NL1030854C2 - Method and assembly are for analysis of stone, concrete or brick object for detection of one or more weaknesses in object - Google Patents

Abstract

The method and assembly are for the analysis of stone, concrete or brick object for detection of one or more weaknesses in the object and a drying stage of the object is involved. During or after the drying, a visual analysis is made of at least a part of the surfaces (2,3) of the object (1) in order to detect local color differences in the surfaces corresponding to one or more weaknesses (4,8). The equipment assembly used for the analysis comprises an analogue optical camera, a digital optical camera, a video camera or a thermo-optic picture taking device. A device is also used for comparison of two or more pictures taken in order to detect object surface color differences.

Description

Short indication: Method and composition for analyzing a stone object for detecting one or more attenuations in the object.

5 DESCRIPTION

The present invention relates to a method for analyzing a stone object for detecting one or more attenuations in the object; and a composition for carrying out such a method.

10 Stone, and in particular natural stone, is a popular and frequently used building material. For example, natural stone is widely used in the finishing of buildings, on floors, in kitchens and bathrooms, on walls, etc. Stone is also popular because it is robust and a structure or structure can provide the desired strength. In the latter case, for example, brick, concrete elements, etc., which play an important role in the construction of a structure, can be envisaged.

Although stone building materials are generally robust, weakening of the material, such as cracks, cavities in the rock (eg caused by air bubbles in, for example, concrete) or places or areas with a relatively large porosity, can considerably weaken the strength of the material. If stone building materials are incorporated in the construction of a building, it is of great importance for safety to be able to detect such weakening of the material early. In the alternative case, when stone building materials are used for finishing a building, for example natural stone, it is also important that local weakening of the material is known beforehand, since this can be taken into account, for example, when processing the material.

For example, in the manufacture of granite counter tops for kitchens, blocks of granite with dynamite are extracted from earthly rock. The recovered debris is then, for example with a diamond saw, sawn into plates of suitable dimensions. Afterwards, holes and recesses are cut in suitable places in the kitchen counter, for example in accordance with the information provided by the buyer of the granite kitchen or counter top, for sinks, taps, etc. The granite 1030854-2 kitchen top thus obtained is attached to one delivered to the buyer.

During the processing of the granite, for example when the granite block is extracted with dynamite, cracks can form in the granite due to the forces created thereon. These cracks can have dimensions that are so small that they are not visible to the naked eye (hair cracks). Although the presence of hairline cracks does not cause any aesthetic problems, the strength of the granite worktop at the location of the hairline crack is weakened. For example, if a hole or recess is cut in the worktop in the vicinity of a hairline in the granite for, for example, a sink, the worktop may break on the hairline and get lost. This can already happen during processing, but can also only take place after a while, when the magazine has already been placed.

The skilled person will understand that when processing building materials, the stone building materials in which large cracks occur will immediately be rejected. The building materials selected in such a way may possibly still be processed for smaller stone objects, or may be pulverized and optionally recycled. Stone objects in which damage occurs which are of such small dimensions that they are difficult to see with the naked eye, such as hairline cracks, will not immediately catch the eye during processing, and can therefore only be detected using appropriate analysis techniques. These techniques include the use of ultrasound, microwaves, vibrations, and the like, and are cumbersome and expensive. The use of such analysis methods is often not commercially interesting and is therefore often omitted. The result of this is breakage during the processing of stone building materials, and deteriorated quality of the end product.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for analyzing a stone object, for detecting one or more attenuations in the stone object, which can be performed quickly and efficiently during the manufacturing process on a cost effective way.

It is also an object of the present invention to provide such a method and composition with which attenuations in the object 1030854a 3 can be accurately detected, even for attenuations with small dimensions.

This object is achieved by the present invention in that it provides a method for analyzing a stone object for detecting one or more attenuations in the object, comprising the step of drying the stone object, further comprising a step of during or after drying, visually analyzing at least a portion of a surface of the object to detect local color differences on the surface corresponding to the one or more attenuations.

