KR102429423B1 - Resistance measuring apparatus for only heating film - Google Patents

Abstract

The present invention relates to a resistance measuring device dedicated to a heating film which can measure resistance of a carbon electrode provided in a moving heating film by contacting the carbon electrode formed on the continuously transported heating film and measuring the resistance and can quickly inspect quality of the heating film by calculating power consumption through the measurement. The resistance measuring device dedicated to a heating film comprises: a probe module sensing a resistance value by contacting a carbon electrode in a width direction formed at regular intervals along a length direction of a heating film; a probe mount having the probe module rotatably installed for contact with the heating film; a probe guide having the probe mount installed at a front end part and adjusting a position of the probe module according to a width of the heating film; and a guide mount fixed and installed on an upper side of a guide bracket to guide movement of the probe guide in the width direction. Accordingly, the resistance of the carbon electrode formed on the moving heating film can be measured quickly and accurately, and the power consumption of a product can be calculated through the measurement.

Description

Heating film resistance measuring device {RESISTANCE MEASURING APPARATUS FOR ONLY HEATING FILM}

The present invention relates to a resistance measuring device dedicated to a heating film, and more particularly, it is possible to measure the resistance of a carbon electrode provided in a moving heating film by contacting a carbon electrode formed on a continuously transferred heating film and measuring the resistance, By calculating the power consumption through this, it relates to a heating film-only resistance measuring device that enables quick inspection of the quality of the heating film.

The heating film is used for heating, etc., and carbon electrodes are formed at regular intervals. These carbon electrodes are formed through the printing process, and serve as a key factor in determining the heating performance of the heating film.

The resistance of these carbon electrodes is controlled through the printing process depending on the product, but as the operator manually measures the resistance using a portable resistance measuring instrument, an error occurs in the measured value. There is a problem that the entire product must be discarded because defects are generated due to errors during inspection.

In addition, during carbon electrode printing, as the diluent constituting the carbon compounding agent evaporates, the resistance increases at the same line speed, and as a probe is used to measure the resistance, pinholes and scratches occur. There is also the issue of hiring workers.

In addition, due to the error of resistance value before and after printing and drying due to evaporation of the diluent and the lack of reliability of the measurement value due to manual operation, the loss of raw materials increases and production decreases as the process of mixing, printing and drying is usually repeated 2-3 times. there is a problem with

In this regard, Korean Patent Laid-Open Publication No. 10-2010-0078616 discloses an integrated circuit chip including a plurality of connection bumps for applying an electrical signal; a substrate having a plurality of test pads to be respectively connected to the plurality of connection bumps through an anisotropic conductive film to receive electrical signals, the intervals between the plurality of test pads being different from each other; and an insulation resistance measuring device capable of measuring the insulation resistance between a pair of adjacent test pads among the plurality of test pads, wherein the insulation resistance measuring device of an anisotropic conductive film includes test pads arranged at different intervals. And a test method of an anisotropic conductive film using the same has been proposed and disclosed, but this method has a disadvantage in that the resistance acting on the carbon electrode of the heating film in motion cannot be measured.

In addition, in Korean Patent Laid-Open No. 10-2011-0075668, in a three-terminal electrode structure for measuring the connection resistance of an anisotropic conductive film used to connect a metal pattern and an electrode of a printed circuit board, any one of the three-terminal electrodes By forming an additional electrode branched from the electrode terminal of Although a three-terminal electrode structure for measuring the connection resistance of an anisotropic conductive film capable of measuring the connection resistance of the conductive film has been proposed and disclosed, this also cannot measure the resistance acting on the carbon electrode of the heating film in motion. There is this.

In addition, in Korean Patent Application Laid-Open No. 10-2020-0135965, a probe unit disposed opposite to the conductive film and the probe unit are scanned in an intersecting direction intersecting with one direction over both a transport region and a non-transport region of the conductive film. a scanning unit and an arithmetic unit for calculating a sheet resistance of the conductive film based on the voltage measured by the probe unit, wherein the arithmetic unit has a memory for storing a reference voltage measured in a non-carrying area, the probe unit conveying Proposed and disclosed a resistance measuring device for measuring the sheet resistance of an elongated conductive film in one direction by correcting an actual voltage measured by scanning the region in a cross direction based on a reference voltage, an apparatus for manufacturing a film, and a method for manufacturing a conductive film, However, there is a disadvantage that it is impossible to estimate the resistance acting on the carbon electrode of the heating film in motion using this.

