CZ2016797A3 - A testing device for diagnosing the leakages of entries in building structures and a method of its utilization - Google Patents

Abstract

Testing device for local leakage diagnostics in building penetration connections, where the closable hollow space body consists of a fixed body part (1), a free openable body part (2), a sleeve (3) attached to a fixed body part (1) and a sleeve ( 9) connected to the freely opening body part (2) forming an air-sealed part of the device in the working position. Furthermore, an air pressure measuring device (8) is connected to the outer shell of the fixed body part (1) for reading the air pressure values in the air-tight part of the test device during the air-tightness measurement and a valve for connecting the connecting element (14) to the device (13) of the device. creating vacuum or overpressure. The method of use of the test device is that before the test device is mounted on the diagnostic part of the building structure with the passage open the openable parts (2, 9 and 10) of the test device first, then connect the test device with one side to the diagnosed building structure and the other side by means of a sleeve (9 and 3) with a skirt (10 and 4) on the construction, and then the device is airtight. After an airtight seal, ie an airtight connection of the openable parts (2, 9 and 10) of the test equipment and the rigid parts (1, 3 and 4) of the test equipment, this equipment is ready to carry out the diagnosis by means of the connected device (13) to create vacuum or overpressure. and measuring equipment (13). After obtaining the measurement values, the device is uninstalled in the opposite way from the diagnosed building structure with the transmission.

Description

Technical field

The present invention relates to the field of measuring, testing and navigating devices, in particular testing devices, for the field of building permeation diagnostics, capable of diagnosing local leaks in connection of external and internal permeations through building structures.

BACKGROUND OF THE INVENTION

Leaks in building structures, in particular leaks in external and internal passages and cable and pipe penetrations, are the cause of many faults diagnosed in buildings. These leaks increase the heat loss of buildings and significantly reduce the efficiency of modern building ventilation systems. In practice, it is possible to ensure the elimination of leaks, ie airtightness of the building by a suitable professional design of airtight layers. To ensure airtightness! However, the quality of building constructions on the construction site is of key importance. Verifying whether the structure or construction detail is airtight immediately after its creation is problematic to impossible using current instrumentation.

For the diagnosis of leaks in building structures, so far mainly devices enabling the so-called Blower-Door test have been used. The Blower-Door test is a type of test in which whole (complete) constructions can be diagnosed with a special testing device. However, the Blower-Door test can only be used after all airtight coatings have been completed, often just before completing the entire building. Therefore, it is not possible to diagnose local leaks in structures at any stage of construction using the Blower-Door test. Making adjustments to already completed building structures and details to achieve the required airtightness can be technically very demanding in practice. A disadvantage of using the Blower-door test and the device to perform this test is also the fact that a specialized company must have the equipment and authorization required for the test to perform the building structure diagnosis.

Another possibility for the diagnosis of leaks in building structures is the use of thermographic imaging. However, the use of thermographic imaging has very limited applications and is dependent on the climatic conditions of the measurements. In practice, thermographic imaging for leak detection can only be used at the same time

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9 99 9 9 9 9 9 9 9 9 9 9 9 9 9 9 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 ···· Blower-door test device.

The optimal solution to this problem would therefore be to verify the airtightness of the component parts immediately after their installation.

Currently, various types of so-called vacuum bells can be used to verify the tightness of building structures immediately after their construction.

An example of this vacuum bell is the apparatus described in US patent application 2108176 A entitled "Apparatus for testing plate seams" or US patent application US4002055 A, characterized in that it is not possible to diagnose non-planar structures such as penetrations through building structures. The leak detection device of US Patent 2660053 A " Flexible seam testing device " is then characterized in that it can be mounted on non-planar structures, such as rounded structures.

However, these measuring devices cannot be mounted airtight on both the passage and the building structure through which the passage passes.

Another known solution is the device described in patent TW527487 (B) entitled " A device using airtight membrane, vacuum and tracer for leak detection " using a differential pressure of air between the test device and the diagnosed building structure to detect leaks. The device is made of a resilient material, which can, to some extent, be airtight connected to structures with uneven surfaces. However, the device cannot be airtightly coupled to shape-complicated structures such as penetrations. For this reason, the device cannot be used to diagnose the airtightness of the connection of penetrations through structures.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a test device capable of diagnosing local leaks in the interconnections of passages that pass through building structures, i.e. to perform a diagnostic showing whether the interconnections of passages in building structures are airtight, both external and internal passages of different cross-section structures. how to use it.