The method according to the invention is based on the insight that the stone object dries more slowly at the area of weakening since moisture accumulates in the weakening. Because the interior of the weakening is physically sealed off from the environment, a stone object at the site of weakening will dry more slowly and after drying, color differences will occur which betray the presence of moisture in the stone object and its location. Attenuations can be detected efficiently in this way. The method can easily be carried out during the processing of stone objects, since during processing the stones often already have a certain degree of humidity which is sufficiently large to be able to successfully use the above-mentioned method.

The method can also be applied, for example, immediately after a sawing, grinding or similar operation. During such operations, water cooling of the tool is often used, so that the stone object is wet or damp after the operation. The method according to the invention can then be used directly for detecting the weakening.

However, according to an embodiment of the invention, prior to drying the object, the stone object can be moistened with a liquid. The method according to the invention can then be carried out at any time, regardless of the degree of moisture of the brick object. The object can be moistened with, for example, water, but a different liquid can also be chosen.

The liquid used to wet the stone object is selected with a suitable viscosity, to obtain a desired drying rate during the drying step. If a liquid with a low viscosity is chosen, the object will dry much faster than if the object is moistened with a liquid with a higher viscosity. The advantage of choosing a liquid with a low viscosity is that due to the higher drying speed the process can be carried out faster, which leads to improved efficiency. The advantage of using a liquid with a higher viscosity, in which the drying speed is actually slower, is that the drying process, precisely because of its slower course, can be better studied, since more time is then available for that. Much information can be obtained from this, as will be further elaborated below. The choice of the liquid used for wetting may, therefore, depend on the application of the method with regard to its viscosity. However, with the use of water as a wetting fluid, the method already yields good results with regard to the detection of attenuations.

According to a preferred embodiment of the invention, the step of visually analyzing the at least one part of the surface of the object comprises locating the local color differences on the surface. Local differences in humidity of the rock are expressed in color differences (usually lighter and darker parts of the surface, the darker parts corresponding to a higher degree of humidity). Analyzing the color differences, and determining the location of striking color differences, makes it possible to locate the precise location of weakening.

Visual analysis may, in accordance with a preferred embodiment of the invention, comprise making at least one image recording of the at least one part of the surface. Such an image recording can then be analyzed in a suitable manner, for example with suitable software. For making image recordings, use can for instance be made of optical image recording means, which are for instance selected from a group comprising an analog optical camera, a digital optical camera, analog or digital video recording means.

In the alternative case, use can be made of thermo-optical image recording means for making the at least one image recording. The use of thermo-optical image recording means provides the advantage that surface contamination is not visible on the recording, and therefore cannot adversely affect the result of the analysis. However, a disadvantage of using the thermo-optical cameras is their relatively low resolution. This is much larger when using optical image recording means, such as for example digital cameras. Due to the larger resolving power, attenuations of much smaller dimensions can be detected with the optical camera.

Both of the above options offer advantages when used in the method according to the invention. The choice of the image recording means can therefore be made dependent on the application of the method, whereby the above-mentioned advantages can be kept in mind.

According to a further embodiment of the invention, a plurality of image recordings are made sequentially during the drying step, to analyze time-dependent changes in color differences during drying. Thus, for example, the speed at which the rock dries can be studied locally, and in particular the drying speed of the brick object at the site of the weakening can be compared with the drying speed elsewhere on the surface of the brick object. By determining the speed of drying of, for example, cracks, an estimate can be made of the depth of the crack. In this way an estimate can be made of the severity of the weakening. Those skilled in the art will understand that a shallow crack in the rock affects the strength of the stone object to a much lesser extent than a deep crack.

According to a further embodiment of the invention, visual analysis of the at least one part of the surface comprises making and mutually comparing a plurality of image recordings, the plurality of image recordings comprising a plurality of magnifications of the at least one part of the surface. Those skilled in the art will understand that it is advantageous to analyze a surface in such a way that first a global overview of the surface is obtained, after which different parts of the surface are again accurately analyzed. This can be achieved by making an image recording of the entire surface (or a prominent part thereof), after which certain parts of the surface are then enlarged to a greater and lesser extent 4030854-6, with the aid of, for example, further recordings in order to obtain the images found therein. analyze weaknesses well.

In a particular embodiment of the method according to the invention, a step of wetting the stone object as described above comprises, and prior to the step of wetting, a step of making a reference recording of the at least one part of the surface. Moistened and again dried surface are compared with the surface of the stone object even before it was moistened, so that color differences that have arisen at the area of weakening are emphasized in particular. Attenuations can be detected much faster and more accurately.

