NL1028248C2 - Detection of presence of methane gas in underfloor areas normally difficult to access - Google Patents

Abstract

The presence of methane gas in underfloor areas difficult to access involves an aperture (1) being drilled from above through the outer (2) and inner (3) walls into the space (4) beneath. The aperture runs from the outermost side of the outer wall, near to the uppermost side of the ground surface (9) in the direction of the restricted space (4) through the outer wall (2). The commencement point (8) of the aperture is near to the upper edge of teh ground surface on the outermost side (2a) of the wall and its end point (10) is on the innermost side (3a) of the wall near the under side (6) of the floor. The aperture can be terminated in a tube (11), through which a gas detection part (12) can be simply inserted and prevents the aspiration of air. The gas detection part can be a sample collection tube, a sensor or other measurement instrument and from the outside can be fixed to a gas analysis apparatus (13) parallel to the innermost sides (14) of the tube. The sample can also be stored in the corresponding tube for analysis at a later time.

Description

Title: Method for detecting gases in spaces.

The invention relates to a method for detecting gases in crawl spaces, pipe ducts or other hard-to-reach spaces.

It is known from practice that gases, in particular methane, can accumulate in rooms or elsewhere in homes because a gas pipe is leaking. The accumulated methane can cause an explosion or fire. To demonstrate whether a gas pipe in the room is leaking, the gas inner pipe (after the gas meter) is usually extorted and a check is made to ensure that the pressure remains intact. This method is not used for the connection line, being that part of the line that is upstream of the meter. This is not done because the pipe would have to be dug up, disconnected and sealed outside, after which a press test could possibly be carried out. The indoor part of the connection line must therefore be inspected in a different way. In addition to the extortion method, the so-called "sniffing method" is used to detect leaks. To demonstrate whether a pipe in the room is leaking, a detection can be made using gas analysis equipment. In general, the room is then entered via a crawl hatch, whether or not after the removal of carpet, parquet or other floor covering. The situation is visually inspected in the room and then, with the aid of a gas analysis device, it is measured at various places near the gas line whether there is methane in the air. Current detection methods include taking air samples or detecting a gas line leak.

The disadvantage of the above method is that when a resident is not at home or a house has no crawl hatch or other access to the hard-to-reach space, it is particularly difficult to be able to measure the possible presence of methane in the space. It is also not always possible for the person carrying out the inspection to enter the room from the point of view of occupational health and safety legislation, since only spaces that meet specific characteristics may be entered.

Another method is the permanent placement of sensors in spaces, whereby the sensors, when they detect gas, can transmit this online to, for example, an energy company. However, this is a labor-intensive and costly method.

Recent research has shown that when methane enters a room via leakage, this amount of methane has spread homogeneously in the air after a short time, generally within a few minutes, and therefore the measured concentration of methane will be the same everywhere. A methane concentration measurement at any point in an enclosed space therefore gives a result that can be considered representative of the average methane concentration in the space. Thus, a very accurate, i.e., selective, measurement can be made anywhere in the room. This is regardless of whether or not there is ventilation in the room. It should be noted that this finding is not consistent with the prejudice of the average person skilled in the art. The average person skilled in the art believes that methane and similar gases will rise and can therefore only be detected at the top of the room. The general opinion is also that the concentration against the ceiling need not be homogeneous.

The object of the present invention is to provide an efficient detection method for determining the technical condition of gas pipes in indoor spaces by measuring the methane concentration in these spaces where these are not actually entered and based on a measurement at one location. The actions during the detection must be such that the results of the inspection represent the situation as well as possible within acceptable costs.

To this end, the invention provides a method according to the type mentioned in the preamble, wherein a gas sensing section is inserted through an opening in a wall delimiting the space.

The advantage of this is that the room does not actually have to be entered, which is beneficial for the safety of the person carrying out the inspection, and that no one needs to be home to allow detection to take place. Furthermore, this entails that there is only limited destructive testing on the outside of the home by drilling one or more holes and possibly excavating locally. If the space is completely enclosed by living space, such as, for example, a pipe duct in an apartment building, there should only be or be made an opening in the wall of the space. This is particularly advantageous since this type of space is not accessible in any other way. In addition, the air situation in the room is disrupted as little as possible, in contrast to when, for example, a crawl hatch would be opened. A risk in the event of a disturbance of the air situation is that the measured values do not correspond with reality. In contrast to the prevailing bias, it is not important whether the detector is placed at the top or bottom of the space to be detected. This determination makes it possible to apply the method according to the invention and to be sure that the results of the method are reliable.