Laid-Open Patent Publication No. 10-2010-0078616 Laid-Open Patent Publication No. 10-2011-0075668 Unexamined Patent Publication No. 10-2020-0135965

Therefore, the present invention has been devised in consideration of and solving the above-mentioned problems, and by measuring the resistance by contacting the carbon electrode formed on the continuously transferred heating film, it is possible to measure the resistance of the carbon electrode provided in the moving heating film. The purpose of this is to provide a resistance measuring device dedicated to the heating film that can quickly inspect the quality of the heating film by calculating the power consumption through this.

In addition, another object is to provide a heating film-only resistance measuring device capable of preventing the occurrence of pinholes and scratches by using a detection roller instead of a probe in contact with the carbon electrode of the heating film.

A heating film-only resistance measuring device according to the present invention for achieving the above object includes: a probe module for sensing a resistance value in contact with a carbon electrode in the width direction formed at regular intervals along the length direction of the heating film; a probe mount on which the probe module is rotatably installed for contact with the heating film; a probe guide having a probe mount installed at the front end and adjusting the position of the probe module according to the width of the heating film; and a guide mount that is fixedly installed on the upper side of the guide bracket to guide the width direction movement of the probe guide.

Here, the probe module is provided with a probe block rotatably installed on the probe mount, a detection roller rotatably installed on the tip of the probe block so as to be in contact with the heating film, and a communication unit to detect the resistance detected by the detection roller. It may include a sensing unit installed on the upper side of the probe block to transmit and a tension spring provided on a hinge shaft rotatably connecting the probe block to the probe mount to apply tension to the detection roller.

Here, the detection roller is connected to the tip of the probe block by a roller shaft, and the probe module may further include a probe roller coaxially connected to the detection roller to stabilize the rotation of the detection roller.

Here, the probe guide may include a guide groove into which a guide projection provided on the guide mount is inserted, and the guide groove may be formed at least on both sides of the probe guide.

Here, the guide mount is formed by bending both ends in the width direction downward, and the body is fixed to the upper side of the guide bracket, is fixed to both sides of the upper surface of the body to guide the movement of the probe guide, and is inserted into the guide groove of the probe guide at the inner upper end It may include a pair of guide blocks formed with guide projections.

Here, the mount bracket may be provided with a plurality of mounting grooves to be detachably installed in the heating film production facility.

Here, it may be arranged in pairs to be respectively installed on both sides of the width direction of the heating film.

The heating film-only resistance measuring device according to the present invention can quickly and accurately measure the resistance of the carbon electrode formed on the moving heating film as the detection roller of the probe module comes into contact with the carbon electrode formed on the heating film and rotates. A useful effect of being able to calculate power consumption can be obtained.

According to the present invention, as the probe block of the probe module is rotatably coupled to the probe mount by the hinge shaft, and a tension spring is provided on the hinge shaft, the detection roller is brought into close contact with the carbon electrode of the heating film to each carbon provided in the heating film. A useful effect of being able to measure the resistance of the electrode without omission can be obtained.

According to the present invention, as the probe module is provided with a roller coaxially connected to the detection roller, it is possible to obtain a useful effect of stabilizing the rotation of the detection roller.

According to the present invention, as the probe guide is movably coupled to the guide mount, it is possible to obtain a useful effect of being able to measure the resistance of the carbon electrode regardless of the width of the heating film.

According to the present invention, as the guide bracket on which the probe guide is installed is detachably installed in the heating film manufacturing facility, it is possible to measure the resistance of the carbon electrode in the process of manufacturing the heating film, and through this, the manufacturing process of the heating film is improved. The useful effect of being able to automate can be achieved.

According to the present invention, it is possible to achieve a useful effect of improving the reliability of the measured value as it is disposed on both sides of the heating film in the width direction to measure the resistance of the carbon electrode.

1 is a reference view showing a state of measuring the resistance value of the heating film by using a resistance measuring device dedicated to the heating film according to the present invention.
2 is a perspective view showing an enlarged state of the heating film-only resistance measuring device and the main part according to the present invention.
Figure 3 is a bottom perspective view showing a heating film dedicated resistance measuring device according to the present invention.
4 is an exploded perspective view of a heating film-only resistance measuring device according to the present invention.
5 is a plan view and an enlarged view of a heating film-only resistance measuring device according to the present invention.
6 is a front view and an enlarged view of the heating film-only resistance measuring device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The terms used in the present invention are terms defined in consideration of the functions in the present invention, which may vary depending on the intention or custom of the user or operator, so the definitions of these terms correspond to the technical matters of the present invention and should be interpreted as a concept.

