KR102213783B1 - Free wide rogowsky coil - Google Patents

Abstract

According to the disclosed present invention, a free wide Rogowski coil includes: a hollow core; a coil winding around the hollow core a plurality of times; and an insulating bonding portion which is wound before one-way or the other-way winding of the coil to prevent loop deformation of the coil wound later by adhesive force. According to the present invention, when winding a coil on the hollow core, the insulating bonding portion is wound before one-way winding of the coil to prevent loop deformation of the coil wound later by adhesive force. Therefore, it is possible to finally improve precision by maintaining alignment winding and reducing a position error, and the inner diameter of the Rogowski coil can be freely adjusted to catch the position error which interferes with the loop formation.

Description

FREE WIDE ROGOWSKY COIL}

The present invention relates to a pre-wide Rogowski coil, and more particularly, to a Rogowski coil capable of implementing a wide loop while freely adjusting the inner diameter size of the Rogowski coil.

Most commonly used current measuring sensors are current transformers. Since the current transformer uses a magnetic core, the current range that can be measured within the specified error range is extremely limited due to magnetic saturation and the limit of measurement range versus size. In addition, it is impossible to accurately detect a fault current reaching tens to hundreds of times the nominal current. In addition, there are many examples of current power devices using a current having a frequency range ranging from several ㎐ to several hundreds ㎑ due to the development of power electronics and pulse power technology, but CT has a limitation in measuring frequency current other than the commercial frequency current.

Due to these problems, a rosowski coil is currently widely used.

Rogowski coils are generally manufactured in a three-dimensional structure by winding the coil around an air core in a toroidal shape around a conductor through which electric current flows. These Rogowski coils are widely used in inverter welding machines, air circuit breakers, gas insulated circuit breakers, motor control monitoring, remote welding machines, electric motors, current measurement of generators, electronic watt-hour meters, and especially as current measurement sensors of power converters and electronic watt-hour meters. .

Such a technique related to the Rogowski coil has been proposed in Korean Patent No. 1707152.

However, Patent Literature 1 has a problem in that the accuracy is degraded because the loop cannot be deformed, and the current measurement error value is generated according to the thickness of the wiring to be measured.

Korean Patent Registration No. 1707152 (2017.02.09)

The present invention has been devised in view of the above points, and an object of the present invention is to provide a pre-wide Rogowski coil that improves precision by reducing a positional error while maintaining an alignment winding.

The pre-wide Rogowski coil according to the present invention for achieving the above object comprises: an air core core; A coil wound reciprocating multiple times around the air core core; And an insulating bonding unit that prevents deformation of a loop of the coil to be wound later by adhesive force by winding one way or the other direction of the coil before winding.

The insulating adhesive part may be an insulating Teflon tape.

The insulating adhesive portions may be attached to each other in an inclined state at both sides of the wound coil.

The Rogowski coil may include a clamp portion that binds the upper and lower ends by a rotation method or by pressing the upper and lower ends so that the Rogowski coil has an inner diameter of any one of a circular shape, a tie type, and a track type.

An inner diameter of the Rogowski coil may be adjusted as the middle of the Rogowski coil is snapped to one side of the clamp part, and a position of the end of the Rogowski coil is moved from the other side of the clamp part.

A position adjusting unit may be provided at each set interval to adjust the biting position of the clamp unit at an end of the Rogowski coil.

A protrusion in a longitudinal direction may be formed on the opposite surface of the position adjusting part.
The pre-wide Rogowski coil according to the present invention is a Rogowski coil 100 for measuring a current, which is fixed to the clamp unit 200 and adjustable in diameter, and includes an air core 110; A first coil 120 wound around the air core 110; An insulating adhesive 130 attached to the first coil 120 and having adhesiveness on both sides; And a second coil 140 wound on the insulation bonding portion 130; wherein the insulation bonding portion 130 includes two insulation bonding portions 130 inclined at both sides of the first coil 120 The Rogowski coil 100 is inserted into and fixed to the second grooves 212b and 222b having stepped jaws and formed by upper and lower cores 221 and 211 of the clamp part 200 at the end of the Rogowski coil 100 A plurality of position adjustment units spaced apart at a set interval to adjust the bite position are provided, and projections 161 are formed on opposite sides of the plurality of position adjustment units so that the upper and lower cores 221 and 211 first groove 212a It is characterized in that the rotation of the Rogowski coil 100 is prevented by being bound to the groove formed on the opposite surface of 222a).

