DE102014000342A1 - Method and device for selective leak testing of sewer pipes - Google Patents

Abstract

A method for selective leak testing of sewer pipes (1) comprises the following method steps: First, the leak tester (5) is positioned at the point to be tested in the sewer pipe (1) and the sealing elements (6) of the leak tester sealingly against the inside of the sewer pipe (1 ) and form between them a test chamber (7), the circumference or wall side is limited by the inner wall of the channel tube (1), and it is known compressed air injected into the test chamber (7), and with at least one in the test chamber (7 ) arranged gas pressure sensor (9) is checked after the injection of compressed air, whether for a longer period of time there blown in the compressed air in the test room is maintained. 1. The test chamber (7) is partially filled with a water filling (13), 2. the filling level of the water filling (13) is detected and evaluated in the test room (7), 3. the test chamber is filled with a compressible gas 4. the pressure in the air-filled area of the test chamber (7) is detected and evaluated, 5. the results and time courses of the detection of the filling level of the water filling (13) are set in relation to the pressure in the air-filled area of the test chamber (7). It can thus be decided whether there is a leak above or below the water filling in the sewer pipe.

Description

The invention relates to a method and a device for selective leak testing of sewer pipes according to the preamble of claim 1.

With those going back to the same applicant DE 198 38 316 A1 . DE 198 29 969 A1 . DE 10 2008 009 538 and DE 197 03 143 A1 In each case generic methods and devices for leak testing of sewer pipes have become known. The tightness of such sewer pipes is usually detected with a leak tester. The leak tester is also referred to as a socket packer. Such a sleeve packer consists of an approximately cylindrical housing, which is equipped in each case at the spaced-apart ends with inflatable sealing elements. During the pressure test, the inflatable sealing elements seal against the inner circumference of the sewer pipe to be tested when the leak tester is in the position of use.

In the middle region between the two arranged at a distance and inflated sealing elements a test space is defined, which is circumferentially bounded by the inside of the sewer pipe. Thus, the circumference of the sewer pipe in the area of the test room is checked for leaks.

According to the prior art, the leak tester is moved or pulled to the point to be tested in the sewer pipe. It is known to couple the leak tester either with a movable in the sewer pipe trolley, or move in with a rope or a push rod to the place of measurement in the sewer pipe.

In a second method step, the sealing elements are then inflated so that they create a sealing against the inside of the sewer pipe and define between them the test space, the circumference or wall side - as previously stated - is limited by the channel inner wall.

In the next process step, compressed air is blown into the test chamber, and with a pressure sensor arranged in the test chamber, it is checked after blowing in compressed air whether the compressed air injected there in the test room is maintained for a longer period.

If the pressure in the test chamber drops, this is an indication of the leaking of the sewer pipe in this area. In general, the socket joints of a sewer pipe are tested with such Dichtheitsprüfgeräten. However, the known Dichtheitsprüfgeräte are not limited to this; Any section of the sewer pipe can be checked for leaks.

The introduction of compressed air, with a concomitant drop in pressure in the test room, therefore speaks for a leakage of the sewer pipe in this area.

Disadvantage of the known test method, however, is that an exact location of the leak can not be made in this area. The leak can be anywhere on the sewer pipe in the test room over a circumferential angle of 360 degrees, without it being possible to determine the exact location of the sewer pipe leak.

In rare cases it is known - instead of filling the test chamber with compressed air - to put the test chamber under vacuum to determine whether air is sucked in from the defective leak of the sewer pipe. The resulting vacuum drop in the test room also indicates a leak in the sewer pipe in the area of the test room.

In other applications, it is known to fill the test room with water or other, non-compressible medium. However, such water filling is usually rejected because the filling with water and the emptying of the test room are relatively difficult and, above all, time consuming. The test duration is thereby extended. The water test is difficult to realize because of the arrangement of the water dispenser.

Such a water tightness test with filled in the pressure chamber under pressure water up to 500 mbar, in the standard with 100 and 200 mbar is carried out mainly in the (vertical) shaft area, or in sewer pipes with very large cross-sections of, for example, 1,000 mm, because at one Pressure build-up in the water eliminates a compression of the water filling and due to the incompressible medium (water), an additional statement about the leakage of the sewer pipe in this area can be made. It can therefore be made a statement about the specific size or type of leak in the water pressure test.

