DE102017112349A1 - Method and device for insulation test - Google Patents

Abstract

Method and device for insulation test, wherein the device comprises an insulation test device (100, 200) for performing an insulation test inside a hollow insulating body (108), wherein the insulation test device (100, 200) comprises a tensioning device (102, 202) which is of a flexible type electrically conductive jacket (104) is surrounded, wherein the clamping device (102) is formed such that the flexible electrically conductive sheath (104) by the clamping device (102) can be clamped, wherein the flexible electrically conductive sheath (104) at least in sections at a Inner surface (110) of the insulating hollow body (108) is present.

Description

The invention relates to a method and a device for insulation test, in particular in the interior of an insulating body.

The insulating body is for example a tube or a can. For an insulation test, in particular inside a tube or a can, the result of an insulation measurement of an insulating body is considered. The insulation measurement determines an insulation resistance and a dielectric strength. The insulation measurement depends on a measuring surface. When performing an insulation measurement with a brush, the measurement surface varies. As a result, measurement results are not reproducible and a detection probability of insulation errors low.

It is therefore desirable to increase the reproducibility of the measurement results and the probability of detection of insulation faults.

For this purpose, the insulation measurement is carried out, for example, with a tensioning device which is introduced into the interior of the insulation body and is enlarged in the interior of the insulation body until the electrodes of the tensioning device lie flat against an inner surface of the insulation body.

Out DE 10 2012 214 231 A1 and DE 10 2012 214 738 A1 For example, a method and a device for controlling the insulating properties of a metal battery housing with insulation is known, wherein at least one electrical electrode is deformable and completely covers itself against the inner measuring surface or the outer measuring surface, whereby a flat control of the insulating properties takes place.

US 2001/0052778 A1 discloses a method and apparatus for controlling insulation properties of insulated cables, wherein a hollow-shaped inflatable cushion has a flat electrode on the inside, the insulated cables laid inside the inflatable cushion, the pad inflated, and the cables and electrode energized so that an areal control of the insulation of the cables takes place.

US Pat. No. 6,225,813 B1 discloses an apparatus for controlling the insulating properties of insulated stator windings in large industrial engines or generators having an inflatable cushion and an electrode disposed on the cushion.

US 4 482 860 A discloses a measuring device for measuring the surface structure of a hollow cylindrical body, wherein a sensor is pressed to the surface via the inflation of an inflatable cushion arranged in the interior of the hollow cylindrical body.

The present invention addresses the problem of providing an improved method and apparatus for an insulation test.

With respect to the device, this problem is solved by an insulation test device for performing an insulation test inside a hollow insulating body comprising a clamping device, which is surrounded by a flexible electrically conductive jacket, wherein the clamping device is designed such that the flexible electrically conductive jacket by the clamping device can be clamped, wherein the flexible electrically conductive jacket rests against an inner surface of an insulating hollow body.

Preferably, the electrically conductive jacket comprises an electrically conductive knit fabric.

Advantageously, the tensioning device comprises a coupling gear with a screw drive.

Advantageously, the clamping device comprises a spindle for driving the screw drive.

Advantageously, the tensioning device comprises an inflatable cushion.

Advantageously, the inflatable cushion is surrounded by an electrically conductive knitted fabric, wherein the electrically conductive jacket comprises the electrically conductive knit fabric.

Advantageously, the inflatable cushion is surrounded by an electrically conductive knitted fabric, wherein the inflatable cushion is made of the electrically conductive knit fabric. The electrically conductive knit fabric can also be made flexible.

Preferably, the insulation test device comprises a connecting line, wherein the inflatable cushion is inflatable via the connecting line.

Advantageously, the insulation test device has a test device which is electrically conductively connectable to the flexible electrically conductive jacket on the one hand and to an at least partially electrically conductive frame on the other hand, wherein the at least partially electrically conductive frame touches an outer surface of the hollow insulating body.

Advantageously, the clamping device comprises at least part of an electrical connection between the test device and the electrically conductive jacket.

Regarding the method is provided for an insulation test, that a clamping device of an insulation tester is at least partially disposed inside a hollow insulating body, wherein a flexible electrically conductive sheath is moved by the tensioning device from an initial position to an end position in which the flexible electrically conductive sheath and touching an inner surface of the insulating hollow body, and wherein in the end position, a continuity test and / or a dielectric strength test between the flexible electrically conductive sheath and an electrically conductive frame is performed, wherein the electrically conductive frame contacts an outer surface of the hollow insulating body.

• 1 schematisch eine erste Vorderansicht einer ersten Isolationstesteinrichtung,
• 2 schematisch eine erste Seitenansicht der ersten Isolationstesteinrichtung,
• 3 schematisch eine zweite Vorderansicht einer zweiten Isolationstesteinrichtung,
• 4 schematisch eine zweite Seitenansicht der zweiten Isolationstesteinrichtung.

