KR20180001246U - Test apparatus for laser levelling and measuring equipment - Google Patents

Abstract

CLAIMS 1. A laser starter testing apparatus for testing whether or not each of the photosensors of a laser star including a plurality of photosensors arranged at regular intervals along a longitudinal direction is responsive to a laser emitted by a laser,
A motor including a shaft for performing controlled rotation;
A gear portion installed on the shaft of the motor and rotated;
A fixing plate on which a laser light is arranged and fixed on an upper surface in a flat shape;
And a vertical gear unit formed along the longitudinal direction so as to be moved along a longitudinal direction perpendicular to the rotary shaft, the gear unit being engaged with the gear unit, A vertical moving part which moves upward or downward as the gear part rotates; And
A control unit connected to the motor to output a controlled signal to control the rotation of the shaft of the motor,
A laser starter test apparatus is disclosed.

Description

[0001] The present invention relates to a laser apparatus,

This technique relates to a laser star test apparatus.

In particular, to test whether a laser staff reacts to a plurality of photosensor rotating laser levels of equal spacing prior to use, the laser staff may be fixed and the laser staff moved up or down at a set speed The present invention relates to a laser starter test apparatus.

A domestic patent application No. 10-2007-0127051 discloses a digital laser starter device.

In order to accurately ascertain the vertical, horizontal level, or tilt at the site or at the construction site of a large structure, the laser staff is required to position the position of the laser light, which rotates at a constant speed or more at a rotating laser level, Sensor, and digitalized into a numerical value, which can be displayed on a current laser receiving height display unit.

These laser staffs must be used after the calibration before they are used in the field. The laser staffs are different according to the standard. For example, one photo sensor is attached per 1 mm for 300 mm size. .

At present, the rotating laser level for emitting the laser is fixedly arranged on one side, and manually checking the reaction of the photosensor arranged at regular intervals on the laser staff while manually moving the laser staff is performed.

When checking whether the photosensor of the laser staff is operated through the above-described method, it is necessary to confirm whether or not the laser staff of the 300 mm standard has reacted 300 times according to the embodiment described above, It is impossible to check the sensor individually.

Therefore, if the laser star automatically moves up or down at regular intervals and the photosensor responding to the current rotating laser level is accurately grasped, the above problem can be solved.

Therefore, a laser star test apparatus capable of solving the above problems is needed.

(Utility model publication 1) Korean utility model application number "20-2005-0003897"

It is an object of the present invention to provide a laser starter test apparatus which can automatically test whether or not each of the photosensors arranged at equal intervals is automatically operated.

Another object of the present invention is to provide a laser starter test apparatus which can easily identify a photosensor that reacts with a laser emitted from a rotating laser level among a plurality of photosensors arranged at regular intervals of a laser star.

It is another object of the present invention to provide a laser star test apparatus capable of real-time confirmation of a photosensor that does not react with a laser emitted by a rotating laser level among a plurality of photosensors arranged at regular intervals of a laser star.

It is to be understood that the technical subject matter of the present invention is not limited to the technical subjects mentioned above and that other technical subjects not mentioned can be clearly understood by those skilled in the art from the description below will be.

A laser starter testing apparatus according to an embodiment of the present invention includes a plurality of photosensors each having a plurality of photosensors arranged at regular intervals along a longitudinal direction, .

A laser starter testing apparatus according to an embodiment of the present invention includes a motor including a shaft for performing controlled rotation; A gear portion installed on the shaft of the motor and rotated; A fixing plate on which a laser light is arranged and fixed on an upper surface in a flat shape; And a vertical gear unit formed along the longitudinal direction so as to be moved along a longitudinal direction perpendicular to the rotary shaft, the gear unit being engaged with the gear unit, A vertical moving part which moves upward or downward as the gear part rotates; And a controller connected to the motor to output a controlled signal to control the rotation of the shaft of the motor.

Here, the gear portion is a lever and the vertical gear portion is a pinion.

Here, the vertical moving part includes a fixed vertical bar having a predetermined length, the fixed vertical bar received therein, one side opened by a predetermined area, and the other side formed with a vertical gear part, And a slide moving plate capable of sliding the bar upward or downward.

In this case, on the lower side of the fixed vertical bar, there is formed a measurement section having the same interval as the photosensor arranged at equal intervals along the longitudinal direction, and the slide movement plate is set to the upper or lower range The position of the photosensor that reacts with the laser emitted by the rotating laser level can be confirmed.