However, a disadvantage of the water pressure test is also that the exact location of the leak in the sewer pipe can not be determined over the circumference of the sewer pipe. The leak can therefore be present over an angle of 360 degrees in the test room, without an accurate location determination would be possible.

The invention is therefore based on the object, a method and an apparatus for selective leak testing of sewer pipes of educate the type mentioned above so that a selective determination of the location of the leak in the sewer pipe in the field of the test room can be made. Another advantage relates to the statement that the pipe connection is leaking, but in the sole area no leakage or only a small Wassererexfiltration exists.

To achieve the object, the method is characterized by features of the independent method claim.

A device performing the method basically consists in arranging at least one first pressure sensor in the upper apex area of the test space and at least one second pressure sensor in the sole area of the test space.

In an alternative embodiment of the invention, the device is characterized in that at least one pressure sensor is arranged in the apex region of the test chamber, and a fill level sensor is arranged in the sole region.

The leak tester used is preferably a so-called test packer, which can be designed in a closed design or with the possibility of the flow of the water / wastewater in the channel.

In a preferred embodiment of this embodiment, it is proposed that the level sensor is also realized by a laser measurement or an IR measurement or an ultrasound measurement, wherein the laser is preferably arranged in the apex area of the test room and detects and evaluates the height of the water level of the water filling in the sole area.

Instead of such a level sensor, which is preferably formed as a result of a laser or ultrasonic measurement, other known level sensors can be used, such as float sensors that allow a certain height measurement mechanically or optically due to their floating property, as well as capacitive, conductive or inductive level sensors , The optical laser measurement and / or the optical IR measurement or the ultrasound measurement can be combined with the results of the liquid level sensors contacting the medium.

The invention thus provides that a pressure sensor is arranged at least in the apex region of the test chamber, and that a fill level measurement of the fill level of the water filling in the sole region by one of the aforementioned sensors or a measuring method replacing the sensor takes place.

• 1. Der Prüfraum wird mit einer Teilwasserfüllung gefüllt, wobei die Wasserfüllung von einem bestimmten Bodensatz von zum Beispiel ein Drittel der Höhe des Füllraumes bis zur Hälfte aber auch bis zu der gesamten Höhe des Füllraumes gehen kann.
• 2. Es wird die Füllhöhe der Wasserfüllung im Prüfraum erfasst und ausgewertet.
• 3. Es wird der Prüfraum mit einem kompressiblen Gas befüllt, welches bevorzugt Luft ist. Statt Luft kann auch ein anderes komprimierbares, gasförmiges Medium verwendet werden, wie zum Beispiel Inertgas, Kohlendioxid, Stickstoff und dergleichen Gase.

The procedure for selective leak testing of the sewer pipe in the area of the test chamber now consists of the following steps:

• 1. The test room is filled with a partial water filling, the water filling can go from a certain sediment of, for example, a third of the height of the filling space to half but also up to the entire height of the filling space.
• 2. The filling level of the water filling in the test room is recorded and evaluated.
• 3. It is the test room filled with a compressible gas, which is preferably air. Instead of air, another compressible gaseous medium can be used, such as inert gas, carbon dioxide, nitrogen and the like gases.

• 4. Im nächsten Verfahrensschritt wird der Druck im luftgefüllten Bereich des Prüfraumes erfasst und ausgewertet.
• 5. Im folgenden Verfahrensschritt wird die Luft aus dem Luftraum wieder abgelassen, solange, bis Atmosphärendruck im luftgefüllten Raum des Prüfraumes herrscht, und es wird erneut der Wasserspiegel der Wasserfüllung im Prüfraum erfasst und ausgewertet.

For the sake of simpler description, however, a compressed gas filling is assumed in the following description, this compressed gas preferably being compressed air or compressed air.

• 4. In the next step, the pressure in the air-filled area of the test room is recorded and evaluated.
• 5. In the following process step, the air from the air space is discharged again until atmospheric pressure prevails in the air-filled space of the test room, and it is again recorded and evaluated the water level of the water filling in the test room.

