Apparatus for the Determination of the Surface Moisture of a Test Object

Information

  • Patent Application
  • 20090304041
  • Publication Number
    20090304041
  • Date Filed
    September 27, 2006
    18 years ago
  • Date Published
    December 10, 2009
    15 years ago
Abstract
An apparatus for determining the moisture of a surface, particularly a wall surface device for determining a room dew point, a surface temperature device for determining the surface temperature by means of an infrared radiation measuring instrument, and an assembly for determining the surface moisture from the room dew point and the surface temperature.
Description
BACKGROUND INFORMATION

The present invention relates to a device for determining the surface moisture of a measured object.


For mold evaluations of measured objects such as closed rooms, it is essential to determine the surface moisture of the walls of the rooms. There is a multitude of measuring methods geared towards determining the dew point spread instead of determining the surface moisture. It should be taken into consideration, however, that at different room and wall temperatures a constant dew point spread limiting value results in different values of surface moisture so that from the dew point spread it cannot be established in a reliable manner whether there is a risk of mold formation on the wall.


To determine the surface moisture of a measured object, known moisture sensors, which must be applied directly to the surface, may be used to determine the ambient humidity in a room; a wait of multiple hours being required before performing the actual measurement in order to equalize the experimental conditions to one another. In particular, the moisture sensors must be protected from the influence of the ambient air for this purpose. Therefore, this method is complex and time-consuming.


Alternatively, the surface temperature of the wall may first be determined, from which the surface moisture may be calculated if the room temperature and the room moisture are additionally determined. A surface detector, which also has a long equalization time, is used to determine the surface temperature. In addition, the surface temperature must be determined at many different points of the measured object to be measured in order to be able to make reliable statements about the surface moisture.


The object of the present invention is therefore to provide a device for determining the surface moisture of a measured object which is simpler to handle, but has a higher precision.


The object of the present invention is achieved by a device for determining the surface moisture of a measured object according to claim 1 and using a method for determining the surface moisture according to claim 12.


Advantageous embodiments and refinements of the present invention are specified in the subclaims.


The device according to the present invention for determining the surface moisture of a measured object, in particular a wall surface, has a fifth device for determining the room dew point, and a third device for determining the surface temperature using an infrared radiation measuring unit, as well as a system for ascertaining the surface moisture from the room dew point and the surface temperature. An advantage of this device is that the surface temperature is determined without contact using an infrared radiation measuring unit, which is significantly faster and more precise than determining the surface temperature using a surface detector. It is thus possible in particular to scan large-area wall surfaces rapidly in regard to the surface temperature and thus determine the surface moisture rapidly at different points of the wall surface, so that it is directly obvious whether the risk of mold formation exists at any points of the wall because of too high a surface moisture.


Preferably the fifth device is provided with a first device for determining the air humidity and a second device for determining air temperature, the system being able to ascertain the room dew point from the air humidity and air temperature, in order to determine the room dew point in a simple and reliable manner.


Preferably, the device is provided with a fourth device for producing a warning signal, in particular an acoustic and/or visual warning signal, if a critical value for the surface moisture is exceeded. The critical value is assigned a magnitude such that if the surface moisture exceeds it, the risk of mold formation exists. In order to provide an alert of this risk, a warning signal is output so that when an inspection of a wall is performed over a large area without registering all values ascertained for the surface moisture, it may also be easily established whether the risk of mold formation exists anywhere on the wall. An optical warning signal, which lights up or starts flashing, can be an additional indicator.


The critical value for the surface moisture is preferably 80%, since the risk of mold formation already exists starting at this value. If not only the risk of mold formation, but also a possibly existing risk of corrosion is to be checked, a critical value for the surface moisture of 60% suggests itself.


In an especially preferred embodiment of the present invention, the system is capable of ascertaining a critical surface temperature from the critical value for the surface moisture and the room dew point. The critical surface temperature thus corresponds to the critical value for the surface moisture, it being possible to ascertain in an especially simple manner therefrom whether the risk of mold formation exists.


For this purpose, the system is preferably capable of ascertaining a critical dew point spread from the critical surface temperature and the surface temperature. In principle, the dew point spread is calculated as the difference between the room dew point, which is determined from air humidity and air temperature, and the surface temperature. The critical dew point spread is determined in the present case as the difference between the critical surface temperature and the actual surface temperature. On the basis of the critical dew point spread, it is thus immediately obvious whether the risk of mold formation currently exists or whether mold formation may possibly occur in the event of only slight temperature differences in the room and on the surface.


The infrared radiation measuring unit is preferably an infrared pyrometer or an infrared camera. An infrared pyrometer only records data precisely; an infrared camera allows easy measurement and inspection of large surfaces.