According to a further embodiment of the invention, the visual analysis step is started if after or during the drying step the object reaches a suitable degree of humidity, the color difference between damaged and undamaged parts of the surface being visually detectable. If the surface of a stone object is still too damp, it may be that the color differences between damaged and undamaged parts of the surface are hardly visible, because the moisture content in the stone is saturated. On the other hand, if the surface of the brick object has dried too much, then it may also be that the color differences between the damaged and undamaged parts of the surface also fade too much (because the damaged parts are already (almost) dry) , and that is precisely why they are no longer visible. The method according to the invention is in particular well applicable if the surface of the brick object has a degree of humidity wherein the color differences of the parts that are still wet while damaged are just clearly visible with respect to the undamaged parts thereof. The optimum moisture content depends on the rock to be examined, the color and the structure thereof. In particular, the difference in humidity between damaged and undamaged parts must be sufficiently large.

The drying step can be carried out in various ways. The rock can be air dried, but it is also possible to speed up the drying process by blowing the stone object dry (with hot or cold air) or by heating the stone object.

According to a further embodiment, the brick 103 08 5 4 - 7 object comprises a plurality of sides, and the at least one part of the surface that is visually analyzed comprises at least a part of one or more of these sides. In particular, when the stone object is, for example, a stone plate such as a tile, a counter top, or a specifically formed other surface, the stone plate being a work surface and a bottom surface facing away from the work surface and situated on the opposite side thereof. , the visual analysis step can be performed on both the work surface and the bottom surface. Thus, it can be achieved that all attenuations of any interest are detectable with the aid of a method according to the invention.

The method according to the invention can be used to detect and / or localize attenuations that influence the extent to which the rock can absorb liquid. In particular, damage such as cracks, irregularities (pits or trenches) in the surface, and the like, but also cavities located in the rock (such as, for example, cavities in the concrete resulting from air bubbles at the manufacture of the concrete), or places and areas where in the rock where the porosity is higher than the average porosity of the rock.

Stone objects that can be examined in this way can for instance be manufactured from a material comprising natural stone, composite stone such as quartz composite, brick or concrete.

According to a second aspect thereof, the invention provides a composition for analyzing a stone object, for detecting one or more attenuations, in the stone object, comprising means for drying the stone object, and means for visually analyzing At least a portion of a surface of the object, for detecting local color differences on the surface corresponding to the attenuation.

Particular embodiments of the composition according to the second aspect of the invention are described in the dependent claims.

The invention will be described below with reference to a specific embodiment thereof, which is not intended to be limiting, with reference to the accompanying drawings. The described embodiments are particularly aimed at the detection of cracks in natural stone, but the method according to the invention can also be used for detecting and locating other types of damage that locally influence the liquid uptake of the stone object. This can be understood to mean, for example: cavities in the rock, areas with a relatively large porosity, unevenness of the surface of the object, and such weakening. In the attached drawings: figure 1a is a cross-section of a moist stone object to be examined; figure 1b shows a top view of the moist, stone object to be investigated of figure 1a; Figures 2a and 2b take pictures of a surface of a stone object before and after wetting according to a method according to the present invention; 3a-3d show a reference recording, as well as three sequential image recordings made during an analysis method according to the invention.

Figure 4 shows a composition according to the second aspect of the invention.

The present invention is based on the insight that when a stone object is or is moistened, weakenings, such as cracks or areas with a relatively high porosity, can absorb a much larger amount of liquid in the stone object than parts of the rock in which no prevent cracks. Rocks such as natural stone, but also artificially manufactured stones such as (quarter) composite, bricks or concrete, are porous, as a result of which the rock easily absorbs water and the water slowly penetrates into the rock. However, if the rock is cracked, the liquid can easily penetrate into the crack and easily reach much deeper portions of the rock. The crack in the rock moreover has certain dimensions, and comprises cavities or spaces in which liquid can accumulate.