Here, a vertical caliper is installed on one side surface of the slide moving plate, and a display unit for measuring and displaying the distance by which the horizontal plate is moved is formed with an extended portion contacting the upper surface of the horizontal plate, And the position of the photosensor that reacts with the laser emitted by the rotating laser level can be confirmed when the slide moving plate is moved in a range set to be complementary or lower according to the rotation of the motor.

Here, the motor is characterized in that it is a step motor or a servo motor which can be rotated by a predetermined angle by the control unit.

Here, the laser starter testing apparatus may further include a speed measuring sensor capable of measuring a moving speed of the vertical moving part when the vertical moving part moves upward or downward.

Here, the laser starter testing apparatus is characterized in that a confirming section is provided for identifying a photosensor that reacts with the laser of the rotating laser level among the plurality of photosensors of the laser staff to be tested.

Here, the confirmation unit is connected to the laser starter test apparatus wirelessly through pairing.

The fixing plate has a flat plate having an insertion hole in which the laser diaphragm is disposed and the vertical moving part is inserted at one side thereof, And a connecting plate extending in a downward direction from a lower side of the flat plate at a portion where the holes are formed and having a bolting hole formed on at least a side surface of the vertical moving portion when the vertical moving portion is disposed inside the insertion hole And the bolt holes are inserted into the bolt holes of the connecting plate, and the position of the vertical moving unit and the fixing plate are adjusted while being fixed.

A laser starter testing apparatus according to an embodiment formed through the above-described configuration includes a motor including a shaft for rotating a set angle, a lever connected to the motor and rotating, The laser star including the photosensor at the set speed through the pinion moves up or down to automatically check whether all the photosensors are reacting with the laser emitting the rotating laser level.

The laser starter testing apparatus according to an exemplary embodiment of the present invention is configured to include a measuring unit, a vertical caliper, an identifying unit, and the like so that the accurate position of the photosensor that reacts with the laser beam .

In the laser starter testing apparatus according to an embodiment of the present invention, the confirmation unit is installed, and among the plurality of photosensors arranged at equal intervals, a photosensor that does not react with the laser emitted by the rotating laser level Can be confirmed.

1 shows a laser starter testing apparatus according to an embodiment of the present invention.
2 is an enlarged view of a motor, a gear unit, and a vertical gear unit according to an embodiment of the present invention.
3 is an enlarged view of the bottom of the horizontal plate and the vertical moving part according to the embodiment of the present invention.
4 shows a laser starter testing apparatus equipped with a speed measuring sensor according to an embodiment of the present invention.
FIG. 5 illustrates a laser starter test apparatus according to an embodiment of the present invention connected to an identification unit.

Hereinafter, one embodiment of the present invention will be described in detail with reference to exemplary drawings. However, this is not intended to limit the scope of the present invention.

It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, the size and shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the configuration and operation of the present invention are intended to illustrate embodiments of the present technology and are not intended to limit the scope of the present invention.

1 shows a laser starter testing apparatus according to an embodiment of the present invention.

2 is an enlarged view of a motor, a gear unit, and a vertical gear unit according to an embodiment of the present invention.

3 is an enlarged view of the bottom of the horizontal plate and the vertical moving part according to the embodiment of the present invention.

4 shows a laser starter testing apparatus equipped with a speed measuring sensor according to an embodiment of the present invention.

FIG. 5 illustrates a laser starter test apparatus according to an embodiment of the present invention connected to an identification unit.

The laser staf 20 testing apparatus according to an embodiment of the present invention includes a photosensor 30 of a laser stapler 20 including a plurality of photosensors 30 arranged at regular intervals along the longitudinal direction, Is a device for testing whether the rotating laser level 10 is responsive to the emitting laser.

In order to solve the above-described problems, the laser starter 20 testing apparatus of the present invention has a configuration in which each photosensor 30 disposed along the lengthwise direction at equal intervals in the laser star wave is rotated by the rotating laser beam 10 In order to confirm whether the laser staple 20 is reacting with the laser, the laser staple 20 is moved to the upper or lower position at a predetermined speed and stopped to determine whether any of the photo sensors 30 reacts with the laser It is necessary to check whether or not another photo sensor 30 is reacting with the laser beam emitted by the rotating laser beam 10 after moving back to the upper or lower position.

For example, if there are 300 photosensors 30, the above experiment is repeated 300 times.

In order to achieve the above object, a laser starter testing apparatus according to an embodiment of the present invention includes a motor 100, a gear unit 150, a fixing plate 200, a vertical moving unit 320, a control unit 800, A measuring unit 400, a vertical caliper 510, a speed measuring sensor 600, an identifying unit 700, and the like.

The fixing plate 200 has a flat shape and the laser switch 20 is disposed and fixed on the upper surface.