According to the present invention, when winding a coil on an air core core, an insulating adhesive part is wound before one-way winding of the coil to prevent loop deformation of the coil to be wound later by the adhesive force, thereby maintaining the alignment winding and reducing the position error. The precision can be improved, and the inner diameter of the Rogowski coil can be freely adjusted, which has the effect of catching positional errors that hinder the loop formation.

1 is a schematic diagram showing a pre-wide Rogowski coil of the present invention.
2 is a cross-sectional view schematically showing a pre-wide Rogowski coil of the present invention.
3 is a perspective view illustrating a process of attaching an insulating adhesive part on a coil wound on an air core in the pre-wide Rogowski coil of the present invention.
4 is an explanatory view showing a state before and after opening and closing a clamp part of a rotation type so that the pre-wide Rogowski coil of the present invention has a circular inner diameter.
5 and 6 are explanatory diagrams showing the structures of upper and lower cores provided inside a clamp part of a rotation type so that the pre-wide Rogowski coil of the present invention has a circular inner diameter.
FIG. 7 is a side view showing a state in which the free-wide Rogowski coil of the present invention has a circular inner diameter by a rotation type clamp portion and the inner diameter size is adjusted.
8 is a perspective view showing a state before and after the opening and closing of the clamp portion so that the pre-wide Rogowski coil of the present invention has a tie-shaped inner diameter by the clamp portion of the rotation type.
9 is a side view showing a state in which the free-wide Rogowski coil of the present invention adjusts the size of the inner diameter while having a tie-shaped inner diameter by a clamp portion of a rotation type.
10 is a perspective view showing a state before and after the opening and closing of the clamp portion so that the pre-wide Rogowski coil of the present invention has a track-shaped inner diameter by a clamp portion of a rotation type.
FIG. 11 is a side view showing a state in which the free-wide Rogowski coil of the present invention has a track-shaped inner diameter by a rotation type clamp unit and the inner diameter size is adjusted.
12 is an explanatory view showing a state before and after opening and closing a clamp part of a pressing type so that the pre-wide Rogowski coil of the present invention has a circular inner diameter.
13 and 14 are explanatory diagrams showing the structure of upper and lower cores provided inside a clamp part of a pressing type so that the pre-wide Rogowski coil of the present invention has a circular inner diameter.

The above objects, features and other advantages of the present invention will become more apparent by describing in detail a preferred embodiment of the present invention with reference to the accompanying drawings. Hereinafter, a free-wide Rogowski coil according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 14, the pre-wide Rogowski coil 100 of the present invention includes an air core 110, coils 120 and 140, and an insulating adhesive 130.

In this case, the first coil 120 is wound on the air core 110 and then fixed with the insulating adhesive 130 and the second coil 140 is wound. 1 In a state in which the coil 120 is wound, two strands (two or more strands are possible) are prepared, and the second coil 140 may be wound after fixing the two strands with the insulating bonding unit 130.

The air core 110 is formed of a straight line, and is preferably formed of a flexible material such that the coils 120 and 140 are wound around the outer circumferential surface and bent to form a circular shape, a tie shape, and a track shape.

At this time, the air core 110 is preferably formed of any one of plastic, synthetic resin, and non-magnetic metal.

The coils 120 and 140 are reciprocally wound around the air core 110 a plurality of times, and in this embodiment, the position error is improved and the overall size and weight of the product can be reduced while having high precision when measuring a low current. It is exemplified that it is composed of a first coil 120 wound in one direction by winding one way twice and a second coil 140 wound in the other direction, and the number of one-way windings is not limited thereto and may be increased or decreased.

That is, the first coil 120 is wound on the outer circumferential surface of the air core core 110, and the second coil is wound on the surface of the insulating bonding unit 130 while the insulating bonding unit 130 is wound around the surface of the first coil 120. The coil 140 is wound.

Insulation bonding part 130 is wound around the surface of the wound first coil 120 by forming adhesive force on both sides, so that the second coil 140 is wound on the surface of the first coil 120 and the second coil. The arrangement of the coils 140 is not disturbed.

