KR101714427B1 - A device for measuring the length and width - Google Patents

Abstract

The present invention relates to a device to measure an entire length and an entire width and, more specifically, relates to a device to measure the entire length and the entire width comprising: a mounting stand placed on a support for an object to be measured to be mounted thereon; a sensor bar coming in contact with one side surface of the object to be measured, wherein the object is mounted on the mounting stand; a displacement sensor into which the sensor bar is inserted; and a pressure fixing bar (400) fixating the object to be measured by applying pressure to the object to be measured in a state of being in contact with one side surface of the object to be measured, wherein the object is mounted on the mounting stand.

Description

Technical Field [0001] The present invention relates to a device for measuring the length and width,

More particularly, the present invention relates to an apparatus for inspecting a full length and a full width of a specific object by contacting only two sides of a sensor bar contacting the four sides of the object to be inspected, The inspection object is moved to the front and rear sides in a state in which the object to be inspected is seated on the seat restraint when the inspection of the total length of the object is made using the displacement sensor having the sensor bar inserted therein To a full length full width inspection apparatus capable of minimizing a measurement error that may be generated.

Measurement of the length in various technical fields is very basic. In the fields of geography measurement, aeronautical satellites, etc., the length is measured in km units. In general industrial fields such as production and construction, The range of lengths to be measured varies depending on the field. Depending on the length range to be measured, the accuracy required in the field may vary accordingly.

Generally, a device for measuring the length and the like includes a measurement sensor. In measuring the length and the like, it is classified into a contact type and a non-contact type inspection device depending on whether such a sensor contacts the object to be inspected.

As a non-contact type inspection apparatus, Korean Unexamined Patent Publication No. 10-1642952 discloses an apparatus and method for measuring a geometric length by using an interferometer using two wavelengths of laser light to measure the length economically and efficiently, To a length measuring device using a two-wavelength laser interferometer.

As another non-contact type inspection apparatus, Korean Unexamined Patent Publication No. 10-1323383, which is a conventional technique, measures the width, height and height of an object to be inspected conveyed through a transfer unit through a sensor, The invention relates to a minimizing method.

However, in the case of such a non-contact type inspection apparatus, it is possible to influence the inspection depending on the material of the inspection object, such as the presence of foreign substances in the inspection object, the fluctuation of the inspection object, It has limitations to guarantee accuracy only when it is controlled.

Disadvantages of the conventional contact type inspection apparatus including the displacement sensor are as follows. When the contact type displacement sensor comes into contact with the object to be inspected, the abrasion of the contact portion in contact with the object to be inspected and the slip in the contact surface occur. There has been a point that it occurs.

As an invention for improving the disadvantages of such a contact type inspection apparatus, Japanese Unexamined Patent Publication No. 10-2011-0031281 discloses an inspection apparatus for mechanically measuring an object to be inspected using a displacement sensor, To thereby improve the accuracy of the measurement value.

However, the prior art Patent Publication No. 10-2011-0031281 discloses a technical feature that minimizes the contact force with the object to be inspected in order to solve the problems caused by wear, slip, and elastic force of the object to be inspected. However, There is not proposed an improvement measure for the problem of measurement error due to a problem due to motion, a minute jumping of the object to be inspected at the moment of sensing, and the like.

(Patent Document 1) KR10-1469224 B

(Patent Document 2) KR10-2011-0031281 A

And an object of the present invention is to provide a full-width full width inspection apparatus capable of minimizing a measurement error due to a minute movement of an object to be inspected by fixing the object to be inspected in order to solve the above-

Furthermore, it is an object of the present invention to provide a full-width full width inspection apparatus capable of minimizing a measurement error caused by a deformation of an object to be inspected (a minute deformation of the object to be inspected according to a pressure applied to the object to be inspected)

Another object of the present invention is to provide a full length full width inspection apparatus capable of preventing an inspection object from being pushed in one direction or deviating from a predetermined position to be measured due to the contact force of the sensor when the sensor contacts or senses the object.

In order to solve the above-described problems, an apparatus for inspecting full length full width according to the present invention comprises: a platform 200 on which a test object is placed; A sensor bar 320 which is in contact with one side of the object to be inspected which is seated on the seat 200; A displacement sensor 340 into which the sensor bar 320 is inserted; And a pressure fixing bar 400 for applying pressure to the object to be inspected in a state of being contacted with one side of the object to be inspected which is seated on the seating table 200 to fix the object to be inspected.