1 to 6 of the accompanying drawings are views illustrating a heating film-only resistance measuring device according to an embodiment of the present invention.

As shown in FIGS. 1 to 6, the heating film-only resistance measuring device according to the present invention includes a probe module 10, a probe mount 20, a probe guide 30, a guide mount 40, and a guide bracket 50 ), and arranged in pairs to be installed on both sides of the heating film 100 in the width direction, respectively. Accordingly, the reliability of the result of measuring the resistance of the carbon electrode is improved.

The probe module 10 is in contact with the carbon electrode 105 in the width direction formed at regular intervals along the length direction of the heating film 100 to sense the resistance value.

Specifically, as shown in FIG. 4 , the probe module 10 includes a probe block 11 rotatably installed on the probe mount 20 , and a tip of the probe block 11 so as to be in contact with the heating film 100 . A detection roller 14 rotatably installed in the , and a communication unit provided with a detection unit 12 installed on the upper side of the probe block 11 to sense and transmit the resistance detected by the detection roller 14, and the detection It includes a probe roller 13 coaxially connected to the detection roller 14 and a tension spring 15 for applying tension to the detection roller 14 so as to stabilize the rotation of the roller 14 .

As described above, as the resistance of the carbon electrode 105 is measured using the detection roller 14, pinholes or scratches do not occur, unlike using a probe.

Here, in addition to the roller probe, a soft thin-film rod-type probe (not shown) is adopted, and in addition, a plate-shaped spring is added to the bottom surface of the rod-type probe to give elasticity when measuring the resistance of the carbon electrode 105, thereby causing pinholes or scratches. It may be adopted as a configuration to prevent

At this time, the tension spring 15 is provided on the hinge shaft 16 that rotatably connects the probe block 11 to the probe mount 20, and is preferably formed in the form of a torsion spring to have a constant tension. .

And it is more preferable that one or more bearings 17 are installed between the hinge shaft 16 and the probe mount 20 so that the probe block 11 can freely rotate.

Unexplained reference numeral 18 denotes a roller shaft connecting the probe roller 12 and the detection roller 14 to the tip of the pro block 11 .

Therefore, the detection roller 14 can be brought into close contact with the carbon electrode 105 of the heating film 100 by using the tension spring 15, and the detection roller 14 can freely move according to the movement of the heating film 100. As it rotates, resistance can be measured.

The probe mount 20 is installed at the tip of the probe guide 30 to support the probe module 10 , and the probe module 10 can be rotated so that the detection roller 14 can come into contact with the heating film 100 . to be installed

The probe mount 20 is preferably made of an MC-based engineering plastic that has excellent electrical resistivity and is advantageous for processing and fixing parts.

The probe guide 30 is movably installed on the guide mount 40 so that the position of the probe module 10 can be adjusted according to the width of the heating film 100. By hard anodizing Al6061 T6 high-strength aluminum It is designed and manufactured to reduce weight and improve hardness to minimize friction and deformation.

At this time, the probe guide 30 is provided with a guide groove 35 into which the guide protrusion 41 ′ provided on the guide mount 40 is inserted, and the guide groove 35 is at least on both sides of the probe guide 30 , respectively. is formed

In addition, when the guide protrusion is formed on the upper surface of the guide mount 40 , guide grooves 36 may be formed on the upper and lower surfaces of the probe guide 30 , respectively.

Accordingly, the probe guide 30 can move only in the horizontal direction.

And, it is preferable that the probe guide 30 passes the measuring wire through the inside to minimize the exposure of the wire to the outside, thereby minimizing the interference to the existing work site.

The guide mount 40 supports the probe guide 30 and guides the movement of the probe guide 30 in the width direction. It is formed by precision processing to become

Specifically, the guide mount 40 is formed by bending both ends in the width direction downward, the body 41 fixed to the upper side of the guide bracket 50 , and the upper surface of the body 41 to guide the movement of the probe guide 30 . It may include a pair of guide blocks 42 fixed on both sides, each having a guide protrusion 42 ′ inserted into the guide groove 35 of the probe guide 30 at the inner upper end thereof.

At this time, the reinforcement block 43 may be further installed on the outside of the one side guide block 42 .