The sequence of the aforementioned test steps now gives a statement as to whether there is a leak anywhere in the test chamber at the circumference of the sewer pipe or not. Either this leak is in the sole area of the test room, and thus in the sole area of the sewer pipe, then fails the hydraulic pressure test. Or the leak lies in the apex area of the test chamber, and thus also in the apex area of the sewer pipe, then fails the air pressure test. Thus, the partial water filling in the test room divides the test room into an upper air-filled room and a lower, water-filled room. The fluid limit resulting medium limit of the liquid medium now allows a statement as to whether the leak at the periphery of the sewer pipe is below the liquid level or above the liquid level. Accordingly, it is an improved selective leak detection of leaks on the circumference of a sewer pipe.

With the following further steps it is even possible to achieve even more accurate leak localization. The following steps are expediently carried out only if the preceding steps have detected a leak (above or below) of the liquid level.

Thus, after the leak detection (above or below the liquid level) and the leak test can be stopped because a statement about the location of the leak is given.

• a. Bei einem Leck unterhalb des Flüssigkeitsspiegels: An welcher Stelle liegt es unterhalb des Flüssigkeitsspiegels?
• b. Bei einem Leck oberhalb des Flüssigkeitsspiegels: An welcher Stelle liegt es oberhalb des Flüssigkeitsspiegels?

Only if, in special cases, a further limitation of the leak found is desired for the following situations:

• a. If there is a leak below the liquid level: at what point is it below the liquid level?
• b. If there is a leak above the liquid level: at which point is it above the liquid level?

• 6. Es wird entweder die Wasserfüllung vermindert oder vergrößert, um so das Verhältnis zwischen dem Luftraum und der Wasserfüllung zu verändern.

According to the invention, the following further test steps are now connected.

• 6. Either the water filling is reduced or increased, so as to change the relationship between the air space and the water filling.

• 7. Es wird danach Druckluft zugeführt und es erfolgt erneut eine Auswertung der Druckluftmessung und des Wasserspiegels.

In the simplest case, water is drained by briefly relaxing the sealing elements so that water can be drained from the test room. After discharge of a part of the water filling from the test room now the lowered water level is recorded and evaluated.

• 7. It is then supplied compressed air and it is again an evaluation of the compressed air measurement and the water level.

At the moment, when the water level after the compressed air test no longer changes, it is made clear that now the leak in the area of the drained water level in the peripheral region of the sewer pipe is, ie in the sole area. Thus, the leak on the circumference of the sewer pipe can be limited precisely to a certain circumferential angle range with a certain height from the sole.

In another embodiment of the invention, it may be provided that instead of the partial discharge of the water level now the water filling is increased and thus the water level in the pressure chamber increases and is maintained at a certain higher value.

After detection of the new, raised water level again takes place an air pressure measurement after the introduction of compressed air into the test room. If the compressed air test fails, but the hydraulic pressure test does not, it means that the water level remains the same with respect to the water level test and that the leak is in the apex area of the sewer pipe because the air pressure measurement fails.

In this way, by selective filling of the sewer pipe with a non-compressible, liquid medium, preferably water, to be specifically checked whether the leak is more in the sole region of the sewer pipe or in the apex area. There is thus an even more refined, selective determination of the leak of the sewer pipe in the test room relative to the circumference of the sewer pipe and its distance from the sole possible, which was not previously possible. From the now known leak detection, the percentage leakage, also be defined in conjunction with the pipe slope and backwater.

The subject of the present invention results not only from the subject matter of the individual claims, but also from the combination of the individual claims with each other.

All information and features disclosed in the documents, including the abstract, in particular the spatial design shown in the drawings, are claimed to be essential to the invention insofar as they are novel individually or in combination with respect to the prior art.

In the following the invention will be explained in more detail with reference to drawings showing only one embodiment. Here are from the drawings and their description further features essential to the invention and advantages of the invention.