The sensor bar 320 and the pressure fixing bar 400 are linearly reciprocated in a vertical direction on one side of the object to be inspected which is seated on the seat 200.

Preferably, the sensor bar 320 contacts all four sides of the object to be inspected, and the pressure-fixing bar 400 contacts only two of four sides of the object to be inspected.

Preferably, at least one of the sensor bars 320 is brought into contact with the side surface corresponding to the electric field of the object to be inspected and the side surface corresponding to the entire width of the object to be inspected.

Preferably, there are three sensor bars 320 contacting the side corresponding to the total length of the object to be inspected.

Preferably, the pressure-fixing bar 400 contacts only one of the two side surfaces corresponding to the total length of the object to be inspected, and only one of the two side surfaces corresponding to the full width of the object to be inspected do.

Preferably, one end of the pressure-fixing bar 400 contacting the object to be inspected is a flexible material.

Preferably, the pressure fixing bar 400 and the sensor bar 320 are linearly reciprocated by a cylinder.

According to the above-mentioned problem, since the sensor bar is in contact with the object to be inspected while the object to be inspected is fixed by the pressure-fixing bar, the measurement error due to the minute movement of the object to be inspected can be minimized.

Further, when fixing the object to be inspected immediately after the pressure is fixed, pressure is applied only in one direction to fix the object to be inspected in a state in which the inner surface of the object to be inspected is in contact with one side of the mounting table. Since the pressure is not applied, the shape of the object to be inspected is not deformed, so that the measurement error can be minimized.

In addition, when the sensor bar comes into contact with the object to be inspected, the sensor bar is brought into contact with the object to be inspected by a predetermined length so that the measurement error according to the sensor bar set to be moved by a predetermined length Of the object to be inspected can not be measured and a measurement error that may occur can be minimized.

1 is a perspective view of a full-width full width inspection apparatus according to the present invention.
2 is a plan view of the full width full width inspection apparatus according to the present invention.
Fig. 3 is a view showing a state in which an object to be inspected is seated on a seat cushion.
4A is a view showing a state in which the object to be inspected is fixed in a state in which the pressure-fixing bar is in contact with the object to be inspected in a state in which the object to be inspected is seated on the seat.
4B is a view showing a state in which the sensor bar is moved in contact with the object to be inspected while the object to be inspected is fixed by the pressure fixing bar.

Hereinafter, preferred embodiments of the method according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

Will be described with reference to Figs. 1 to 4B.

In the full-width full width inspection apparatus according to the present invention, the "overall length" refers to the total length and width, and the total length corresponds to the length of the object to be inspected, and the width corresponds to the width of the object to be inspected.

 The object to be inspected in the full-width full width inspection apparatus according to the present invention may be any object to be inspected that can be applied to the present invention, and is not limited to any particular object to be inspected. However, in explaining the full-width full width inspection apparatus according to the present invention, a smartphone case will be described as an object to be inspected.

 The full length full width inspection apparatus according to the present invention includes a pedestal 100, a pedestal 200, a sensor unit 300, a pressure fixing bar 400, and a switch 500 located on the main body 10.

The pedestal 100 is placed on the main body 10 to support the object to be inspected.

The seat 200 is formed on the pedestal 100 to match the shape of the object to be inspected. That is, when the object to be inspected is a smartphone case as an embodiment, the seating base 200 may be a frame shape adapted to the shape of the inner side of the smartphone case so that the seating base 200 can be inserted into the smartphone case. Accordingly, when the operator places the smartphone case on the seating table 200 having a predetermined frame shape, the seating table 200 is inserted into the smartphone case, so that the smartphone case is seated on the seating table 200 It is positioned for full-scale full-width inspection.

It goes without saying that the seat 200 may be formed in a frame shape having a predetermined stepped-up portion from the support plate 100. That is, it is needless to say that the seating table 200 having any shape can be used as long as the seating table 200 can position the object to be inspected in a fixed manner for the full-width full-width inspection.

Reference portions 220 and 240 may be positioned on the seating table 200. When the object to be inspected is a smartphone case as one embodiment, the reference portions 220 and 240 are required to discriminate between the upper and lower sides or the left and right sides of the smartphone case that the smartphone case is seated to be positioned on the seating table 200. In addition, when the object to be inspected is placed on the mounting table 200 and the pressure fixing bar 400, which will be described later, applies pressure to the object to be inspected to fix the object to be inspected, To be able to support.