The device is preferably provided also with an optical camera for generating an image in the visible spectrum area, which will be referred to as a visual image hereon, making it easy for the user doing the evaluation of the provided data to know where the data have been recorded.


The device preferably has a display for displaying the measured values of the first, second, and third devices and/or the ascertained room dew point and/or the ascertained surface moisture and/or the critical surface temperature and/or the critical dew point spread, and/or the visual image and/or the infrared image so that an operator may read off the measured and ascertained values immediately and take suitable measures, if necessary.


In a preferred embodiment of the present invention the system is designed in such a way that it provides an overlay of the ascertained surface moisture and/or the critical surface temperature and/or critical dew point spread with a visual image and/or the infrared image, that can be shown on the display. The overlay may preferably be presented by the system in such a way that the visual image and/or the infrared image is optically highlighted section by section, especially by using colors or by flashing. The overlay enables the user to easily identify at which part of the examined measured object there is a risk of mold formation. The examined measured object can be directly recognized by the user in the visual image or the infrared image. In addition, the endangered areas will be marked by the corresponding graphical presentation, for example, in that the endangered areas of the measured objects are presented in another color or by flashing, so that the user can identify directly in which areas of the examined measured objects it would be necessary to take action. In particular, this overlay provides an optical warning signal.


The first and/or second devices are preferably linked to the system via radio contact, in order to avoid high cable complexity, and to make it possible to situate the first and/or the second device in a space separate from the system.


The method according to the present invention for determining the surface moisture (TWallmois) of a measured object, in particular a wall surface (6), has the following steps. The room dew point and the surface temperature are determined with the appropriate devices. In particular, the surface temperature is determined quickly and effectively with the help of a contact-free infrared radiation measuring sensor. Subsequently the surface moisture is ascertained from the room dew point and the surface temperature.





An exemplary embodiment of the present invention will be explained in detail on the basis of the following figure.



FIG. 1 shows a schematic view of an exemplary embodiment of a device according to the present invention.






FIG. 1 illustrates schematically an exemplary embodiment of a device which is implemented as measuring unit 5 in particular. Measuring unit 5 is shaped like a pistol having a handle 5a and a measuring head 5b, which is comparable to the pistol barrel.


A first device 1 for determining air humidity TAirhum, which has a moisture sensor, for example, is situated below measuring head 5b in a carrier tube 5c through which air flows. Furthermore, a second device 2 for determining air temperature TAir using a temperature sensor is situated in carrier tube 5c. A third device 3 for determining surface temperature Twall of a wall surface 6 is located in measuring head 5b. Third device 3 has an infrared radiation measuring sensor, which detects the thermal radiation produced by wall surface 6 and may thus determine surface temperature Twall of wall surface 6 rapidly without long equalization times. The infrared radiation measuring sensor may be an infrared pyrometer or an infrared camera. Finally, device 5 may be provided with another optical camera, not shown, to provide a visual image. The moisture sensor of first device 1 and the temperature sensor of second device 2 also have short response times, so that the measurement may be performed rapidly.


Measured values TAirhum, TAir, and TWall ascertained by first device 1, second device 2, and third device 3 and, if necessary, the visual images or the infrared image are relayed to system 7 via a radio link, which further processes and analyzes measured values TAirhum, TAir, and TWall. First, room dew point TPRoom existing in the room is determined from air humidity TAirhum measured by first device 1 and air temperature TAir measured by second device 2, for which the known Magnus formula is typically used. Surface moisture TWallmois is ascertained in system 7 from surface temperature TWall determined using third device 3 and ascertained room dew point TPRoom using the following approximation formula







T
Wallmois

=



(


1.098
+


TP
Room

100



1.098
+


T
Wall

100



)

8


100.





In an infrared pyrometer this analysis may be performed only for one point of the examined surface; however, the infrared measuring sensor is preferably designed as an infrared camera so that a plurality of pixels of an infrared image is analyzed.


For example, first device 1 ascertains an air humidity TAirhum of 65% and air temperature TAir measured using second device 2 is 21° C. First, a room dew point TPRoom of 14.2° C. results therefrom using the Magnus formula. Furthermore, a value of 18° C. for surface temperature TWall of wall surface 6 is ascertained using third device 3. From these values; system 7 ascertains a surface moisture TWallmois of 78.5% using the above approximation formula.