The invention is based on the insight that when a damp or wet rock is dried, the rock dries much slower at the location of the cracks since there is much more water at the location of the crack. Another reason for the relatively slow drying process at the location of cracks in the rock is the fact that the liquid can penetrate deeper into the stone, and therefore it takes longer for this water to evaporate. This has the consequence that when a damp or wetted rock is dried again, color differences occur on the surface of the rock during drying, which betray the location of the cracks. When a rock contains relatively much moisture, the rock is relatively dark in color, while the surface of the dry rock is much lighter. Due to the slow drying process at the location of the crack, the surface of, for example, a stone object, which after drying is dried, will at some point be relatively light in color, while dark discolorations can be seen at the area of weakening.

Figure 1a schematically shows a cross section of a natural stone slab 1. The natural stone slab 1 has a first surface 2 and a second surface 3. In the natural stone slab there is a hairline 4, which is not visible to the eye, the dimensions of which are slightly exaggerated in figures 1a and 1b for the sake of clarity of the figure.

The stone plate 1 was cut to size with a diamond saw a short time ago, while the blade of the diamond saw was constantly cooled with water during sawing. And the natural stone slab 1 is therefore moist. And the local humidity is shown with dots in Figure 1a, where the density of the dots in Figure 1a is a measure of the local humidity.

The wet stone slab 1 is artificially dried for some time according to a method of the present invention. The cross-section of the stone plate 1 shown in Figure 1a shows the state of the stone plate 1 after the plate has been subjected to the drying process for some time.

The inner rock 7 in the vicinity of the surface 2 (as well as the inner rock in the vicinity of the surface 3) has a relatively low degree of humidity, since the moisture 2 has been evaporating through the surface 2 (and the surface 3) for some time. occurred in the rock. The humidity in the inner 9 of the stone, on the other hand, is slightly higher than in the vicinity of the surface, since it also takes longer for the inner 9 of the stone slab 1 to be completely dried.

Because water has accumulated in the hairline when the stone plate 1 is moistened, the degree of humidity of the rock in the vicinity of the crack 4, for example at the indicated location 8 in the rock, is much higher than elsewhere in the rock ( for example in comparison with the degree of humidity of the rock at indicated location 7 near the surface 2, or even relative to the degree of humidity in the interior 9 of the stone slab 1).

A recording of the surface 2 of the stone slab 1 is made after the drying step, and the result thereof can be seen in Figure 1b.

Although in reality it is not visible to the naked eye, for the sake of clarity the hairline 4 is shown in Figure 1b. With the help of shading 10 and 11, the color difference between the relatively dry and relatively moist parts of the surface in Figure 1b is also made clear. It can be seen that in the middle of the surface, for example at the location indicated by reference numeral 11, the degree of moisture of the rock is relatively small, so that the stone is relatively light in color, while precisely in the vicinity of the hairline 4, for example at the location indicated by reference numeral 10, the rock is more moist so that this part of the surface 2 looks much darker on the recording. The dark spot 10 in the inclusion of the surface 2 therefore indicates the location of the hairline.

15 If the surface of a stone object comprises color differences of its own, or if this surface is contaminated, it may be that when a recording is made after drying of the rock, the dark spots associated with hairline cracks are indistinguishable from others discolourations on the surface. This can be overcome with the aid of a reference recording, as is made clear in figures 2a and 2b.

In Figure 2a, a surface of a stone object is photographed before the stone object was wetted during a method according to the invention. The surface 15 comprises a spot 17. After the stone object has been moistened, the surface is actively dried, and a recording is made again after some time. The result of this second recording can be seen in Figure 2b.

Figure 2b again shows surface 15 comprising the spot 17. The image in figure 2b also shows a dark spot 18 which was not yet visible on the image made before the wetting (figure 2a). Therefore, by comparing the recordings from Fig. 2b and Fig. 2a with each other, contaminations of the surface that were already present before the wetting can be easily identified and ignored. Discolourations of the surface that are visible in Figure 2b (such as discoloration 18) and that were not yet visible in Figure 2a may indicate the presence of weakening, such as hairline cracks.

1030854-11

Figures 3a-3d show four images of a surface 20 of a stone object that is analyzed with a method according to the invention. The surface 20 of the stone object comprises a spot 23 which is the result of a contamination of the surface. In figure 3a reference reference 21 can be seen, which recording was made with a digital optical camera before the stone object was wetted.