Show it:

1 : Schematics a section through a sewer pipe with a leak tester in the driving position

2 : the same representation as 1 with the leak tester in the working position

3 : schematizes a section through the test room of a partial water filling

4 : one opposite 3 modified embodiment, from which it follows that instead of air and another compressible medium can be used in conjunction with the water filling

5 : a basic picture based on 3 which explains the principle of measurement

6 a section through the test room with representation in the event that the sewer pipe has no leakage

7 : the pressure time chart of the water column measurement in the sole area

8th : the pressure time diagram of the pressure measurement in the airspace after 6

9 : Schematically sectioned through the test room in a leaky sewer pipe, in which the leak is located in the apex area of the sewer pipe

10 : the result of the water pressure measurement in the case after 9

11 : the result of the pressure measurement in the case after 9

12 : schematizes a section through the test chamber in the event of a leak in the sole area of the sewer pipe

13 : the pressure curve of the water pressure measurement after 12

14 : the pressure curve of the air pressure measurement in the airspace

15 : Schematics a section through the test room with a located in the sole region of the sewer pipe leak

16 : the representation of the test steps, if that in the sole area after 15 located leak should be located

17 : the pressure curve of the water pressure measurement after 15 and 16

18 : the pressure curve of the air pressure measurement after 15 and 16

19 : schematizes a section through the test chamber at a located in the apex area of the sewer pipe leak

20 : the result of the water pressure measurement when performing the measuring steps 19

21 : the result of the air pressure measurements in the airspace when performing the measuring steps 19

In the 1 and 2 is a sewer pipe 1 represented, which consists of a plurality of sections, which via sleeves 2 . 3 connected to each other. It is a sewer leading sewer pipe. In the sewer pipe 1 For the purpose of tightness measurement, a carriage is used 4 retracted, via a supply cable 8th supplied with electrical signals, with energy and with compressed air and water.

With the carriage 4 is a leak tester 5 coupled, which consists essentially of a cylindrical body, at its two opposite ends inflatable or otherwise expandable sealing elements 6 are arranged.

From the state after 1 the entire testing device is compared to a sleeve to be tested for leaks 3 according to 2 hazards. It will then be the sealing elements 6 in the position 6 ' inflated and placed sealingly against the inner wall of the sewer pipe 1 in the area of the sleeve 3 at. This will between the two sealing elements 6 . 6 ' a test room 7 formed, which is optionally and / or sequentially filled with compressed air and water according to the method steps to be described later.

The 3 already shows some with a water filling 13 filled test room 7 , wherein only schematically shown that the leak tester in the upper part of the test room 7 at least one gas pressure sensor 9 is arranged, the pressure in the air space 14 filled compressed air detected, while in the lower area, namely in the area of water filling 13 , another sensor is arranged, which simplifies as a water sensor 10 referred to as.

In the general description has already been noted that the water sensor 10 preferably also designed as a pressure sensor. However, the invention is not limited thereto, since it is sufficient to measure the height of the water column of the water filling, which also includes a non-contact, optical, acoustic or sensor-controlled detection of the filling level of the water filling 13 can be done by, for example, the water level 15 in the test room 7 is detected by a laser and / or ultrasound and / or infrared measurement.

By partial filling of the test room 7 with the water filling 13 It is now possible for the first time to leak one or more leaks in the sewer pipe 1 could be present at the circumference in the test room, to locate more accurately. Namely, the invention distinguishes between the section of the sewer pipe 1 in the sole area 12 characterized in that the water filling 13 in the sole area, that of the overlying vertex area 11 through the overlying airspace 14 is delimited.

The invention is now able to determine for the first time whether a leak in the water-filled sole area 12 or in the airspace 14 of the sewer pipe 1 located.

The 4 shows as another example that it is not necessary to solve the problem, the airspace 14 to fill with compressed air. Likewise, it may be possible in another embodiment, another gaseous medium filling 16 to use, which preferably consists of a compressible gas.

For the sake of clarity it is also pointed out that the drawings could give the impression that the sensors mentioned above 9 . 10 each at the sewer pipe 1 are arranged. This is not the case and is shown here only for illustrative simplification reasons. In reality, the two sensors form 9 . 10 a part of the test room 7 off and are with the leak tester 5 connected.

It is of course possible, both in the apex area 11 as well as in the sole area 12 several adjacent and at the periphery of the sewer pipe 1 distributed sensors arranged 9 . 10 to use.

In any case, for the sake of simplicity, it is assumed that the upper sensor 9 is referred to as a gas pressure sensor, while the lower sensor 10 as water sensor (WS) 10 is designated, although this water sensor can also be replaced by a level measurement.

The 5 schematically shows the principle of selectively detecting a leak, which now either in the sole area 12 or in the apex area 13 (please refer 3 ).