Measuring unit 5 preferably has a fourth device 4 for producing a visual and/or acoustic warning signal if a critical value TWallmoisCrit for surface moisture TWallmois is exceeded. Critical value TWallmoisCrit for surface moisture TWallmois is assigned a magnitude such that if this value TWallmoisCrit is exceeded, a risk of mold formation on wall surface 6 exists. Fourth device 4 is equipped with an LED 4a and a loudspeaker 4b and connected to system 7 for this purpose. Typically, the use of one LED 4a or one loudspeaker 4b suffices. Critical value TWallmoisCrit for surface moisture TWallmois may be stored in system 7 or directly in fourth device 4. This value is 80%, for example. If not only the risk of mold formation but rather also a possibly existing risk of corrosion is to be checked, a critical value TWallmoisCrit for surface moisture TWallmois of 60% suggests itself. In the above-mentioned example, surface moisture TWallmois is at 78.5% and is thus below critical value TWallmoisCrit of 80%, so that an output of a warning signal by LED 4a or loudspeaker 4b is not necessary, since the risk of mold formation is negligible. If critical value TWallmoisCrit of 80% is exceeded, LED 4a may begin to light up or flash, or loudspeaker 4b may produce an acoustic signal once, multiple times, or continuously in order to notify the user of the risk of mold formation.


Furthermore, system 7 is equipped in such a way that it ascertains and stores a critical surface temperature TwallCrit from critical value TWallmoisCrit for surface moisture TWallmois. Critical surface temperature TWallCrit represents the temperature of wall surface 6 at which, under the given conditions, surface moisture which corresponds to critical value TWallmoisCrit or more may occur and the risk of mold formation may thus exist, and is determined at a critical value TWallmoisCrit of 80% using the following approximation formula:







T
WallCrit

=


(



1.098
+


TP
Room

100


0.9572

-
1.098

)


100.





In the present example, the resulting critical surface temperature TwallCrit is 17.4° C. It is thus only 0.6° C. lower than previously ascertained actual surface temperature TWall of wall surface 6 of 18° C. The risk of mold formation could thus exist if wall temperature TWall of wall surface 6 is only slightly reduced. System 7 ascertains this difference of 0.6° C. as a critical dew point spread TPCrit of critical surface temperature TWallCrit and surface temperature TWall. It may be read off rapidly and easily on the basis of critical dew point spread TPCrit whether the risk of mold formation currently exists and whether even slight changes in the room climate may possibly result in a risk of mold formation.


Furthermore, measuring unit 5 has a display 8 on which measured values TAirhum, TAir, and TWall measured by first device 1, second device 2, and third device 3, as well as values TPRoom, Twallmois, TwallCrit, and TPCrit ascertained therefrom by system 7 may be displayed. The stored values such as critical value TWallmoisCrit for surface moisture TWallmois may also be displayed on display 8. Display 8 may also have a function switch (not shown), using which the display may be switched over between different measured values TAirhum, TAir, and TWall or ascertained values, TPRoom, Twallmois, TWallCrit, and TPCrit.


Display 8 may also be used for presenting a visual image or an infrared image and may send out optical warning signals in particular. Additional light-emitting diode 4a may then be eliminated. To that effect, system 7 overlays the visual image or the infrared image with the corresponding ascertained values TPRoom, TWallmois, TWallCrit, TPCrit. If, for example the visual image or the infrared image is overlain with a surface moisture image, which shows the surface moisture of every point in the image, or alternatively with a dew point spread image which shows the dew point, i.e., the difference between the room dew point TPRoom, calculated from the air humidity TAirhum and air temperature TAir, and the surface temperature TWall, for every point in the image, the user will be able to identify immediately, in which areas of the measured objects the risk of mold formation or precipitation of moisture exists. In particular, those areas of the measured object in which the critical value TWallmoisCrit for the surface moisture TWallmois is exceeded or falls below a preset dew point spread, particularly the critical dew point spread TPCrit, are optically highlighted with a corresponding color or through flashing, by which an optical warning signal is provided for the user, making the user aware that this area must be inspected.


Furthermore, measuring unit 5 has a switch 9 on handle 5a, using which measuring unit 5 may be turned on and off. The different measurements by first device 1, second device 2, and third device 3 may be started using switch 9 or a further switch (not shown). By scanning entire wall surface 6, it may be determined rapidly and easily whether the risk of mold formation exists at any points of wall surface 6.