Accordingly, the laser staff 20 moves upward or downward together with the fixing plate 200 when the fixing plate 200 is moved upward or downward.

The fixing plate 200 has a predetermined thickness and includes a flat plate 210 and a connecting plate 220.

The flat plate 210 is formed to have flat upper and lower surfaces.

The above-described laser staff 20 is disposed and fixed on the upper surface of the flat plate 210.

At one side of the flat plate 210, an insertion hole into which the vertical movement part 320 is inserted is formed.

The connection plate 220 is formed to extend downward in a portion where the insertion hole of the flat plate 210 on the lower side of the flat plate 210 is formed.

That is, the connection plate 220 is formed with the same insertion hole so as not to close at least the insertion hole of the flat plate 210.

The insertion holes of the flat plate 210 and the coupling plate 220 may be holes that pass through the upper and lower portions of the flat plate 210 and the coupling plate 220, And a hole formed through the upper and lower portions of the plate 220 to open the other side.

That is, in order to connect the fixing plate 200 and the vertical moving unit 320, the fixing plate 200 may be positioned at the upper portion of the vertical moving unit 320 and may be connected to the vertical moving unit 320 while moving the fixing plate 200 downward Alternatively, the fixing plate 200 may be simply disposed on one side of the vertical moving part 320 and moved to the other side so as to be in contact with the vertical moving part 320.

The connecting plate 220 may abut the side surface of the vertical moving part 320.

That is, according to the connection between the fixing plate 200 and the vertical moving part 320, when the vertical moving part 320 is disposed on the fixing plate 200, the vertical moving part 320, with reference to the inner circumferential surface of the insertion hole, The flat plate 210 and the connecting plate 220 can be brought into contact with each other at one side, another side, or side surface, or can be abutted from one side or side.

In either case, at least the side of the vertical transfer part 320 abuts the side of the connecting plate 220.

A bolting hole is formed on a side surface of the connecting plate 220.

A fixing hole 340 is formed along the longitudinal direction at a predetermined interval on the side surface of the vertical moving part 320.

The fixing plate 200 is disposed to align the bolt holes formed on the side surfaces of the connection plate 220 and the fixing holes 340 of the vertical portion 320 and then the bolts are inserted into the bolting holes and the fixing holes 340, And may be fixed to the moving part 320.

The fixing plate 200 is connected to the vertical movement unit 320 and is fixed at a position where the bolt hole of the fixing hole 340 is connected to the fixing hole 340 of the vertical movement unit 320 Lt; / RTI >

The motor 100 includes a shaft that performs controlled rotation.

The gear portion 150 is installed on the shaft and rotates on the same axis as the shaft.

Here, the motor 100 may be a servo motor or a step motor.

Therefore, the motor 100 rotates the shaft by a predetermined angle, and after stopping, rotates again by the set angle, and can be stopped again.

The gear portion 150 is connected to the shaft of the motor 100 and may be rotated in the same manner according to the shaft control of the motor 100. [

The controlled rotation of the shaft of the motor 100 can be controlled through the control unit 800. [

That is, the control unit 800 may be connected to the motor 100 to output a controlled signal to cause the shaft of the motor 100 to rotate in a controlled manner.

Here, the control unit 800 may continuously output the controlled signal to the motor 100 so that the controlled rotation can be continuously performed according to the user's manipulation, or alternatively, So that the rotation direction can be rotated in one direction or another direction.

In addition, the control unit 800 may output a control signal to the motor 100 so that the motor 100 can stop without being operated according to the user's operation.

The vertical moving part 320 is engaged with the gear part 150 and can be moved in the other direction in accordance with the rotation of the gear part 150.

The vertical moving part 320 is disposed along the longitudinal direction with a predetermined length.

The vertical movement part 320 is formed with one side, the other side and the side. The side surface of the vertical moving part 320 is formed along the predetermined interval of the fixing hole 340 described above.

The vertical moving part 320 is disposed on one side of the fixing plate 200.

The vertical movement unit 310 is formed on the other side of the vertical movement unit 320.

The vertical gear unit (310) meshes with the gear unit (150).

The vertical gear unit 310 is formed to move on an axis perpendicular to the rotational axis of the gear unit 150.

That is, the vertical gear unit 310 may be a pinion.

The gear portion 150 is engaged with the shaft of the motor 100 and performs controlled rotation in the same manner as the shaft of the motor 100 performing the controlled rotation. The vertical gear unit 310 engaged with the gear unit 150 is moved upward or downward according to the controlled rotation of the gear unit 150.