On the other hand, the insulating adhesive part 130 is an insulating Teflon tape or the like is applied thereto, and uses a pressure-sensitive adhesive having high heat resistance to maintain excellent adhesive strength even at a high temperature.

Therefore, the insulating adhesive 130 prevents loop deformation of the first and second coils 120 and 140 by bonding the first coil 120 and the second coil 140 to be wound later by adhesive force to each other by adhesive force. Is done.

In addition, as shown in FIG. 3, the two insulating adhesive parts 130 are attached to each other in an inclined state at both sides of the first coil 120, thereby reducing a positional error while maintaining the alignment winding and increasing the overlapping area. .

And although not shown in the drawing, the pre-wide Rogowski coil 100 may be finished with a tube on the surface.

And the pre-wide Rogowski coil 100 of the present invention is circular (see Figs. 4 and 7), tie type (see Figs. 8 and 9) and track type (Fig. 10 and 11), etc.).

And the Rogowski coil 100 is fixed by biting the middle to one side of the upper and lower cores 221 and 211 located inside the clamp unit 200, and the biting position of the end in a state that is wound to have a circular inner diameter The first, second, and third position adjustment units 160a, 160b, and 160c are fixed at each set interval so that the inner diameter of the winding can be adjusted while moving.

At this time, the clamp part 200 includes a fixing part 210 and a rotation part 220 as shown in FIGS. 4 to 11, but the rotation button 230 and the locking ring 232 are rotated by a rotation method. ) To the fixing part 210, and the first grooves 212a and 222a and the second grooves of the upper and lower cores 221 and 211 on opposite surfaces of the fixing part 210 and the rotating part 220 Each of the semicircular grooves corresponding to the (212b, 222b) is formed, so that the first groove (212a, 222a) and the second groove (212b, 222b) to form a circular shape when combined.

Furthermore, the clamp unit 200 has a rotation engaging groove 2120 and a rotation engaging protrusion 2220 so as to be rotatable when coupled to one side of the opposite surface of the fixing unit 210 and the rotating unit 220.

In addition, a hole 2210 is formed through the fixing part 210 and the other side of the opposite surface of the rotating part 220 so that the rotating button 230 is inserted into the outer surface of the end of the rotating part 220.

In addition, a locking ring 232 at the end of the rotation button 230 inserted into the hole 2210 of the rotation unit 220 is coupled to a rectangular projection and a rectangular groove structure. In this way, while the locking ring 232 is interlocked by the rotation button 230, a second locking protrusion 2320 is provided on the locking ring 232 that is bent so as to be caught or released from the first locking protrusion 2110.

At this time, the end of the rotation button 230 has a protrusion formed so that it is not separated when coupled to the locking ring 232.

In addition, the first locking protrusion 2110 and the second locking protrusion 2320 are formed in a convex shape having an arc shape corresponding to each other.

In addition, the second locking protrusion 2320 extends upright from the bottom of the fixing part 210.

Therefore, when the first position adjustment unit 160a is fixed to the first grooves 212a and 222a formed on the other side of the upper and lower cores 221 and 211, the inner diameter of the Rogowski coil 100 is the largest and the second When the third position adjusting unit 160c is fixed to the grooves 212b and 222b, the inner diameter of the Rogowski coil 100 is the smallest, and the second position adjusting unit 160b is located in the second grooves 212b and 222b. When fixed, the winding inner diameter of the Rogowski coil 100 is formed in a medium size.

In this way, since the length of the Rogowski coil 100 is adjusted without being fixed inside the clamp unit 200, a positional error that interferes with the loop formation is caught.

At this time, the first, second, and third position adjusting parts 160a, 160b, 160c have protrusions 161 formed on opposite sides, so that the facing surfaces of the upper and lower cores 221 and 211 and the first grooves 212a and 222a Rogowski coil 100 is prevented from rotating while being bound to the groove formed in the.

And in the second grooves 212b and 222b formed on one side of the upper and lower cores 221 and 211, a hexahedral protrusion formed on the outer surface of the lead wire connection molding 150 in the middle of one side of the upper and lower cores 221 and 211 The third grooves 214 and 244 having a hexahedral shape larger in size than the second grooves 212b and 222b are formed to be coupled to prevent rotation of the Rogowski coil 100.