After moistening of the stone object, and after the stone object has been subjected to a drying process for some time, a second recording 25 is made of the surface 20. On top of the contamination 23 two dark spots 27 and 28 can be applied to the surface. see. The dark spots 27 and 28 reveal the locations of two cracks in the rock.

The drying process is continued, and after a while a third recording 30 of the surface 20 is made with the digital optical camera. This shows again the contamination 23 as well as the two dark spots 27 and 28. With respect to the receiving 25, the dark discolorations 27 and 28 of the surface 20 of the rock have now become somewhat lighter, which is to be expected since drying the degree of moisture of the rock at the location of the hairline cracks has also decreased. However, it can be seen that the color difference between the dark discoloration 27 in recording 25 and the same discoloration 27 in recording 30 is much greater than the color difference in the dark discoloration 28 in recording 28 and the same dark discoloration 28 in recording 30. This is say that the humidity level at the location of discoloration 28 is still much greater than the humidity level of the rock at the location of dark discoloration 27 at the time that recording 30 was taken. The rock dries much slower at the location of the dark discoloration 28 than at the location of discoloration 27.

Figure 3d shows a fourth shot which was made after the drying process was continued for some time. The dark discoloration 27 has almost completely disappeared in recording 32, but the dark discoloration 28 has indeed become lighter, but is still clearly present. Pollution 23 30 can also be seen again.

The recordings 25, 30 and 32 of Figures 3b, 3c and 3d make it possible to analyze the speed of the drying process at the location of the cracks by comparing the recordings with each other. Since the color difference between the dry surface and the wet surface is a measure of the 10.? 08 54-12 humidity of the wet surface, it is possible to estimate the extent to which the humidity changes by analyzing the color differences of the discolorations 27 and 28 as a function of time (by comparing the recordings 25, 30 and 32 and comparison 5 of these recordings with the reference recordings 21 shown in Figure 3a).

If the change in the degree of humidity as a function of time is known, then an estimate can be made of the depth of the hair cracks in the rock. This principle is based on the insight that the moisture content in the vicinity of a shallow crack decreases much faster during drying than the moisture content in the vicinity of a deep crack. Those skilled in the art will understand that the depth of the crack is a measure of the severity of the weakening. A relatively shallow crack is less likely to lead to fracture of the stone object than a deep crack. A stone object may or may not be approved based on the results of such an analysis.

Figure 4 shows schematically a composition according to the second aspect of the invention, with which the method according to the invention can be carried out. The composition schematically indicated by reference numeral 34 consists of a first part 35 on which the stone object can be presented for input to the composition. The stone object is moistened in the car wash 36, after which the object with conveyor belt 33 is transported to analysis room 38. A drying unit 37 blows hot air with the aid of outflow opening 39 onto the stone object to be analyzed in the analysis room 38. During or after drying, camera 40 takes pictures of the surface to be analyzed. The images 25 made with camera 40 are sent to processing unit 44, which digitally processes and analyzes the images. The results of the analysis, or recordings, are displayed to the user on image display means 45. This may or may not approve or reject the stone object based on the images shown.

A special embodiment of the composition 30 according to the invention comprises a unit 41 with which the orientation of the stone object can be changed. For example, the brick object can be turned over or tilted to make the bottom of the brick object available for analysis. After the stone object has been tilted, it can, for example, be moistened again in car wash 36 and analyzed in analysis room 38.

1030854-13

Those skilled in the art will understand that the method can also be implemented in a different manner than with the aid of the composition shown in Figure 4. The method can also comprise further analysis steps which are obvious to the person skilled in the art based on the above description. The scope of protection of the present invention is only limited by the following claims.