That is, if the shaft of the motor 100 rotates at a predetermined angle and then stops for a specific time, and then the shaft of the motor 100 rotates at a predetermined angle and then repeats the operation, The vertical movement unit 320, which receives the controlled rotation of the motor 100, moves to the upper or lower position, stops for a specific time, moves to the upper or lower position again, and then stops for a predetermined time.

Here, the fixing plate 200 on which the laser staff 20 is disposed is also connected to the vertical moving unit 320, so that the laser staff 20 is also moved upward or downward in the same manner.

The position of the photosensor 30 of the laser star 20 corresponding to the laser of the rotating laser level 10 can be changed and the position of the photosensor 30 of the laser sensor 20 of the laser star 20 can be automatically changed. You can check if you have a reaction.

The vertical moving part 320 includes a fixed vertical bar 320 and a slide moving plate 330 slidable with respect to the fixed vertical bar 320.

The fixed vertical bar 320 is disposed with a predetermined length and the slide moving plate 330 is arranged to receive the fixed vertical bar 320 therein.

The above-described vertical gear unit 310 is formed on the other side of the slide moving plate 330, and one side is formed to be opened by a predetermined area.

One side of the slide moving plate 330 is opened by a predetermined area, and the fixed vertical bar 320 disposed therein can be observed.

The slide moving plate 330 can be slid upward or downward with respect to the fixed vertical bar 320 according to the controlled rotation of the motor 100 as described above.

The present invention is a device for testing whether or not each photosensor 30 arranged at equal intervals along the longitudinal direction of the laser staff 20 reacts with the laser emitted by the rotating laser level 10, It is important to confirm the position of the photosensor 30 that is in reaction with the laser level 10.

Therefore, in order to achieve the above-mentioned object, the laser star 20 testing apparatus according to one embodiment of the present invention includes a measuring unit 400, a vertical caliper 510, an identifying unit 700 and the like .

The measurement unit 400 is installed on the lower side of the vertical movement unit 320 described above.

Precisely at the lower one side of the fixed vertical bar 320.

Here, the measuring unit 400 may be one example, and it is not a problem if the measuring unit 400 can measure the length.

The measuring unit 400 has display lines formed at intervals equal to the intervals of the photosensors 30 arranged at regular intervals of the laser sight 20. [

Here, a display protrusion indicating the position of the display line of the measuring unit 400 may be formed at an open portion of the predetermined area on one side of the slide moving plate 330.

Therefore, when the slide moving plate 330 moves upward or downward according to the controlled rotation of the motor 100, the position where the slide moving plate 330 is moved to the upper or lower position can be grasped, The position of the photosensor 30 which reacts with the level 10 can be confirmed.

The laser starter 20 testing apparatus according to one embodiment of the present invention may be provided with a vertical caliper 510.

The vertical caliper 510 can hold the point at zero point regardless of the position of the laser starter 20 and can accurately set the zero point of the measuring unit 400.

A horizontal plate 500 may be formed on one side of the vertical movement unit 320.

That is, the horizontal plate 500 may be formed in a horizontal shape with an open space of a predetermined area on one side of the slide moving plate 330.

The vertical caliper 510 is provided with a measurement arm that abuts on the upper and lower sides of the horizontal plate 500, respectively.

The measuring arm which is in contact with the upper surface of the measurement arm of the vertical caliper 510 moves in contact with the upper surface of the horizontal plate 500 when the horizontal plate 500 moves upward.

As the horizontal plate 500 moves, the measuring arm which is in contact with the upper surface of the measuring arm is moved upward, and the moving distance is displayed through the display unit.

That is, the horizontal plate 500 is installed in the vertical movement unit 320, and the horizontal plate 500 is also moved in accordance with the movement of the vertical movement unit 320, which is moved in accordance with the rotation of the controlled motor 100 , And the vertical caliper 510 displays the movement of the horizontal plate 500 through the display unit.

The position of the photosensor 30 which reacts with the laser of the current rotating laser level 10 can be accurately grasped.

The confirmation unit 700 can identify the photosensor 30 that is responsive to the laser emitted by the rotating laser level 10 among the plurality of photosensors 30 of the laser staff 20.

Here, the confirmation unit 700 can be connected to the laser staff 20 through pairing.

Therefore, the confirmation unit 700 and the laser staff 20 are connected via radio.

The confirmation unit 700 can confirm whether or not the photosensor 30 of the laser staff 20 is responsive to the laser of the rotating laser level 10. [

If the photosensor 30 does not react with the laser of the rotating laser level 10 according to the confirmation unit 700, the user can control the position of the motor 100 through the control unit 800, It can be confirmed whether or not it is responsive to the laser of the rotating laser level 10.