By changing the water filling 13 . 13 ' about the difference 17 in the test room 7 can thus be decided whether the leak is now in the apex area 11 or in the sole area 12 or in an intermediate area.

For this purpose, the water filling 13 increased, so that the water level 15 on the elevated water level 15 ' increased.

Accordingly, the airspace decreases 14 on a reduced airspace 14 ' ,

For all drawings, the measured value of the water sensor is plotted on the ordinate with "WS" as the pressure of the water column or as the filling level of the partial water filling, while in the drawing below (with the same time on the abscissa) with "LS" the pressure of the air sensor in the air space above the partial water filling is specified.

The 6 to 8th show as a first embodiment the case when no leak is detected in the test room.

In a first process step, the test room is first filled with water 13 as long as filled up a certain water level 15 is reached, for example, up to a third or up to half of the cross section of the sewer pipe 1 can extend.

The water or another liquid test medium is in the direction of the arrow 19 via an inlet nozzle 18 in the test room 7 initiated, and the in 7 illustrated water pressure measurement with the water sensor 10 shows at the curve 22 an increase in the pressure of the water column until time t1 at which the water supply is completed.

Is now in the sole area 12 no leak, the curve remains 23 the same and unchanged.

After filling with water according to the curve 22 with the water flow 20 in 7 takes place from the time t1 according to 8th a supply of compressed air stream 21 over the inlet pipe 18 , thus the airspace 14 in the test room 7 subjected to overpressure.

According to the curve 24 thus increases the air pressure in the airspace 14 in the period t1 to t2, until he turns 25 remains stable.

The stable curve 23 in conjunction with the constant curve 25 now shows that now in the air 14 there is no leak. In the period t3, the compressed air is now out of the inlet port 18 dismiss and the pressure drops according to the curve 26 from.

At time t4 is then again according to 7 a water level measurement is performed or alternatively a water pressure measurement to ensure that also the water pressure of the curve 23 was maintained until time t4. This makes it clear that there is no leak either in the sole area of the sewer pipe or in the apex area in the test room.

The 9 to 11 show as another embodiment the case when a leak 27 in the apex area 11 of the sewer pipe 1 in the test room 7 is present.

In this case, the same test steps are carried out as they are based on the 6 to 8th were explained. However, the water pressure of the water sensor shows 10 according to 10 a constant curve 23 , which ensures that no leak in the sole area 12 is available.

When subsequently introducing the compressed air flow 21 from time t1 to time t2 according to 11 follows the pressure measurement of the curve 24 - as previously. However, the compressed air falls after completion of the filling process at time t2, so that the curve 25 ' arises, and about the leak 27 the compressed air as a leakage air flow 29 from the leak 27 according to 9 escapes.

This is due to the sloping curve 25 ' in 11 detected. At time t3, the compressed air is released and follows the curve 26 , wherein at time t4 again the water column after 10 is measured to make sure the curve 23 the water column has remained the same.

Thus, it can be stated that the leak 27 in the test room 7 in the apex area 11 of the sewer pipe is located.

The 12 to 14 show the opposite case, wherein the same test steps - as previously stated - are performed.

It will according to 12 assumed that the leak 27 in the sole area 12 located.

After filling the water filling 13 becomes the water level 15 by a certain difference 28 fall, because the water from the leak 27 as a leakage water flow 30 escapes. This is due to the falling pressure measurement according to the curve 23 ' in the water filling 13 according to 13 recognized.

After filling the sole area 12 with the water filling 13 the water filling increases according to the pressure curve 22 first. At time t1, the filling is stopped and it is due to the leak 27 the sloping curve 23 ' because of the leakage water flow 30 from the leak 27 flows out. As a result, the curve following in the period t2 also becomes 23 '' fall until finally at time t4 the falling curve 23 '' results.

Due to the falling water level also changes the pressure measurement in the airspace 14 , After the delivery of a compressed air stream 21 in the period from t1 to t2 there is an increase in the curve 24 , Due to the falling water level, however, the pressure in the air space decreases according to the curve 25 ' and the pressure becomes from the time t3 according to the curve 26 dismissed, so then atmospheric pressure in the airspace 14 arises.