1030854-

Claims (31)

Method for analyzing a stone object, for detecting one or more attenuations in the object, comprising the step of drying the stone object, further comprising a step of visually analyzing at or after drying at least a portion of a surface of the object for detecting local color differences on the surface corresponding to the one or more attenuations. 2. Method as claimed in claim 1, wherein the visual analysis comprises locating the local color differences on the surface. Method according to any one of the preceding claims, wherein the visual analysis comprises making at least one image recording of the at least one part of the surface. 4. Method as claimed in claim 3, wherein the at least one image recording is made with the aid of optical image recording means. The method of claim 4, wherein the optical image recording means are selected from a group comprising an analog optical camera, a digital optical camera, analog or digital video recording means. 6. Method as claimed in any of the claims 3-5, wherein the at least one image recording is made with the aid of thermo-optical image recording means. The method of any one of claims 3-6, wherein a plurality of image recordings are made sequentially during the drying step, for analyzing time-dependent changes in color differences. The method of claim 7, further comprising a step of analyzing the change in color differences to determine the drying rate of the object at the attenuation site. 9. Method as claimed in any of the foregoing claims, wherein the visual analysis comprises making and mutually comparing a plurality of image recordings of a plurality of magnifications of the at least one part of the surface. A method according to any one of the preceding claims, wherein prior to drying the object, the stone object is moistened with a liquid. 1030854- The method of claim 10, wherein the liquid is selected with a suitable viscosity, for obtaining a desired drying rate during the drying step. 12. Method as claimed in any of the claims 10 or 11, wherein the liquid comprises water. The method of any one of claims 10-12, further comprising a step of making a reference recording of the at least one portion of the surface prior to the step of wetting the brick object. 14. Method according to claim 13, insofar as dependent on at least one of claims 3-9, wherein the step of visual analysis comprises a step of comparing the at least one image recording with the reference recording. 15. Method as claimed in any of the foregoing claims, wherein the step of the visual analysis is started if after or during the step of drying the object reaches a suitable degree of humidity wherein the color difference between damaged and undamaged parts of the surface can be visually detected. 16. Method as claimed in any of the foregoing claims, wherein the step of drying is selected from a group comprising blowing dry with hot or cold air, heating the object, and air-drying. The method of any one of the preceding claims, wherein the brick object comprises a plurality of sides, and wherein the at least one portion of the surface that is visually analyzed comprises at least a portion of one or more of the plurality of sides. A method according to any one of the preceding claims, wherein the stone object comprises a stone plate. 19. Method as claimed in claims 17 and 18, wherein the stone plate comprises a working surface and a bottom surface facing away from the working surface and located on the opposite side of the plate, wherein the step of visual analysis is carried out on the working surface and the bottom surface. A method according to any one of the preceding claims, wherein the attenuations to be detected comprise at least one element selected from a group comprising damage such as cracks or pits, cavities or areas in the stone object with an above-average porosity relative to the average porosity of 1030854 the stone object. 21. Method as claimed in any of the foregoing claims, wherein the stone object is manufactured from a material comprising at least one element selected from a group comprising natural stone, composite stone such as quartz composite, brick or concrete. A composition for analyzing a stone object, for detecting one or more attenuations in the stone object, comprising means for drying the stone object, and means for visually analyzing at least a part of a surface of the stone object object, for detecting local color differences on the surface corresponding to the attenuation. The composition of claim 22, wherein the means for visually analyzing the at least one portion of the surface comprises means for making at least one image recording of the surface. The composition of claim 23, wherein the means for making the at least one image recording is selected from a group comprising an analog optical camera, a digital optical camera, analog or digital video recording means, thermo-optical image recording means. 25. Composition as claimed in any of the claims 23 or 24, wherein the means for making the at least one image recording are adapted to make a plurality of image recordings sequential. 26. A composition according to any one of claims 23-25, wherein the means for visually analyzing comprises means for analyzing the at least one image recording for detecting color differences of the surface. 27. Composition as claimed in claims 25 and 26, wherein the means for analyzing the at least one image recording are adapted to mutually compare two or more image recordings of the plurality of image recordings, for detecting differences between the two or more image recordings . The composition of claim 27, wherein the means for analyzing the at least one image capture is adapted to detect changes in local color differences in the two or more mutually similar image recordings. t 03 08 54 -_ The composition of at least one of claims 22-28, further comprising means for wetting the stone object with a liquid. 30. Composition as claimed in at least one of claims 29, insofar as dependent on at least one of claims 21-26, wherein the means for making the at least one image recording are arranged for making at least one reference recording, prior to wetting the stone object. 31. A composition according to at least one of claims 22-30, wherein the means for visually analyzing the at least one part of the surface are arranged for visually analyzing a plurality of surfaces of the stone object. 1030854-_