In one embodiment, the reference portions 220 and 240 are formed as a first reference portion 220 and a second reference portion 240. However, the reference portions 220 and 240 may be formed in a shape of an object to be inspected It goes without saying that the shapes of the reference portions 220 and 240 may be changed.

The sensor unit 300 positioned on the main body 10 includes a sensor bar 320 and a displacement sensor 340 into which the sensor bar 320 is inserted. The sensor bar 320 is linearly reciprocated toward one side of the object to be inspected while being inserted into the displacement sensor 340.

As the sensor bar 320 reciprocates linearly, an electrical displacement value is generated in the displacement sensor 340, and the generated electrical displacement value is transmitted to a control unit (not shown) to calculate the total length of the object to be inspected. The displacement sensor 340 is known to those of ordinary skill in the art, and a detailed description thereof will be omitted.

The pressure-fixing bar 400 placed on the main body 10 applies pressure to the object to be inspected in a state in which one side of the object to be inspected is seated on the rest seat 200 to fix the object to be inspected.

That is, after the object to be inspected is placed on the seating table 200, the pressure-fixing bar 400, which is linearly reciprocated, is moved in one direction of the object to be inspected and contacts the object to be inspected. Further, So that the object to be inspected does not move.

The linear reciprocating movement of the sensor bar 320 and the linear reciprocating movement of the pressure fixing bar 400 are performed by the operation of the cylinder. By the fine operation of the cylinder, the sensor bar 320 and the pressure fixing bar 400 are linearly reciprocated in a predetermined length range toward one side of the object to be inspected.

After the object to be inspected is placed on the seating table 200, the pressure fixing bar 400 is moved in front of the sensor bar 320 by the operation of the switch 500 or the position sensor (not shown) The sensor bar 320 is advanced forward to one side of the object to be inspected while contacting with the object to be inspected, and the object to be inspected is brought into contact with the object to be inspected, Total length is measured.

The worker operates the linear reciprocating movement of the sensor bar 320 and the pressure fixing bar 400 through the switch 500 on the main body 10 after the object to be inspected is seated on the seat 200.

The number of switches 500 on the body 10 may be two.

The sensor bar 320 can be sensitive to the surrounding environment in an electric field width measuring apparatus capable of measuring up to several micrometers. When the object to be inspected comes into contact with one side of the object to be inspected in a state where it is not positioned on the seat 200, The movement of the sensor bar 320 may be affected.

Accordingly, the operator is required to pay attention to the sensor bar 320 so that the sensor bar 320 can be operated in a state where the object to be inspected is correctly positioned. Therefore, only when the two switches 500 are turned on at the same time, The bar 320 and the pressure fixing bar 400 can be operated.

Further, the sensor bar 320 and the pressure fixing bar 400 can be operated by the operation of a position sensor (not shown). That is, as the object to be inspected is seated on the seat 200 in a state where a position sensor (not shown) positioned on the body 10 is sensing a predetermined point of the seat 200, It is possible to control the sensor bar 320 and the pressure fixing bar 400 through a control unit (not shown) after a predetermined time elapses when the position sensor (not shown) can not sense a predetermined point. have.

A plurality of such position sensors (not shown) may be provided, and a plurality of position sensors (not shown) may sense a plurality of the predetermined points. So as to increase the accuracy of the correct position of the object to be inspected.

The sensor bar 320 and the pressure fixing bar 400 are moved forward to one side of the object to be inspected which is seated on the seat 200 and moved in a vertical direction to one side of the object to be inspected.

When the pressure fixing bar 400 is moved in front of the sensor bar 320 and the object to be inspected is fixed by applying pressure to the object to be inspected, When the bar and the pressure fixing bar 400 are vertically contacted with one side of the object to be inspected and contacted obliquely without being contacted, the direction of the pressure is applied in a direction different from the vertical direction so that the object to be inspected is slightly out of the position And thus an error in measurement occurs.

Likewise, even in the case of the sensor bar 320, if the sensor bar 320 is moved vertically to one side of the object to be inspected, and contacts the sensor bar 320 obliquely without contacting the sensor bar 320,

As described above, the sensor bar 320 and the pressure-fixing bar 400 are linearly reciprocated in a vertical direction on one side of the object to be inspected. The sensor bar 320 and the pressure- When a predetermined point on one side of the object to be inspected is touched, but when a certain point is touched on a certain side, the object is linearly reciprocated in parallel with each other.

