuring container 700 in the longitudinal direction, and is configured to detect the falling motion of the measuring object 1100 through a laser beam and display the measurement result. And a control part 500 formed on the outer surface in the longitudinal direction of the measuring container part 700, and configured to control the sensing and display part 200.

The present invention relates to a gravitational acceleration measuring device capable of measuring gravitational acceleration from a free-falling measurement object without being affected by recording paper or air resistance, and measuring gravitational acceleration as a precise drop distance and drop time are measured by a laser beam. .

In schools, gravitational acceleration is commonly used by record timers. However, this method is a test method conducted in the atmosphere because the recording paper is connected to the falling object, it is difficult to accurately measure the acceleration of gravity.

It would be desirable to have a gravitational acceleration measuring device capable of measuring gravitational acceleration from a free falling measurement object without being affected by recording paper or air resistance.

For this purpose, an experimental method was devised to measure the motion of a free-falling object not connected to recording paper in a container close to vacuum using a laser beam.

An object of the present invention is to provide a gravitational acceleration measuring device capable of measuring gravitational acceleration from a free falling measurement object without being affected by recording paper or air resistance.

It is also an object of the present invention to provide a gravity acceleration measuring device that measures the acceleration of gravity as the accurate falling distance and the falling time is measured through a laser beam.

The present invention relates to a gravity acceleration measuring device.

The present invention includes a measuring vessel 700, the detection and display unit 200, the control unit 500.

The present invention is formed of a cylindrical container member, the measuring object 1100 is formed so as to fall inside, the lower portion of the container measuring vessel portion 700 is formed with a lower portion 710 which is an outlet for taking out the dropped object The sensing and display unit 200 is formed on the inner and outer surfaces of the measuring container 700 in the longitudinal direction, and is configured to detect the falling motion of the measuring object 1100 through a laser beam and display the measurement result. The present invention relates to a gravity acceleration measuring device including a control part 500 formed on an outer surface in a longitudinal direction of the measuring container part 700 and configured to control the sensing and display part 200.

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

1 is a perspective view of a gravity acceleration measuring device of the present invention.

2a to 2d is a schematic diagram showing a state in which the sensing and display unit 200, which is a component of the present invention acceleration device.

3a to 3b is a schematic view showing a vacuum device 760 that is a component of the present invention gravity acceleration measuring device.

The present invention is formed of a cylindrical container member, the measuring object 1100 is formed so as to fall inside, the lower portion of the container measuring vessel portion 700 is formed with a lower portion 710 which is an outlet for taking out the dropped object The sensing and display unit 200 is formed on the inner and outer surfaces of the measuring container 700 in the longitudinal direction, and is configured to detect the falling motion of the measuring object 1100 through a laser beam and display the measurement result. And a control part 500 formed on the outer surface in the longitudinal direction of the measuring container part 700 and configured to control the sensing and display part 200.

The measuring vessel 700 is formed of a cover member of the measuring vessel 700, the central portion of the cover member is formed of a through-hole, the object clamp 120 is formed to pick up the measuring object 1100 ) Covers the through hole, but is formed to be inserted between the rubber pins 150 having the object tweezers 120 and the access groove, and the cover member is tightly coupled to the body of the measuring container 700. Cover portion 100 is formed in the rubber packing for coupling, the lower portion of the measuring vessel 700 is formed, the vacuum in the measuring vessel 700 to remove the air resistance during the falling of the measuring object 1100 A vacuum device 760 in which a vacuum device for adjusting to a state close to is formed, is formed at a lower end of the measurement container part 700, and is formed of an exit door member capable of taking out the dropped measurement object 1100, The exit door member is The lower portion 710 where the rubber packing is formed for a tight coupling at the portion coupled to the body of the measuring vessel 700, so that the dropped measurement object 1100 naturally rolls toward the lower portion 710. The bottom surface of the measuring vessel 700 may be formed to include a sloped bottom portion 720 which is formed to be inclined downward toward the lower portion 710 side.

The measuring container 700 may be formed to have a plurality of legs to be installed stably.

End of the leg may be formed of a rubber material to be installed more stably.

The vacuum unit 760 may be a professional vacuum device having a self-operating switch as shown in Figure 3a, as shown in Figure 3b, a vacuum cleaner may be used.

The inclined bottom portion 720 may be formed of a soft and fluffy material such as a sponge to reduce the impact of the measuring object 1100 on the measuring vessel 700.

The rubber plate 150 is formed in a closed manner to allow only the entry of the object clamp 120 and prevent the entry of air.

As described above, the measuring object 1100 is free to fall inside the measuring vessel 700 in a state close to the vacuum from the object clamp 120, so that the recording paper is connected to the falling object, It is not affected by the resistance of the air.