According to a further elaboration of the invention, an endoscope is inserted through the opening or a second opening to perform a visual inspection of the space before the gas sensing portion passes through the opening. This means that it can be checked whether the situation in the room matches the expectations of this room. The expectations may include what the space 30 looks like on the basis of drawings, the year of construction of a home and / or the appearance of the home. The use of an endoscope can provide meaningful data, for example with regard to the route of the gas line or the condition of the space to be inspected, and it can also be checked whether the position of the gas detection part is correct during sampling.

According to a further elaboration of the invention, with the gas detection part that can be connected to a gas analysis device, at least one sample is extracted from the air present in the closed space. This has the advantage that a representative sample of the air is taken from the space within a short time.

According to a further elaboration of the invention, in rooms with a plurality of compartments, at least one sample is extracted from each of the compartments. The advantage of this is that if nothing is measured in one compartment due to compartmentalisation, it can be the case that in another compartment there is an increased concentration of gas that is measured. If gas has leaked then this will always be found in this way.

According to a further elaboration of the invention, the sample is analyzed for the presence of gas. The advantage of this is that it is known within a short time whether there is gas in the space and whether there is therefore a leak.

According to a further elaboration of the invention, the opening on the outside of the wall starts above ground level, the opening opening into the space on the inside of the wall. This implies that detection in this way can take place at many houses, mainly single-family houses with crawl spaces, since in many houses the floor is at a level that is above ground level.

According to a further elaboration of the invention, the gas detection is carried out at a wind force of less than 3 Beaufort. This entails that the wind speed with a ventilation grille will be less than 1028248 than 8 m / s, as a result of which the chance that any leaked gas is ventilated away from the room and nothing is measured despite the presence of a leak being as small as possible.

According to a further elaboration of the invention, the opening 5 is provided with a finish, such as, for example, a hollow tube. As a result, the chance that the gas sensing section only sucks in air from the wall cavity is no longer present.

According to a further elaboration of the invention, the opening is provided with a removable closing device. With the aid of the closing device it is prevented that no unwanted objects can enter the house. Because the closing device is removable, any subsequent detection is facilitated at a later time.

A further elaboration of the invention is that the gas analysis device is a portable measuring device which, by means of a signal or a display on the screen, indicates that the methane has been detected.

According to a further elaboration of the invention, if gas has been detected, the space must be entered or made accessible for further inspection and / or repair. The number of spaces to be accessed is minimal since only a deviation in the space 20 actually requires access to it or makes it accessible.

According to a further elaboration of the invention, the gas detection part comprises a sampling tube, in which gas from the space is stored in the sampling tube during the recording, the sampling tube being placed in an analyzer for analyzing the sampled gas after sampling. In this way it is possible to take samples in a simple way and later analyze them in one go, for example in a laboratory. Another advantage is that the person taking the samples does not have to be able to operate and read gas analyzers.

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A favorable effect of the present invention is that the time required to carry out a detection is very short, so that a much greater number of detections can be carried out by one person on a day than to date, so that the cost per house is low is. Users of this method for gas detection in spaces are, for example, the residential construction companies, energy network managers or others who want to monitor and improve the quality of the pipes in houses by means of periodic checks and maintenance.

The invention will be further elucidated with reference to the following figures:

Figure 1 shows schematically the method for measuring methane in an arbitrary space.

Figure 2 schematically shows the method for measuring methane in a pipe duct.