When the object to be inspected is a smartphone case, the seating pad 400 may have a shape having four sides so that the inner surface of the smartphone case can be seated.

After the four side faces of the smartphone case are seated on the seat 400, the pressure fixing bar 400 contacts the two sides of the four sides of the smartphone case by cylinder operation to apply pressure to the smartphone case . Specifically, the pressure fixing bar 400 contacts only one side of two sides corresponding to the total length of the smartphone case, and contacts only one side of two sides corresponding to the full width of the object to be inspected.

When pressure is applied to the four side surfaces of the smartphone case 400 that are seated on the seating table 400 by contacting the pressure fixing bar 400, the pressure applied to one side and the other side corresponding to the pressure side is correspondingly A temporary distortion such as a minute distortion may occur in the form of a smartphone case, and thereafter, an error occurs in measurement by the sensor bar 320 naturally.

Therefore, pressure is applied to only one of the two sides corresponding to the electric field so that the smartphone case is pushed in one direction. The side of the seat 200 and the inner side of the smartphone case are pushed in one direction while being in contact with each other. When the side of the seating table 200 and the inner side of the smartphone case are closely contacted, And such a state lasts while the sensor bar 320 measures the electric field.

Further, the side surface of the seat 200 functions to support the pushing of the smartphone case, and at the same time, supports the reference portions 220 and 240 formed in a shape corresponding to the shape of the inner side of the smartphone case .

The case of full width is the same as the case of the above-mentioned electric field.

The function of the pressure fixing bar 400 is to fix the object to be inspected by applying pressure to the object to be inspected, and one end of the pressure fixing bar 400 contacting the object to be inspected is preferably made of a soluble and flexible material.

When the object to be inspected is a smartphone case, the sensor bar 320 is brought into contact with all four sides of the smartphone case. A full-width full width inspection apparatus according to the present invention is a contact-type inspection apparatus. In order to measure an electric field, it is necessary for the sensor bar 320 to contact both sides corresponding to an electric field. The same is true for the full width.

In general, for smartphone cases, the total length is much longer than the full length. As the length increases, the measured value at a certain distance from the measured value at a certain point may be different. Therefore, only one sensor bar 320 is contacted to the side corresponding to the electric field, In case of measurement, error of measurement may occur.

Accordingly, when the length of the electric field is long, it is preferable that a plurality of sensor bars 320, which are positioned at regular intervals, contact the side corresponding to the electric field to inspect the entire width of the smartphone case.

Even if the entire length of the full width is long, the length of the electric field at another point may be different from the predetermined point of the side corresponding to the full width. Therefore, the plurality of sensor bars 320 as described above may check the electric field of the smartphone case .

In the case of a rectangular smart phone case, it is preferable that there are three sensor bars 320 contacting the side corresponding to the whole length, and one sensor bar 320 contacting the side corresponding to the entire width is preferable.

Likewise, in the case of the pressure-fixing bar 400, it is preferable to apply a pressure in a state in which a plurality of pressure-fixing bars 400 are in contact with the side surface depending on the length of the side surface.

The linear reciprocating movement of the sensor bar 320 and the pressure fixing bar 400 will be described.

As described above, after the object to be inspected is placed on the seating table 200, the sensor bar 320 and the pressure fixing bar 400 are moved in a straight line direction to the object to be inspected by the operation of the switch 500 or the position sensor .

The sensor bar 320 may be moved in a straight line direction toward the one side of the object to be inspected in a state where the object to be inspected is fixed in a state in which the pressure- And the total length of the electric field is measured by contacting the object to be inspected.

After the electric displacement value is measured by the displacement sensor 340, the sensor bar 320 is returned to the original state by the control of the controller (not shown), and then the pressure fixing bar 400 is also returned to the object to be inspected It falls back to the original again.

The measured full length full width value is output to the monitor on the main body 10. [

A method of measuring the full length of the object to be inspected will be described.

After the object to be inspected is placed on the platform 200, the pressure-fixing bar 400 is moved to contact the object to be inspected. A distance to which the pressure fixing bar 400 is moved in a state of being in contact with the master inspection object, a pressure to be applied to the inspection object, and the like are set in a control unit (not shown). After the object to be inspected is placed on the mounting table 200, the pressure fixing bar 400 contacts the object to be inspected by the set distance and presses the object with the set pressure.

The distance by which the pressure fixing bar 400 is linearly moved is maintained longer than the moving distance in the master inspection object and is covered to a predetermined error range since an error can be produced in the full- .