Test equipment for diagnosing local leaks in the connection of penetrations to building structures, based on the detection of leaks by the air pressure difference caused by the test equipment between the airtight part of the test equipment, and

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· · ♦ · ♦ ^{1 1 1 1 1 1 1} - ^{1 1} - - ^{1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1} A diagnosis part of a building structure according to the present invention, consisting of an air-sealed part of a device consisting of a closable spatial body, an air pressure reading device, a device for generating a vacuum or a positive pressure. air and a connecting element of the device for generating a negative or positive air pressure, the principle being that the closable hollow space body consists of a fixed body part, a free openable body part, a sleeve attached to a fixed body part and a sleeve attached to a freely openable body part forming an air-sealed part of the device in the working position, the air pressure measuring device being further connected to the outer shell of the fixed body part u for reading the air pressure values in the airtight portion of the test device during airtightness measurement and a valve for connecting the attachment to the device for generating air pressure or pressure, the airtight portion of the device being airtightly connectable by the contact surface of the rigid body of the device the openable body portions formed on one side of the airtight portion of the device to the building structure and, at the same time, the individual body portions are collared on the opposite side of the airtight portion of the device by means of a collar the body part and the rigid arm of the fixed body part of the test rig shall be provided at the contact edge of the contact surface with the construction structure with a flexible seal, and the collar the sleeve is formed of an airtight fabric when, for the airtight connection of the loose and solid body portion of the device, at least one of said portions is provided with an airtight longitudinal seal, preferably an airtight fabric overhang around the penetration and the fixed arm of the free portion is connected to the contact surface of the fixed portion by means of a fastener, the airtight portion of the test device having the shape of a rotating body or a regular or irregular multi-lateral body when at least a portion of the airtight portion fabrics, allowing the testing device to be fitted to penetrations of different dimensions and shapes, the body of the testing device comprising a fixed part and a free part - openable when the t The body of the test device and its free part allows the test device to be put on the diagnosed penetration of the building structure. An air pressure measuring device for reading the air pressure readings in the sealed part of the testing device during the airtight measurement and a valve for connecting a connecting member, preferably a flexible hose, for supplying and extracting air from the testing device to the creating a vacuum or

And the overpressure of air needed to perform diagnostics. The loose body portion of the tester adjacent to the building structure is provided with a rigid arm articulated to the fixed body portion of the tester, and the fixed body portion of the tester is provided with a contact surface to allow opening of the free body portion of the tester.

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The method of use of the test device according to the present invention is characterized in that in order to deploy the test device, it is necessary first to open the loose body part of the test device, the loose part of the sleeve and the loose part of the sleeve of the sleeve. After opening said parts, the test device is threaded onto the passage and the loose portion of the collar and the loose portion of the test device sleeve are closed. After mounting, the openable parts of the test device are airtightly connected by means of a rubber seal and Velcro fasteners to a fixed body part of the test device. The opening portions of the neck and collar interconnect with the fixed portions of the neck and collar. The collar is closed and airtightly connected with the Velcro. Velcro fasteners allow airtight connection of loose sleeve parts and sleeve collars to different profiles of building constructions. The rigid arm of the loose body portion of the tester is then airtightly coupled to the contact surface of the solid body with a Velcro fastener and at the same time the loose body portion of the tester is coupled to the rigid body of the tester with an airtight seal, preferably by their connection, the body of the test device becomes an airtight element. The rigid arm of the loose body part and the rigid arm of the rigid body part of the tester are provided with a flexible seal at the contact edge of the contact surface with the building structure.

A vacuum or overpressure device, preferably a vacuum pump to create a vacuum and a compressor to create a positive pressure, is connected to the test device after mounting on the transmission. The device for generating a negative or positive air pressure is then actuated and, if necessary, decreases or increases the air pressure in the test device. The sealed part air pressure measuring device is used to check the sealed part air pressure. To verify that the connection of the passage to the building structure is airtight, it is necessary to achieve a pressure difference of - 0.2 bar under the effect of negative pressure and + 0.2 bar under the effect of positive air pressure. The pressure difference shall be monitored on the measuring device for 30 seconds, monitoring whether the air pressure in the test device is changed by more than 20%.

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The device according to the invention then measures the air pressure in the test device and performs the diagnostics, and is further connected by means of a valve to a device generating, if necessary, an underpressure or overpressure of air.