Therefore, it is possible to precisely test whether or not the reaction of the photosensor 30 of the laser staff 20 occurs.

Further, in the laser starter 20 testing apparatus of the present invention, a speed measuring sensor 600 may be additionally provided.

The speed measuring sensor 600 can measure the speed at which the vertical movement unit 320 is moved.

Through this, it can be determined whether the vertical movement unit 320 has performed the controlled movement.

The speed measuring sensor 600 measures the speed at which the vertical moving unit 320 is moved and transmits the measured speed to the confirming unit 700. Accordingly, when the vertical movement unit 320 is moved at a speed other than the predetermined speed, the test apparatus is delivered to the user using the alarm or other method.

Although the present invention has been shown and described with respect to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit of the invention, which is provided by the following claims Will be apparent to those of ordinary skill in the art.

10: rotating laser level 20: laser star
30: Photoelectric sensor 100: Motor
150: gear portion 200: fixed plate
210: flat plate 220: connecting plate
300 vertical moving part 310 vertical fishing fisher
320: fixed vertical bar 330: slide moving plate
340: Fixing hole 400: Measuring part
500: horizontal plate 510: vertical caliper
600: speed measuring sensor 700: confirmation part
800:

Claims (10)

CLAIMS 1. A laser starter testing apparatus for testing whether or not each of the photosensors of a laser star including a plurality of photosensors arranged at regular intervals along a longitudinal direction is responsive to a laser emitted by a laser,
A motor including a shaft for performing controlled rotation;
A gear portion installed on the shaft of the motor and rotated;
A fixing plate on which a laser light is arranged and fixed on an upper surface in a flat shape;
And a vertical gear unit formed along the longitudinal direction so as to be moved along a longitudinal direction perpendicular to the rotary shaft, the gear unit being engaged with the gear unit, A vertical moving part which moves upward or downward as the gear part rotates; And
A control unit connected to the motor to output a controlled signal to control the rotation of the shaft of the motor,
The laser star test apparatus comprising: The method according to claim 1,
Wherein the gear portion is a gear and the vertical gear portion is a pinion
Characterized in that the device is a laser star. The method according to claim 1,
Wherein the vertical moving part comprises:
A fixed vertical bar having a predetermined length,
And a vertical gear portion is formed on the other side to slide the fixed vertical bar upward or downward according to the rotation of the motor,
The laser star test apparatus comprising: The method of claim 3,
On the lower side surface of the fixed vertical bar,
A measurement section having the same interval as the photosensors arranged at regular intervals along the longitudinal direction is formed,
The position of the photosensor that reacts with the laser emitted by the rotating laser level can be confirmed when the slide moving plate is moved in the upper or lower set range according to the rotation of the motor
Characterized in that the device is a laser star. 5. The method of claim 4,
A horizontal plate is provided on one side surface of the slide moving plate,
A vertical caliper including an extension portion formed to abut an upper surface of the horizontal plate and measuring a distance by which the horizontal plate is moved is displayed and the slide movement plate is set to be complementary or lower If the range is moved, it is possible to confirm the position of the photosensor that reacts with the laser emitted by the rotating laser level
Characterized in that the device is a laser star. The method according to claim 1,
The motor is a step motor or a servo motor that can rotate the shaft by a predetermined angle by a control unit
Characterized in that the device is a laser star. The method according to claim 1,
The laser star test apparatus
When the vertical moving part moves upward or downward,
Including a speed measuring sensor capable of measuring the speed of movement
Characterized in that the device is a laser star. The method according to claim 1,
The laser star test apparatus
A confirmation part for confirming a photo sensor which reacts with a laser of a rotating laser level among a plurality of photosensors of the laser star to be tested
Characterized in that the device is a laser star. 9. The method of claim 8,
The confirming unit may be connected to the laser light testing apparatus through wireless connection
Characterized in that the device is a laser star. The method according to claim 1,
Wherein the vertical moving part has a fixed hole formed along the longitudinal direction at a predetermined interval,
Wherein the fixing plate comprises a flat plate on which the laser light is disposed and on which an insertion hole is formed in which the vertical moving part is inserted and a lower flat plate on which the insertion hole is formed, And a connecting plate having at least a bolt hole formed on a side thereof and abutting a side surface of the vertical moving part when the insertion hole is disposed inside the insertion hole,
A bolt may be inserted after fixing one of the fixing holes arranged at the predetermined interval and the bolt hole of the connection plate to fix the position of the vertical movement unit and the fixing plate while adjusting the position
Characterized in that the device is a laser star.

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