Therefore, the object of the present invention is to provide a gravitational acceleration measuring device capable of measuring gravitational acceleration from freely falling measurement objects without being affected by recording paper or air resistance.

The detection and display unit 200 includes a plurality of laser firing units 210 and the laser firing unit 210 disposed at regular intervals in the longitudinal direction of the measuring vessel 700 among the inner surfaces of the measuring vessel 700. And a plurality of laser detectors 220 and the measurement vessel 700 which are formed to detect the laser beam emitted from the laser beam, and are disposed opposite to the laser projector 210 among the inner surfaces of the measurement vessel 700. Is disposed in the vicinity of the laser detector 220 of the outer surface of, by detecting the falling motion of the measuring object 1100 through the laser beam using the laser emitter 210 and the laser detector 220 by It may be formed including a plurality of measurement result display unit 250 is formed to display the passing time of the measurement object 1100 that is a measurement result.

The wirings of the laser projector 210, the laser detector 220, and the measurement result display unit 250 are neatly arranged so as not to interfere with the falling motion of the measurement object 1100.

The control unit 500 controls the switch unit 510, the laser firing unit 210, the laser sensing unit 220, and the measurement result display unit 250, which are formed as power switches of the detection and display unit 200. It may be formed to include a control panel 520 is formed to.

As shown in Figs. 2a to 2d, the time when the measurement object 1100 passes through the laser beam is measured.

As described above, the falling time of the measurement object 1100 is accurately measured through laser beams at regular distances, and the gravity acceleration is measured from the falling distance and the falling time.

Therefore, to achieve the object of providing a gravity acceleration measurement device to measure the acceleration of gravity as the accurate fall distance and fall time through the laser beam.

The present invention provides a gravitational acceleration measuring device capable of measuring gravitational acceleration from a free falling measurement object without being affected by recording paper or air resistance.

In addition, the present invention provides a gravity acceleration measuring device that measures the acceleration of gravity as the accurate fall distance and fall time are measured through a laser beam.

Claims (4)

It is formed of a cylindrical container member, the measuring object 1100 is formed so as to fall inside, the lower portion of the container measuring vessel 700 is formed with a lower portion 710 which is an outlet for taking out the dropped object; A detection and display unit 200 formed on the inner and outer surfaces of the measuring container 700 in the longitudinal direction and configured to sense a falling motion of the measuring object 1100 through a laser beam and display the measurement result; A control part 500 formed on an outer surface in the longitudinal direction of the measurement container part 700 and configured to control the sensing and display part 200; Gravity acceleration measurement device comprising a. The method of claim 1, wherein the measuring vessel 700 Is formed of a cover member of the measuring vessel 700, the central portion of the cover member is formed with a through hole, the object clamp 120 is formed to pick up the measurement object 1100 covers the through hole The object clamp 120 is formed to be inserted between the rubber plate 150 having an access groove, and a portion of the cover member is coupled to the body of the measuring vessel 700, the rubber packing is formed for a tight coupling Cover part 100; The vacuum apparatus is formed near the lower end of the measuring vessel 700, the vacuum device for adjusting the measuring vessel 700 in a state close to the vacuum to remove the air resistance when the measurement object 1100 falls Unit 760; Is formed in the lower end of the measuring vessel 700, formed of an exit door member that can take out the falling measurement object 1100, the portion of the exit door member and the body of the measuring vessel 700 A lower portion 710 in which rubber packing is formed for a tight coupling; An inclined bottom portion 720 formed such that the bottom surface of the measuring vessel 700 is inclined downward toward the lower portion 710 so that the dropped measurement object 1100 naturally rolls toward the lower portion 710; Gravity acceleration measuring device, characterized in that the measuring vessel comprising a. The method of claim 1, wherein the detection and display unit 200 A plurality of laser projectors 210 disposed at regular intervals in the longitudinal direction of the measurement vessel 700 among the inner surfaces of the measurement vessel 700; A plurality of laser detectors 220 formed to detect lasers emitted from the laser emitters 210 and disposed on opposite sides of the laser emitters 210 of the inner surface of the measuring vessel 700; The outer surface of the measuring vessel 700 is disposed in the vicinity of the laser detection unit 220, the falling motion of the measuring object 1100 using the laser launch unit 210 and the laser detection unit 220. A plurality of measurement result display units 250 which are configured to sense a through laser beam to display a passage time of the measurement object 1100 as a measurement result; Gravity acceleration measurement device, characterized in that the detection and display unit comprising a. The method of claim 1, wherein the control unit 500 A switch unit 510 formed as a power switch of the sensing and display unit 200; A control panel unit 520 formed to control the laser projector 210, the laser detector 220, and the measurement result display unit 250; Gravity acceleration measurement apparatus, characterized in that the control unit including a.

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