The advantage of the test device according to the invention is that it is possible to perform a complete leak diagnostics in connection of penetrations of building structures in one measurement. The test device is able to diagnose different diameters and shapes of passages thanks to a flexible collar located in the part of the test device mounted on the diagnosed passage. The design of the test device allows the device to be mounted on the diagnosed permeation without having to thread the complete device over the end of the permeation, which is often impossible in practice using available diagnostic instruments. The possibility of threading the test device onto the diagnosed transmission is made possible by the construction of the device comprising loose body parts and the sleeve of the test device. The maximum size of the diagnosed transmission is limited only by the size of the free part of the test device

BRIEF DESCRIPTION OF THE DRAWINGS

The test device for diagnosing leaks through building structures and how to use it will be further explained with reference to the drawings in which: FIG. 1 illustrates a test device according to the present invention with an open free body portion allowing the test device to be threaded onto a diagnosed transmission, and FIG. 2 showing the same test device with an airtight free body portion of the test device, i.e. in a position in which measurement.

DETAILED DESCRIPTION OF THE INVENTION

Example 1.

An example is a test device for diagnosing leaks in the gas pipeline connection to the perimeter wall of an object. The gas pipeline is routed in a steel tube of circular cross-section and passes through the perimeter wall at the point of penetration.

The test apparatus of FIG. 1 and FIG. 2. it is fitted on the passage (gas pipe) in the interior of the building. The test device is airtightly connected to the passage by a sleeve 3 with a flexible collar 4 of a flexible airtight fabric, attached to the first end of the rigid part 1 and the free openable part 2 of the body of the test device. The airtight fabric is made of a coated PES fabric. The flexible collar 4 is secured to the passageway by means of a "collar".

Using a Velcro fastener that is attached around this passage. The airtight connection of the test device to the peripheral wall is provided by a flexible seal 7 of the arm 6 and the contact surface 5 fixedly connected to the other end of the fixed body part 1 and the free openable body part 2 of the test device. The test device is connected by means of a pressure hose 14 to the device 13, to induce a vacuum or overpressure of the air when performing the diagnostics.

In the leak test of the penetration connection to the building structure, the test device is manually pushed against the building structure through which the penetration passes. The flexible seal 7 seals in an airtight manner, instead of connecting the test equipment to the building structure. After the test device has been sealed, the device 13 may be actuated to create a negative or positive air pressure. The test device also includes an air pressure reading device 8 in the test device.

Example 2:

An example is the test apparatus of FIG. 1 and FIG. 2, which is airtightly mounted on the diagnosed structure and also on the passage that passes through the structure. An air vacuum device 13 connected to the test apparatus by means of a pressure hose 14 is actuated. The air pressure readings of the test apparatus are read on a measuring device 8 for reading the air pressure in the sealed part which is mounted on the body of the fixed part 7 of the test device. The output of the vacuum / overpressure generating device is set to 0.2 bar. Upon reaching -0.2 bar on the air pressure reading device 8, the air pressure generating device 13 is turned off. The air pressure reading device 8 is monitored for 30 seconds unless the air pressure in the test device rises above - 0.2 bar. If there is no change in the air pressure inside the test device by more than 20% during the monitored period, the connection of the penetration to the building structure can be considered airtight.

Example 3:

An example is a test device for diagnosing leaks in the air duct connection. The air distribution is guided by rectangular or rectangular cross-section pieces and passes through the peripheral wall at the point where it passes through.

The test apparatus of FIG. 1 and FIG. 2, after opening the free parts of the test device, it is fitted to the air distribution in the interior of the building. The test equipment is airtight connected to the distribution (square or rectangular fittings) by closing

By means of the joints 11, 12, the opening portions 2 of the test body are provided in an airtight manner to the fixed parts 1 of the body of the test device. The airtight connection of the test device to the peripheral wall is provided by a flexible seal 7, which is attached to the contact surface 5, 6 of the test device. The test device is connected by a pressure hose 14 to a device 13 which generates a negative or positive air pressure. In the leak test, the test device is manually pressed against the peripheral wall by pressure. The flexible seal 7 seals in an airtight manner, instead of connecting the test device to the peripheral wall. After the test device has been sealed, the device 13 may be actuated to create a negative or positive air pressure. The test device is fitted with a measuring device 8 for reading the air pressure in the test device.

Industrial applicability

The test equipment according to the invention can be used outside the building industry in all industrial areas where it is necessary to verify that the connections of the penetrations through the structures are made airtight, gastight or waterproof.