Other features and advantages of the invention will become apparent from the dependent claims, from the description, and from the drawing. In the drawing shows:

• 1 schematically a first front view of a first insulation tester,
• 2 schematically a first side view of the first insulation tester,
• 3 schematically a second front view of a second insulation tester,
• 4 schematically a second side view of the second insulation tester.

In the figures, like reference numerals refer to like, similar or functionally identical components.

1 schematically shows a front view of a first insulation tester 100 , The first insulation tester 100 includes a tensioning device 102 that of a flexible electrically conductive jacket 104 is surrounded. The flexible electrically conductive jacket 104 is preferably extensible in all directions. Preferably, the electrically conductive jacket comprises 104 an electrically conductive knit fabric.

The tensioning device 102 is designed to the flexible electrically conductive jacket 104 to span.

The first insulation test device 100 is to carry out an insulation test inside a hollow insulating body 108 educated. This is the flexible electrically conductive jacket 104 to an inner surface 110 an insulating hollow body 108 when the flexible electrically conductive jacket 104 is stretched. The insulation holkörper is of an at least partially electrically conductive frame 112 surround. The guiding framework 112 is for example a tube or a can.

Advantageously, the tensioning device 102 mechanically executed. The tensioning device 102 is for example as a coupling gear 114 with a screw drive 116 executed. The tensioning device 102 is for example via a spindle 118 drivable from the insulation body 108 is guided when the tensioning device 102 in the insulation body 108 is arranged. The tensioning device 102 preferably has at least one pressure body 120 on. The pressure hull 120 is electrically non-conductive or conductive and can, depending on the application, in a different way to the flexible electrically conductive jacket 104 be isolated. The pressure hull 120 is formed, the flexible electrically conductive jacket 104 against the inner surface 110 of the hollow insulating body 108 to squeeze when the jig 102 the pressure body 120 on the inner surface 110 moved. This will be the flexible electrically conductive jacket 104 when clamping at least partially against the inner surface 110 pressed.

In the example is the insulation body 108 a tube or can with rounded inside surfaces 110 , The pressure hull 120 is in this case a cylinder whose lateral surface has substantially the same curvature as the inner surface 110 at the edges. In particular, four such pressure bodies are in a rectangular frame with rounded edges 120 provided by the tensioning device 102 each moved to another of the rounded edges. The flexible electrically conductive jacket 104 when clamping between the pressure bodies 120 curious; excited. The clamped flexible electrically conductive jacket 104 is made so that its the inner surface 110 facing lateral surface in the edges by the pressure hull 120 to the inner surface 110 is pressed. The clamped flexible electrically conductive jacket 104 is made so that its the inner surface 110 facing lateral surface between the edges by the pressure hull 120 to the inner surface 110 is tense. Preferably, the entire of the inner surface touches 110 facing lateral surface of the tensioned flexible electrically conductive jacket 104 the inner surface 110 , Preferably, the inner surface touches 110 facing lateral surface of the tensioned flexible electrically conductive jacket 104 the entire inner surface 110 ,

A test device 122 is via a first electrically conductive connection 124 with the electrically conductive jacket 104 connected. The test facility 122 is via a second electrically conductive connection 126 with the electrically conductive frame 112 connected.

The test facility 122 For example, a continuity tester, ie, an electrical tester that indicates by an optical, acoustic, or electrical signal, is current from the test device 122 over the electrically conductive jacket 104 and the at least partially electrically conductive frame 112 back to the test facility 122 flows.

Instead or in addition to this is the test facility 122 designed, a dielectric strength and or insulation resistance of the insulating body 108 to determine.

2 schematically shows a first side view of the first insulation tester 100 , In 2 are the same reference numerals for the same components of the insulation tester 100 used.

A rotary movement of the spindle 118 moved in the example via the coupling gear 114 with the screw drive 116 the four pressure hulls 120 on the inner surface 110 to. The spindle 118 is in the example centered in the fixture 102 arranged. The spindle 118 is in the example on both sides of the jig 102 from the insulation body 108 guided. It can be provided to guide the spindle only on one side of the insulating body.

The isolation test device 100 has a test device 122 on, the electrically conductive with the flexible electrically conductive jacket 104 on the one hand and with an at least partially electrically conductive frame 112 on the other hand. The at least partially electrically conductive frame 112 touches an outer surface of the hollow insulating body 108 , The tensioning device 102 In the example, at least part of an electrical connection between the test device 122 and the flexible electrically conductive jacket 104 ,

3 schematically shows a second front view of a second insulation tester 200 ,

4 schematically shows a second side view of the second insulation tester.

In 3 and 4 are components of the second insulation tester 200 , the same or a similar function as the components of the first isolation device 100 have, denoted by the same reference numerals, in 1 and 2 were used.

The second insulation tester 200 differs from the first insulation tester that a tensioning device 202 includes an inflatable cushion.

The inflatable cushion is surrounded by an electrically conductive knit fabric. The electrically conductive jacket 104 includes the electrically conductive knit fabric. Alternatively, the inflatable cushion is made of the electrically conductive knit fabric.