The two sloping curves 23 and 25 ' according to the 13 and 14 leave on a leak 27 in the sole area 12 the test room 7 and thus the sewer pipe 1 shut down.

The 15 to 18 show a still further refined localization of the leak, where it can be more accurately determined in which area of the sole area the leak 27 located.

The refined test method according to the 15 and 18 is optional. It can be performed in addition to the previously described test method. It should therefore enjoy protection both in combination with one of the aforementioned test methods and in isolation.

It will be in 15 assumed that the leak 27 located just below the center line of the sewer pipe, and the sewer pipe 1 and thus also the test room 7 More than half of them are filled with a water filling, so that the water level 15 located approximately in the middle of the sewer pipe. The pressure measurement according to 17 now shows according to the example 15 , so an increase according to the curve 22 takes place until time t2, but then drops the water column and the course of the curve 23 ' follows.

These are therefore the same conditions as they are based on the 13 were specified.

Now water is drained in a further process step, so that a reduced water filling 13 ' is present. The water level thus drops by the difference 17 so he's on the value 15 ' drops. This is also the airspace 14 increased.

The subsequent water pressure measurement now follows the other curve, which with " 16 " in 17 is registered. Here again follows a smaller increase in water pressure according to the curve 22a , The decisive factor now is that the curve 23a behaves stably over the further time t1 to t4, that is, does not fall over the entire measurement period. This suggests that in the sole area 12 there is no leak anymore.

The pressure curve in the airspace behaves quite differently accordingly 18 , The two curves were marked with " 15 " and " 16 " designated.

In the presence of a leak in the sole region thus the barometric pressure measurement of the curve 25 ' Follow, because the water level decreases and thus the air pressure according to the curve 25 ' decreases.

Is the water level on the value 15 ' lowered, also the increase of the air pressure becomes according to curve 24a lower, and also the curve 25a has the characteristic drop, which now indicates the presence of a leak in the sole area 16 speaks.

Thus, by changing the water filling 13 on 13 ' about the difference 17 a leak in the range of the difference 17 on the circumference of the test room 7 , and thus the sewer pipe 1 to be localized. This is a more refined statement as to where the leak is 27 located in the sole area.

In the same way, by selectively filling the sewer pipe with the water filling 13 . 13 ' also a leak 27 in the apex area according to 19 to 21 be determined. The same reference numerals apply to the same parts, and the same test procedures again run as previously described.

It is important now that the water filling from the water level 15 based on the difference 17 to an elevated water level 15 ' he follows.

The water pressure measurement after 20 but still shows a constant water pressure in the water filling 13 . 13 ' , which suggests that throughout the sole area to the water level 15 ' there is no leak.

Conversely, the pressure measurement after 21 that both at low water filling 13 as well as with increased water filling 13 ' there must be a leak in the airspace, which leads to the realization that a leak 27 in the upper crest area 11 of the test room 7 is available.

Thus, it can be specified selectively via a controlled water filling and successive pressure measurements in the water area and in the air area, at which point of the peripheral area of the sewer pipe 1 the leak is present.

The training of Dichtheitsprüfgerätes as a packer with two spaced-apart sealing elements and a test space defined therebetween 7 is only an example. It is known, instead of two spaced-apart sealing elements 6 to use more than two sealing elements, in which case is spoken by double packers.

Likewise, it is possible with the present tightness test, to check the connection areas between a sewer pipe and an adjoining sub-channel pipe, in which case the test chamber is formed by the fact that in the secondary channel pipe also an inflatable packer is pushed, which then the test room 7 over part of the (main) sewer pipe 1 , namely the connection area of the sewer pipe 1 extends to the secondary channel as well as into the secondary channel pipe.

In this way, the transition areas between a sewer pipe 1 and a not shown, to the sewer pipe 1 Subsequent channel to be tested.

Likewise, the invention is not on the leak test in a sewer pipe designed as a main channel 1 limited. The same description applies to the leak test in side channel pipes, in which case the sewer pipe 1 is not a main channel pipe, but a small-sized secondary channel in which the leak tester can be moved to any position. All specified measurements and their evaluations can be automatically computer-aided.