Claims (5)

Patent claims 1. Test apparatus for diagnosing local leaks in connection of penetrations to building structures, consisting of an air-sealed part of a device consisting of a closable hollow space body, an air pressure reading device, a device for generating a vacuum or air pressure and a connection element for a vacuum or air pressure device characterized in that the closable hollow space body comprises a fixed body part (1), a free openable body part (2), a sleeve (3) attached to the fixed body part (1) and a sleeve (9) attached to the freely openable part (1). 2) bodies forming an airtight part of the device in the working position, the air pressure measuring device (8) being connected to the outer shell of the fixed body part (1) for reading the air pressure values in the airtight part of the test device during the measurement and a valve for connecting the attachment element (14) to the device (13) of the device for generating a vacuum or overpressure of the air, the airtight portion of the device being airtightly connectable by the contact surface (5) of the fixed body part (1) together with the fixed arm (6) free openable body parts (2) of the device formed on one side of the air-tight device part to the building structure and at the same time the parts (1 and 2) are provided by a sleeve (3 and 9) provided with a collar (4 and 10) formed on the opposite side air-tight parts of the device connected to the passage through the building structure. Test device for diagnosing local leaks in the connection of penetrations to building structures according to claim 1, characterized in that the sealable hollow spatial body is in the form of a rotating body or regular or irregular multi-lateral body and a fixed arm (6) of the openable body part (2) and the contact surface (5) of the rigid body portion (1) of the tester is provided with a flexible seal (7) at its contact edges with the building structure and provided with a connecting element (12) on its contact surface. Testing device for diagnosing local leaks in connection of penetrations to building structures according to claims 1 and 2, characterized in that the collar (4 and 10)% The sleeve (3 and 9) is formed of an airtight fabric when, for the airtight connection of the fixed body part (1) and the free body part (2) of the device, at least one of these parts (1 and 2) is provided with an airtight longitudinal joint ) equipped with a Velcro connection. Test device for diagnosing local leaks in the connection of penetrations to building structures according to claims 1 to 3, characterized in that at least a part of the air-tight part of the device is made of an airtight fabric enabling to install the test device on diagnosed penetrations of different sizes and shapes. Method of using the test device according to claims 1 to 4, characterized in that, before placing the test device on the diagnosed part of the constructional structure with penetration, the free openable part (2) of the test device body is first opened together with the sleeve (9) connected to the free an opening part (2) of the body and a collar (10) of said sleeve (9). After opening the parts, the test device is threaded onto the passage and the collar (10 and 4) of the sleeve (9 and 3) on the first side of the test device is closed, then the test device is placed opposite the other side provided with contact surface (5) and free arm ( 6) connects the contact surface (5) to the diagnosed wall of the building structure with a penetration and by means of a flexible seal (7) connected to the contact surface (5) and its free arm (6) with this diagnosed wall of the building structure. The rigid arm (6) of the loose body part of the test device is thereby airtightly connected to the contact surface (5) of the fixed body part (1) by means of a connecting element (12) and the sleeve (9) and collar (10) are simultaneously connected with the sleeve (3). ) and collar (4). After attaching the sleeve (9 and 3) by the sleeve (10 and 4) to the diagnosed building structure penetration, the opening parts of the testing device (2, 9, and 10) are airtightly connected by means of a flange (11) and Velcro to the fixed part device, sleeve (3) and its collar (4), and at the same time airtightly connected to the penetration by means of Velcro. The hook-and-loop fasteners allow an airtight connection of the sleeve (9 and 3) and the collar (10 and 4) of the sleeve (9 and 3) to the various penetration profiles of the building structures. Upon joining the rigid and free openable parts of the test device, the test device becomes an airtight element. Subsequently, to the formed airtight element is connected by means of a connecting element (14) a device (13) for creating an underpressure or overpressure of air, preferably a vacuum pump and to its outer body a measuring device (8) for reading air pressure in the sealed part of the test device. After connecting these Λ · · · · ^W - - - '··· ··· ··· ··· ···· · * (13 and 8) is then put into operation the device (13) for creating a vacuum and positive pressure air, if necessary, the air pressure in this test apparatus is decreased or increased for measurement. The sealed air pressure measuring device (8) is then checked for the air pressure in the sealed portion of the test device when a pressure difference of - 0.2 bar is required under vacuum to verify that the passage connection to the building structure is airtight. and + 0.2 bar under air overpressure. After obtaining the measurement values, the device is reversed from the diagnosed building structure with the penetration from the system.