The isolation test device 200 includes a connection cable 204 , The inflatable cushion is over the connecting cable 204 inflatable. A connecting part 206 is between inflatable cushion and connecting lead 204 arranged. The inflatable cushion, the connecting part 206 and the connection line 204 are preferably airtight. The inflatable cushion, the connecting part 206 and the connection line 204 trained to fill the pillow with compressed air.

An electrically conductive connection element 208 is preferably with the flexible electrically conductive jacket 104 connected. On a surface of the inflatable cushion, for example, a corresponding contact is arranged.

By inflating the inflatable cushion becomes the electrically conductive jacket 104 to the inner surface 110 emotional. Preferably, the electrically conductive jacket touches 104 the inner surface 110 when the pillow is inflated.

The second insulation tester 200 has the test device 122 on, the electrically conductive with the flexible electrically conductive jacket 104 on the one hand and with the at least partially electrically conductive frame 112 on the other hand. The at least partially electrically conductive frame 112 touches the outer surface of the insulating hollow body 108 ,

For both insulation test equipment is a method for an insulation test, characterized in that the tensioning device 102 the insulation test device 100 . 200 inside the insulating hollow body 108 is arranged, the flexible electrically conductive jacket 104 through the tensioning device 102 is moved from an initial position to an end position in which the flexible electrically conductive sheath 104 and the inner surface 110 touch, wherein in the end position, the continuity test and / or the test of dielectric strength is performed, and wherein the electrically conductive frame 112 the outer surface of the hollow insulating body 108 touched. In the initial position is the flexible electrically conductive jacket 104 less tensioned than in the final position. This allows easier handling in the arrangement inside the insulation hollow body 108 ,

For example, the spindle 118 driven to the pressure hull 120 from the initial situation to move radially outward in the end position with respect to a spindle axis.

For example, the inflatable cushion is moved from an uninflated state in the initial position to an inflated state in the end position.

After completion of the test, the flexible electrically conductive jacket 104 for example, to remove the tensioning device 102 moved back to the starting position.

For example, an electrical control is provided, which carries out the process automatically. The result is preferably used or stored to control a machine control. As a result, the inspection process can be tracked and documented.

Through this test, the measuring surface is the same insulation holkörper 108 the same in every measurement. The probability of detection of an insulation fault is thereby increased.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012214231 A1 [0005]
• DE 102012214738 A1 [0005]
• US 2001/0052778 A1 [0006]
• US 6225813 B1 [0007]
• US 4482860 A [0008]

Claims (11)

An insulation tester characterized by insulation testing means (100, 200) for conducting an insulation test inside a hollow insulating body (108) comprising a tensioning device (102, 202) surrounded by a flexible electrically conductive jacket (104) Clamping device (102) is formed such that the flexible electrically conductive sheath (104) by the clamping device (102) is clamped, wherein the flexible electrically conductive sheath (104) on an inner surface (110) of the insulating hollow body (108). Device after Claim 1 Characterized in that the electrically conductive jacket (104) comprises an electrically conductive knitted fabric. Device after Claim 1 or 2 , characterized in that the tensioning device (102) comprises a coupling mechanism (114) with a screw drive (116). Device according to one of Claims 1 to 3 , characterized in that the tensioning device (102) comprises a spindle (118) for driving the screw drive (116). Device after Claim 1 , characterized in that the tensioning device (202) comprises an inflatable cushion. Device after Claim 5 , characterized in that the inflatable cushion is at least partially surrounded by an electrically conductive knit fabric, wherein the electrically conductive sheath (104) comprises the electrically conductive knit fabric. Device after Claim 5 , characterized in that the inflatable cushion is at least partially surrounded by an electrically conductive knit fabric, wherein the inflatable cushion is made of the electrically conductive knit fabric. Device according to one of the preceding claims, characterized in that the insulation test device (200) comprises a connecting line, wherein the inflatable cushion is inflatable via the connecting line. Device according to one of the preceding claims, characterized in that the insulation test device (100, 200) has a test device (122) which is electrically conductive with the flexible electrically conductive jacket (104) on the one hand and with an at least partially electrically conductive frame (112) on the other is connectable, wherein the at least partially electrically conductive frame (112) contacts an outer surface of the insulating hollow body (108). Device after Claim 9 characterized in that the tensioning device (102) comprises at least a portion of an electrical connection between the test device (122) and the flexible electrically conductive jacket (104). Method for an insulation test, characterized in that a tensioning device (102) of an insulation test device (100, 200) according to one of the Claims 1 to 9 is at least partially disposed inside an insulating hollow body (108), wherein a flexible electrically conductive sheath (104) is moved by the tensioning device (102) from an initial position to an end position in which the flexible electrically conductive sheath (104) and an inner surface (110) of the insulating hollow body (108), and wherein in the end position, a continuity test and / or a test of the dielectric strength between the flexible electrically conductive sheath (104) and an electrically conductive frame (112) is performed, wherein the electrically conductive frame ( 112) contacts an outer surface of the insulating hollow body (108).

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