LIST OF REFERENCE NUMBERS

1

sewer pipe

2

sleeve

3

sleeve

4

trolley

5

Leak Testing

6

sealing element

7

testing room

8th

power cable

9

Gas pressure sensor

10

water sensor

11

apex region

12

sole area

13

water filling 13 '

14

airspace

15

water level 15 '

16

medium filling

17

difference

18

inlet port

19

arrow

20

water flow

21

Compressed air flow

22

Curve

23

Curve 23 '

24

Curve

25

Curve 25 '

26

Curve

27

leak

28

Difference (from 15 )

29

Air leakage

30

Leak water flow

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 19838316 A1 [0002]
• DE 19829969 A1 [0002]
• DE 102008009538 [0002]
• DE 19703143 A1 [0002]

Claims (10)

Method for selective leak testing of sewer pipes ( 1 ) comprising the following method steps: 1. the leak tester ( 5 ) is at the point to be tested in the sewer pipe ( 1 2) the sealing elements ( 6 ) of the leak tester sealingly against the inside of the sewer pipe ( 1 ) and form a test room between them ( 7 ), the circumference or wall side by the inner wall of the channel tube ( 1 3. It is compressed air in the test room ( 7 ), and with at least one in the test room ( 7 ) arranged gas pressure sensor ( 9 ) is checked after the injection of compressed air, whether for a longer period of time the compressed air injected there in the test room is maintained, characterized by the further steps 3. the test room ( 7 ) is filled with a water filling ( 13 ) partially filled, 5. the filling level of the water filling ( 13 ) is in the test room ( 7 ) recorded and evaluated. 6. the test chamber is filled with a compressible gas, 7. the pressure in the air-filled area of the test room ( 7 ) is recorded and evaluated, 8. the results and time courses of the detection of the filling level of the water filling ( 13 ) with the pressure in the air-filled area of the test room ( 7 ) are related to each other. A method according to claim 1, characterized in that by a chronologically successive, different filling of the test room ( 7 ) with the non-compressible, liquid medium, preferably water, in chronological successive test steps for a particular degree of filling of the test chamber ( 7 ) is checked, whether the leak ( 27 ) in the sole area ( 12 ) of the sewer pipe ( 1 ) or in the apex area ( 11 ) is located. A method according to claim 1 or 2, characterized by the further steps, wherein following the test step 8th the following further test steps are connected: 9. either the water filling is reduced or increased, so as to increase the ratio between the air space and the water filling in the test room ( 7 ). Compressed air is then supplied and an evaluation of the compressed air measurement and the height of the water level is again carried out. 11. The results and time profiles of the detection of the new filling level of the water filling ( 13 ' ) with the pressure in the air-filled area of the test room ( 7 ) and evaluated. Device for selective leak testing of sewer pipes ( 1 ) with a leak tester ( 5 ), in which the sealing elements ( 6 ) sealing to the inside of the sewer pipe ( 1 ) and create a test room between 7 ), the circumference or wall side by the inner wall of the channel tube ( 1 ) is limited, with an inlet port ( 18 ) Compressed air into the test room ( 7 ) and the gas pressure of the compressed air with at least one in the test room ( 7 ) arranged gas pressure sensor ( 9 ) is detectable, characterized in that the gas pressure sensor ( 9 ) in the upper vertex area ( 11 ) of the test room ( 7 ) and that in addition the level of a liquid medium in the sole area ( 12 ) of the test room ( 7 ) is detectable. Apparatus according to claim 4, characterized in that for detecting the level of the liquid medium in the sole region ( 12 ) of the test room ( 7 ) a level sensor in the test room ( 7 ) is arranged. Apparatus according to claim 4 or 5, characterized in that the level of the liquid medium in the sole region ( 12 ) of the test room ( 7 ) takes place by a non-contact detection of the liquid level. Apparatus according to claim 6, characterized in that the non-contact detection of the liquid level by an optical measuring method or by an ultrasonic measurement is carried out. Device according to one of claims 1 to 7, characterized in that the test room ( 7 ) in the region of the sewer pipe ( 1 ) is located. Device according to one of claims 1 to 8, characterized in that the test room ( 7 ) in the region of the sewer pipe ( 1 ) and extends into the connection of a secondary channel into the main channel. Device according to one of claims 1 to 9, characterized in that the test room ( 7 ) is arranged in a secondary channel, which is connected to the sewer pipe ( 1 ).

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