At this time, the lead wire connection molding 150 closes the PCB protection cap 162 surrounding the end of the Rogowski coil 100 to protect the PCB (P) positioned between the adjacent lead wire 100 ′.

Here, the PCB protection cap 162 is cut in half in a cylindrical shape, so that the Rogowski coil 100 and the lead wire 100 ′ are inserted into each of the insertion grooves 163a and 136b, and the adjacent one end rotates It is provided so as to be possible, and the adjacent other end is coupled or separated by the protrusion 1631a and the groove 1631b.

The clamp part 200 includes a fixing part 210 and a rotating part 220 to be opened and closed by a rotation method, and considering that the cross-sectional shape of the Rogowski coil 100 is circular, the upper and lower cores 221, Semicircular first grooves 212a and 222a and second grooves 212b and 222b respectively formed on opposite surfaces of 211) are formed on one side and the other side, respectively.

In addition, the fixing part 210 and the rotating part 220 are provided rotatably by a hinge on one side of the opposite surface, and the other side of the opposite surface is provided so as to be bonded through a groove and a protrusion structure having an uneven structure.

Meanwhile, although not shown in the drawings, a noise filter or the like may be provided inside the clamp unit 200.

In the above, a case in which the winding shape of the Rogowski coil 100 is circular has been described as an example, and the tie-type and the track-type are also fixed in the first grooves 212a and 222a of the clamp part 200. 3 Since the size of the inner diameter of the Rogowski coil 100 can be adjusted according to any one of the position adjusting units 160a, 160b, and 160c, a detailed description will be omitted.

In addition, the fixing part 210 of the clamp part 200 is fixed by a fixture such as a wire (not shown in the drawing) and a cable tie to be measured for current.

Referring to FIGS. 12 to 14, the clamp part 200 ′ binds or releases the rotation part 220 ′ to the fixing part 210 ′ by a pressing method by a push button 230 ′ unlike the previous embodiment. Let it. At this time, the clamp part 200 ′ differs only in the structure of the fixing part 210 ′, the rotating part 220 ′, and the push button 230 ′, and the length adjustment structure and method of the remaining Rogowski coil 100, Since the lower cores 221 ′ and 211 ′, the lead wire connection molding 150 and the PCB protection cap 162 have the same structure and function as those of the previous embodiment, detailed descriptions are omitted.

Moreover, the clamp part 200 ′ includes a fixing part 210 ′ and a rotating part 220 ′, and upper and lower cores 221 ′ and 211 ′ on opposite surfaces of the fixing part 210 ′ and the rotating part 220 ′. ') of the first groove (212a', 222a') and the second groove (212b', 222b') and the corresponding semicircular grooves are formed, respectively, when combined, the first groove (212a', 222a') and the 2 Make a circular shape like the grooves 212b' and 222b'.

Moreover, the clamp part 200 ′ is formed with a rotation engaging groove 2120 ′ and a rotation engaging protrusion 2220 ′ so as to be rotatable when coupled to one side of the opposite surface of the fixing part 210 ′ and the rotating part 220 ′. .

And the push button 230' on the upper surface of the end of the rotating part 220' among the other side of the opposite surface of the fixing part 210' and the rotating part 220' is able to move up and down in a state that is energized by a spring (not shown in the drawing). A hole 221 ′ is formed through it to be inserted.

The push button 230 ′ has a driving inclined surface 231 ′ formed on one side thereof, and a separation preventing protrusion C is formed on both sides thereof so as not to be separated from the hole 221 ′. In this way, when the push button 230' is pressed, the driving inclined surface 231' presses the driven inclined surface 2162' of the third locking protrusion 216' extending upright from the bottom surface of the fixing part 210'. In the meantime, when passing through the driven slope 2162 ′, the third locking protrusion 216 ′ interferes with the driving slope 231 ′ by the restoring force.

In the above, the winding shape of the Rogowski coil 100 was described as an example, and the tie-type and the track-type were also fixed in the first grooves 212a' and 222a' of the clamp part 200'. , Since the size of the inner diameter of the Rogowski coil 100 can be adjusted according to any one of the 2nd and 3rd position adjustment units 160a, 160b, and 160c, a detailed description will be omitted.

Further, the fixing part 210 ′ of the clamp part 200 ′ is fixed by a fixture such as a wire (not shown in the drawing) and a cable tie to be measured for current.