The guide bracket 50 is to fix the guide mount 40, the guide mount 40 is installed at the upper end, and has a plurality of mounting grooves 55 so that it can be used by attaching it to a heating film production facility.

The guide bracket 50 is made of SS41 steel, and the parts are manufactured by bending and welding after laser processing.

Therefore, it is possible to use by being attached and fixed to the heating film production facility through the mounting groove, or to be stored separately from the heating film production facility.

Accordingly, the measurement of the resistance of the heating film using the resistance measuring device for the heating film according to the present invention having the above-described configuration will be described as follows.

A guide bracket 50 is installed on the outlet side of the heating film manufacturing facility, and the probe guide 30 is installed on the guide mount 40 installed on the guide bracket 50 .

Next, the probe module 10 is rotatably installed on the probe mount 20 provided at the tip of the probe guide 30 .

And, by adjusting the position of the probe guide 30 corresponding to the width of the heating film 100 to be manufactured, the detection roller 14 of the probe module 10 is in contact with the carbon electrode 105 of the heating film 100. make it possible

At this time, it is preferable to arrange the resistance measuring device respectively on both sides of the heating film 100 in the width direction.

When the heating film 100 arrives at the part where the measuring device is installed, the probe block 11 of the probe module 10 is rotated so that the detection roller 14 is in close contact with the carbon electrode 105 of the heating film 100, In this state, the resistance of the carbon electrode 105 is measured.

At this time, the measured data is distinguished as a pure value without going through a filter, and only the data within the range of the minimum and maximum measured values are set as valid measurement resistance. process

Accordingly, it is possible to effectively measure the resistance of the carbon electrode 105 provided in the heating film 100 produced and transported in the heating film manufacturing facility.

The embodiments described above are merely illustrative of preferred embodiments of the present invention, and are not limited to these embodiments, and various modifications and variations by those skilled in the art within the technical spirit and claims of the present invention It will be said that this can be done, and it will be said that it falls within the technical scope of the present invention.

10: probe module 11: probe block
12: sensing unit 13: probe roller
14: detection roller 15: tension spring
16: hinge pin 17: bearing
18: roller shaft 20: probe mount
30: probe guide 35, 36: guide groove
40: guide mount 41: body
42: guide block 42': guide projection
43: reinforcement block 50: guide bracket
55: mounting groove 100: heating film
105: carbon electrode

Claims (7)

a probe module for sensing a resistance value by being in contact with a carbon electrode in the width direction formed at regular intervals along the length direction of the heating film;
a probe mount on which the probe module is rotatably installed for contact with the heating film;
a probe guide having a probe mount installed at the front end and adjusting the position of the probe module according to the width of the heating film; and
Heating film-only resistance measuring device, characterized in that it comprises a; guide mount that is fixedly installed on the upper side of the guide bracket to guide the movement of the probe guide in the width direction.
The method according to claim 1,
The probe module is provided with a probe block rotatably installed on the probe mount, a detection roller rotatably installed on the tip of the probe block so as to be in contact with the heating film, and a communication unit to detect and transmit the resistance detected by the detection roller. A heating film-only resistance measuring device, comprising: a sensing unit installed on the upper side of the probe block; and a tension spring provided on a hinge shaft that rotatably connects the probe block to the probe mount to apply tension to the detection roller.
3. The method according to claim 2,
The detection roller is connected to the tip of the probe block by a roller shaft,
The probe module is a heating film-only resistance measuring device, characterized in that it further comprises a probe roller coaxially connected to the detection roller so as to stabilize the rotation of the detection roller.
The method according to claim 1,
The probe guide has a guide groove into which the guide projection provided on the guide mount is inserted,
The guide groove is a heating film dedicated resistance measuring device, characterized in that each formed on both sides of the probe guide at least.
The method according to claim 1,
The guide mount is formed by bending both ends in the width direction downward, a body fixed to the upper side of the guide bracket, and a guide protrusion that is fixed on both sides of the upper surface of the body to guide the movement of the probe guide, and is inserted into the guide groove of the probe guide at the inner upper end Heating film-only resistance measuring device, characterized in that it comprises a pair of guide blocks formed.
The method according to claim 1,
Heating film-only resistance measuring device, characterized in that the mount bracket is provided with a plurality of mounting grooves and is detachably installed in the heating film production facility.
7. The method of any one of claims 1 to 6,
Heating film-only resistance measuring device, characterized in that it is arranged in pairs to be installed on both sides of the heating film in the width direction.

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