Figure 1 shows schematically the situation of the method for methane detection in a space, in the present exemplary embodiment a crawl space. It can clearly be seen that an opening 1 from outside has been drilled through the outer wall 2 and then through the inner wall 3 towards the space 4. That is, the opening 1 from the outer side of the outer wall 2, near the upper side of ground level 9 runs through the outer wall 2, the wall cavity 5 and the inner wall 3 in the direction of the space 4 and ends near the bottom of the floor 6 but above the foundation 7 of the wall. The opening 1 can of course also be made by chopping, sawing, cutting or already made during the construction of a house. The starting point 8 of the opening 1 is located near the top of the surface 9 on the outer side 2a of the wall, the end point 10 of the opening 1 is located on the inner side 3a of the wall 3 near the bottom side 6 of the wall. floor. The opening 1 is provided with a finish, which may be a tube 11, but also a different type of means, which finishes the drilled outlines of the opening 1, through which a gas detection section 12 can be easily slid through. The tube 11 also prevents undesired suction of air from the wall cavity 5. The gas detection section 12 can be a sampling tube, a sensor but also another measuring instrument. From the outside, the sampling tube which can be attached to a gas analyzer 13 is introduced parallel to the inner sides 14 of the tube 11 through the tube 11 into the opening 1 in the space 4. If a quantity of methane is present in the space 4, a concentration of methane will be measurable at any point in the space as methane spreads homogeneously in the air present. Logically, this method is also applicable to other homogeneous dispersing gases. After detection has taken place, the sampling tube 12 will be taken through the tube 11 in the direction of the gas analysis device 13. It may also be that sample is stored in the sampling tube 12 for analysis at a later time. The opening 1 will be closed with a cap 15, wherein the cap can also be easily removed again, as a result of which subsequent detections can easily take place. The possible gaps between the tube 11 and the opening 1 are sealed off so that water or a possible gas leak outside cannot find its way into the space. In addition to the closing device being a cap 15 that falls over the opening 1, it can also be a device that falls wholly or partially into the opening 1.

Figure 2 schematically shows the method for measuring methane in a pipe duct 16 in an apartment building 17. In the apartment building 17 there are various apartments 18. The apartments 18 each have their own gas meter 19. To conduct gas to the various apartments 18, a pipe 20 runs from outside the apartment through the pipe duct 16. The pipe 20 has branches 21 which connect the gas meters 19 to the pipe 20. The pipe sleeve 16 is a space that is not accessible. To detect any gas in the pipe duct 16, an opening 22 is made in a wall of the pipe duct or an opening 22 is already present. This opening 22 can be at any point on the wall 23. A gas sensing portion 24 is inserted through said opening 22, which takes a sample of the air present. The sample can be analyzed directly or at a later stage by a gas analyzer, for example in a laboratory.

It will be clear that not only these exemplary embodiments 10 fall within the scope of the invention, but that, for example, other types of detection are also possible.

1028248

Claims (20)

Method for detecting gas in crawl spaces (4), conduit tubes (16) or similar other hard-to-reach spaces, characterized in that a gas sensing section through an opening (1, 22) in a wall (2, 3) bounding the space (12, 24) is inserted. The method of claim 1, wherein the gas sensing portion (12, 24) is a sampling tube. The method of claim 1, wherein the gas sensing portion (12, 24) is a sensor. 4. Method as claimed in any of the foregoing claims, wherein an endoscope is inserted through the opening or a second opening to perform a visual inspection of the space (4) before the gas detection part (12, 24) through the opening (1, 22) to stick out. 5. Method as claimed in any of the foregoing claims, wherein at least one sample is extracted from the air present in the enclosed space with the gas detection part (12) that can be connected to a gas analysis device (13). A method according to any one of the preceding claims, wherein in rooms with a plurality of compartments at least one sample is extracted from each of the compartments. The method of any one of claims 5-6, wherein the sample is analyzed for the presence of gas. A method according to any one of the preceding claims, wherein the gas to be detected is a homogeneously dispersing gas. 9. A method according to any one of the preceding claims, wherein the gas to be detected is methane. A method according to any one of the preceding claims, wherein the opening on the outside (2a) of the wall (2) starts above ground level (9) and wherein the opening (1) on the inside (3a) of the wall (3) into the space (4). 11. Method according to claim 10, wherein the opening (1) on the inside (3a) of the wall (3) ends at a highest point of the room (4) on the inside of the room. A method according to any one of the preceding claims, wherein gas detection is carried out at a wind force of less than 3 Beaufort. A method according to any one of the preceding claims, wherein the opening (1) is a hole obtained by a drilling operation. A method according to any one of the preceding claims, wherein the opening (1, 22) is provided with a finish (9). The method of claim 14, wherein the finish is a hollow tube. 16. Method as claimed in any of the foregoing claims, wherein the opening is provided with a removable closing device (14). The method of claim 17, wherein the closure device (14) is a removable cap. The method of any one of the preceding claims, wherein the gas analyzer (13) is a portable measuring device. A method according to any one of the preceding claims, wherein if gas is detected, the space must be entered or made accessible for further inspection and / or repair. The method of claim 1, wherein the gas sensing portion (12, 24) comprises a sampling tube, wherein during recording gas from the space is stored in the sampling tube, wherein after sampling the sampling tube is placed in an analyzer for analyzing the sampled gas. 30 1028248