In this way, the pre-wide Rogowski coil 100 of the present invention winds the first coil 120 in one direction on the outer circumferential surface of the air core 110, and the insulating adhesive 130 on the surface of the wound first coil 120 Since the second coil 140 is wound in the other direction on the surface of the insulating bonding part 130 in a state of bonding the first coil 120 and the second coil 140 in a process such as bending, the arrangement of the first coil 120 and the second coil 140 is not disturbed. It is possible to implement a wide loop without changing the arrangement.

This enables the alignment winding so that the coils do not overlap and wind uniformly, thereby preventing the loop of the aligned winding coil from being deformed when the air loop of the flexible Rogowski coil is bent.

In addition, the Rogowski coil 100 is in a state in which the protrusion of the lead wire connection molding 150 provided in the middle of one side of the clamp unit 200 and 200 ′ is located in the second grooves 212b and 222b of the clamp unit 200. The first, second, and third position adjustment units 160a, 160b, 160c are formed on the other side of the clamp unit 200 while being bitten and fixed and wound in any one of a circle, a tie type, and a track type. Since the first grooves 212a and 222a are bitten and fixed, the size of the wound inner diameter can be freely adjusted.

In this way, since the size of the wound inner diameter of the Rogowski coil 100 can be freely adjusted, the output value remains the same and there is no deformation of the loop.

At this time, when the clamp unit 200 is a rotation type, if the rotation button 230 is rotated in one direction in order to close the rotation unit 220 from the fixing unit 210, the second locking protrusion 2110 is separated from the second When the locking protrusion 2320 is rotated toward the first locking protrusion 2110 to interfere, and rotating the rotating button 230 in the other direction to open the rotating part 220 at the fixing part 210, the rotating button 230 and The interference is released while the second locking protrusion 2320 of the interlocking locking ring 232 is separated from the first locking protrusion 2110 of the fixing part 210.

On the contrary, when the clamp part 200 ′ is in a pressing method, when the rotating part 220 ′ is closed to the fixing part 210 ′, the driving slope 231 ′ of the push button 230 ′ is After pressing the driven slope 2162 ′ of the third locking protrusion 216 ′ extending from the bottom surface, the driven slope 2162 ′ is caught on the driving slope 231 ′ while passing through the peaks, and When the push button 230 ′ is pressed to open the rotating part 220 ′ at 210 ′, the driving slope 231 ′ of the push button 230 ′ becomes the driven slope of the third locking protrusion 216 ′. By retreating (2162'), it is possible to separate the driving slope 231' and the driven slope 2162'.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features. You can understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting.

100: pre-wide Rogowski coil 110: air core core
120: first coil 130: insulation bonding portion
140: second coil 200, 200': clamp portion
210, 210': fixed part 220, 220': rotating part
230: rotation button 232: locking ring
230': push button

Claims (7)

As a Rogowski coil 100 for current measurement that is fixed to the clamp unit 200 and adjustable in diameter,
An air core 110;
A first coil 120 wound around the air core 110;
An insulating adhesive 130 attached to the first coil 120 and having adhesiveness on both sides; And
Including; a second coil 140 wound on the insulating bonding portion 130,
In the insulating adhesive part 130, two insulating adhesive parts 130 are attached to each other in an inclined state at both sides of the first coil 120,
The end of the Rogowski coil 100 is formed by the upper and lower cores 221 and 211 of the clamp unit 200 and is inserted and fixed into the second grooves 212b and 222b having stepped jaws to adjust the bite position. A plurality of position control units spaced apart are provided,
Protrusions 161 are formed on opposite sides of the plurality of position control units, and are bound to grooves formed on opposite surfaces of the upper and lower cores 221 and 211, and the first grooves 212a and 222a, and the Rogowski coil 100 Free-wide Rogowski coil, characterized in that the rotation is prevented. The method of claim 1,
The insulating adhesive part is a pre-wide Rogowski coil, characterized in that the insulating Teflon tape.
delete The method of claim 1,
It characterized in that it comprises a clamp unit that binds the upper and lower ends by a rotational method or by pressing the upper and lower ends so that the Rogowski coil has an inner diameter of any one of a circle, a tie type, and a track type. Free-wide Rogoski coil.
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