In the case of the sensor bar 320, it is preferable that the sensor bar 320 is set to be longer than the length in contact with the master inspection object in consideration of the defective product.

For example, if a state in which the distance moved is longer than the movement distance of the sensor bar 320 in contact with one side of the master inspection object by about 2 mm (the maximum error range that can be generated) is set as a zero point, The sensor bar 320 will be moved toward the object to be inspected within a distance range set to zero.

At this time, if the measured value is the same as the zero point (the product is 2 mm longer than the master inspection object), it is determined that the sensor bar 320 has moved to the zero distance and that the sensor bar 340 is in contact with the object to be inspected If it is not moved to the set zero point, it is judged to be normal product if a short measurement value of 2 mm is obtained at zero point. Further, if the measured value in this state is not more than 3 mm shorter than the zero point, it is judged as a defective product.

As described above, the sensor bar 320 is also linearly reciprocated by the cylinder. Unlike the pressure-fixing bar 400, the pressure applied to the object by the sensor bar 320 in contact with the object is almost insufficient, The movement is stopped at the same time as the object is contacted. The moving distance of the sensor bar 320 is measured in the interrupted state.

In the case of a smartphone case, which is an embodiment of the present invention, the moving distance of the sensor bar 320, which is in contact with both sides corresponding to the total length, is transmitted to a controller (not shown), and the moving distance of the sensor bar 320 measured on both sides And the electric field value is measured. The same applies to full width.

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. It will be appreciated that embodiments are possible. Accordingly, the scope of protection of the present invention should be determined by the claims.

10: Body
100:
200: seat
220: first reference part
240: second reference part
300:
320: Sensor bar
340: displacement sensor
400: Pressure fixing bar
500: Switch
A: object to be inspected

Claims (8)

A base plate (100) positioned on the body (10);
A seating table 200 placed on the bed plate 100 to seat the object to be inspected;
A sensor bar 320 which is in contact with one side of the object to be inspected which is seated on the seat 200;
A displacement sensor 340 into which the sensor bar 320 is inserted; And
And a pressure fixing bar (400) for fixing the object to be inspected by applying pressure to the object to be inspected while being in contact with one side of the object to be inspected (200)
A plurality of reference portions 220 and 240 formed in a shape corresponding to the inner surface shape of the object to be inspected are positioned on the seating table 200. The plurality of reference portions 220 and 240 are positioned on the seating table 200 by the pressure fixing bar 400, So that the object to be inspected is not pushed,
A position sensor for sensing a predetermined point of the seating table 200 is positioned on the main body 10 to sense whether the subject is seated on the seating table 200. The sensor bar 320 and the pressure fixing Bar 400 is actuated by the sensing of the position sensor,
The moving distance of the sensor bar 320 and the pressure fixing bar 400 is input to the control unit while the moving distance of the sensor bar 320 and the pressure fixing bar 400 is in contact with the master inspection object, Is longer than the length of the contact state,
After the object to be inspected is placed on the seat 200, the pressure fixing bar 400 is moved toward the object to be inspected before the sensor bar 320.
Wherein the sensor bar (320) is detached from the object to be inspected before the pressure fixing bar (400) is returned to its original state after the full length full width measurement of the object to be inspected is completed.
The method according to claim 1,
Wherein the sensor bar (320) and the pressure fixing bar (400) are linearly reciprocally moved in a vertical direction on one side of an object to be inspected which is placed on the seating table (200).
3. The method of claim 2,
Wherein the sensor bar (320) is in contact with all four sides of the object to be inspected, and the pressure fixing bar (400) is in contact with only two sides of the four sides of the object to be inspected.
The method of claim 3,
Wherein at least one of the sensor bars (320) is in contact with a side surface of the object to be inspected and a side surface corresponding to the entire width of the object to be inspected.
5. The method of claim 4,
And the sensor bar (320) contacting the side corresponding to the electric field of the object to be inspected is three.
The method of claim 3,
The pressure-fixing bar 400 is configured to be in contact with only one side surface of two sides corresponding to the total length of the object to be inspected, and to make contact with only one of the two sides corresponding to the full width of the object to be inspected Device.
The method according to claim 6,
Wherein one end of the pressure fixing bar (400) which is in contact with the object to be inspected is a flexible material.
8. The method of claim 7,
Wherein the pressure fixing bar (400) and the sensor bar (320) are linearly reciprocated by a cylinder.

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