LIST OF REFERENCE NUMERALS




  • 1 first device


  • 2 second device


  • 3 third device


  • 4 fourth device


  • 4
    a LED


  • 4
    b loudspeaker


  • 5 measuring unit


  • 5
    a handle


  • 5
    b measuring head


  • 5
    c carrier tube


  • 6 wall surface


  • 7 system


  • 8 display

  • 9 switch

  • TAir air temperature

  • TAirhum air humidity

  • TPRoom room dew point

  • TWall surface temperature of the wall surface

  • TWallmois surface moisture of the wall surface

  • TWallCrit critical surface temperature

  • TWallmoisCrit critical surface moisture

  • TPCrit critical dew point spread


Claims
  • 1. A device for determining surface moisture of a surface, comprising: a dew point device for determining room dew point;a surface temperature device for determining surface temperature using an infrared radiation measuring unit; anda system for ascertaining the surface moisture from the room dew point and the surface temperature.
  • 2. The device as recited in claim 1, wherein the dew point device is provided with an air humidity device for determining air humidity and an air temperature device for determining air temperature, and wherein the system determines the room dew point from the air humidity and the air temperature.
  • 3. The device as recited in claim 1, further comprising: a warning device for producing a warning signal if a critical value for the surface moisture is exceeded.
  • 4. The device as recited in claim 3, wherein the critical value for the surface moisture is 80%.
  • 5. The device as recited in claim 3, wherein the system determines a critical surface temperature from the critical value for the surface moisture and the room dew point.
  • 6. The device as recited in claim 5, wherein the system determines a critical dew point spread from the critical surface temperature and the surface temperature.
  • 7. The device as recited in claim 1, wherein the infrared radiation measuring unit is at least one of: an infrared pyrometer and an infrared camera.
  • 8. The device as recited in claim 1, further comprising: an optical camera for providing a visual image.
  • 9. The device as recited in claim 1, further comprising: a display for displaying at least one of: air humidity, air temperature, the surface temperature, room dew point, the surface moisture, a critical surface temperature, a critical dew point spread, a visual image and an infrared image.
  • 10. The device as recited in claim 9, wherein the system provides an overlay of at least one of: the surface moistures the critical surface temperature, and the critical dew point spread (TPCrit) with at least one of: the visual image and the infrared image, and wherein the overlay is shown on the display.
  • 11. The device as recited in claim 10, wherein the overlay is displayed in such a way that at least one of: the visual image and the infrared image is optically highlighted section by section, by using colors and by flashing.
  • 12. The device as recited in claim 2, wherein at least one of: the air humidity device the air temperature device are connected to the system through a radio link.
  • 13. A method for determining surface moisture of a surface, comprising: determining the surface temperature using an infrared radiation measuring unit;determining room dew point; and ascertaining the surface moisture from the room dew point and the surface temperature.
  • 14. The method as recited in claim 13, wherein in order to determine the room dew point first air humidity and air temperature is determined and then the room dew point is ascertained from the air-humidity and the air temperature.
  • 15. The method as recited in claim 13, wherein when a critical value for the surface moisture is exceeded, a warning signal is produced.
  • 16. The method as recited in claim 15, wherein the critical value for the surface moisture is 80%.
  • 17. The method as recited in claim 15, wherein a critical surface temperature is determined from the critical value for the surface moisture and the room dew point.
  • 18. The method as recited in claim 17, wherein a critical dew point spread is determined from the critical surface temperature and the surface temperature.
  • 19. The method as recited in claim 13, wherein at least one of: a visual image and an infrared image is taken of the surface.
  • 20. The method as recited in claim 13, further comprising: displaying on a display at least one of: air humidity air temperature, the surface temperature, the room dew point, the established surface moisture, a critical surface temperature, a critical dew point spread, a visual image and an infrared image.
  • 21. The method as recited in claim 20, wherein an overlay of at least one of: the surface moisture, the critical surface temperature and the critical dew point spread is presented with at least one of: the visual image and the infrared image, which are shown on the display.
  • 22. The method as recited in claim 21, wherein the overlay is created in such a way that at least one of: the visual image and the infrared image is optically highlighted section by section, by using colors or by flashing.
  • 23. A device for determining dew point spread of a surface, comprising: a dew point device for determining room dew point;a third device for determining surface temperature using an infrared radiation measuring unit;a system for providing the dew point spread from the room dew point and the surface temperature;an optical camera for providing a visual image; anda display, wherein the system provides an overlay of the dew point spread using the visual image which is presented on the display.
  • 24. The device as recited in claim 23, wherein the dew point device has an air humidity device for determining air humidity and air temperature device for determining air temperature and the system determines the room dew point from the air humidity and the air temperature.
  • 25. The device as recited in claim 23, wherein the overlay is produced by the system in such a way that the visual image is highlighted optically section by section by using color or flashing.
  • 26. The method for determining dew point spread of a surface, comprising: determining room dew point;determining surface temperature using an infrared radiation measuring unit;ascertaining the dew point spread from the room dew point and the surface temperature;providing a visual image; andproviding an overlay of the dew point spread with the visual image.
  • 27. The device as recited in claim 26, wherein for determining the room dew point first air humidity and air temperature are provided and then the room dew point is established from the air humidity and the air temperature.
  • 28. The device as recited in claim 26, wherein the overlay is created in such a way that the visual image is highlighted optically section by section by using color or flashing.
Priority Claims (1)
Number Date Country Kind
202005015397.4 Sep 2005 DE national
PCT Information
Filing Document Filing Date Country Kind 371c Date
PCT/EP2006/009380 9/27/2006 WO 00 8/10/2009