KR20050071824A - Thickness deviation measuring apparatus for brick panel and the measuring method - Google Patents

Abstract

The present invention relates to a method for measuring thickness deviation of a building exterior stone panel and a device thereof, wherein a distance measuring means such as a dial gauge is installed on a bridge-type slide bar installed in a movable state by guide rails installed at both ends of a surface plate. And it is a thickness deviation measurement method and measuring device of the building exterior stone panel for measuring the height deviation of the bolt fastening position of the stone panel placed on the surface plate through the measuring means.

Description

Thickness deviation measuring apparatus for brick panel and the measuring method

The present invention relates to a device and a method for measuring the thickness deviation of each part of the flat panel, and more particularly, to a method and measuring device for measuring the thickness deviation of the stone panel used for processing the exterior of the curtain wall type.

In general, the stone panel installed as an exterior finishing material in the form of a curtain wall in a building such as a large building is used to process a natural standard marble or granite in the form of a square standard panel having a certain thickness and width. Such stone panels show thickness deviations for each part due to mass production and processing accuracy limitations. Due to the thickness deviation of the stone panel as described above, when installing the stone panel in the form of a curtain wall on the truss or frame of the building, it is difficult to precisely align the outer wall surfaces of adjacent stone panels side by side to form a curved outer wall surface There is a problem that acts as a factor, and there is a problem that acts as a factor not only to lower the construction efficiency, but also to reduce the appearance of the building due to the correction work for the correction and the like.

On the other hand, since the thickness deviation of the stone panel as described above affects the fastening depth of the anchor bolt, in particular, when the anchor bolt is coupled to the relatively thin portion of the thickness of the stone panel has a problem that the stone panel is broken by breaking.

Therefore, the building stone panels should be inspected for their thickness deviations before they are constructed with curtain walls. The necessity of measuring the thickness deviation of the stone panel is increasing with the advancement of the building.

However, current measuring instruments are not only easy to precisely measure the thickness of the stone panel, but also have a problem in that inspection efficiency is lowered. Therefore, the inspection and precise thickness measurement of the stone panel are not performed properly. During the construction of the worker attaching the stone panel to the outer wall of the building, the anchoring bolts are adjusted while adjusting the mounting depth of the anchor bolts. There is a difficulty to correct the degree of protruding stone panel from the truss or frame.

The present invention was created in view of the above problems, and an object of the present invention is to measure the thickness deviation of the stone panel thickness deviation with respect to the anchor bolt fastening position of the building panel stone panel in large quantities easily and precisely And to provide a measuring device using the measuring method.

Further, another object of the present invention is to calculate the thickness deviation data for the anchor bolt fastening position of the stone panel by using the thickness panel measurement method and measuring device for achieving the above object, based on the data In order to facilitate the adjustment of the anchor bolt depth in advance when the curtain wall construction to facilitate the maintenance of the curtain wall construction efficiency of the stone panel and the quality of the exterior wall.

The apparatus for measuring thickness deviation of a stone panel according to the present invention for achieving the above object includes a surface plate having a pair of guide rails installed at both ends, a slide bar installed in a bridge shape to be movable along the guide rail, and placed on the surface plate. The paper is characterized in that it comprises at least one distance measuring means movably installed on the slide bar to measure the height deviation for any position of the stone panel.

And, in order to achieve the above object, the method for measuring the thickness deviation of the stone panel according to the present invention, in the method for measuring the relative thickness deviation with respect to the plurality of bolt fastening positions of the building exterior stone panel, the building exterior stone panel is placed Setting a zero point of the distance measuring means provided to be movable above the ground plate, setting the stone panel on the surface plate, and height of the bolt fastening point of the stone panel through the distance measuring means. Comprising a step of calculating the height data for each point, and comparing the respective height data for the bolt fastening point of the stone panel, characterized in that it comprises the step of calculating the data of the relative thickness deviation.

Hereinafter, with reference to the accompanying drawings will be described a method and measuring device for measuring the thickness deviation of the building panel stone exterior according to an embodiment of the present invention.

1 to 3, the thickness deviation measuring apparatus 100 of the stone panel according to the preferred embodiment of the present invention includes a surface plate 110, first and second guide rails 121 and 122, and The first and second movement guides 131 and 132, the slide bar 140, the first and second position adjustment guides 151 and 156, and the first and second dial gauges 161 and 166. It includes.

The surface plate 110 has an even and flat top surface 111, the stone panel is placed on the top surface 111. The surface of the surface plate 110 should have a hardness that is not damaged or damaged by friction with the stone panel or collision of the stone panel. Preferably, the surface plate 110 is made of marble with a uniform surface.

The first and second guide rails 121 and 122 may be installed on both sides of the upper surface 111 of the surface plate 110 so as to be spaced apart from each other by a distance larger than the width of the stone panel. The guide rails 121 and 122 support the first and second dial gauges 161 and 166 positioned on the stone panel, and at the same time, the guide rails 121 and 122 of the first and second dial gauges 161 and 166 It has a function of guiding the movement of the opposite direction (A; see Fig. 2), for example, LM guides widely used in machine tools may be used.

The first and second moving guides 131 and 132 are installed on the first and second guide rails 121 and 122, respectively, and the first and second dial gauges 161 and 166 are guide rails (see FIG. 121) allows the user to move in the front-rear direction (see FIG. 3) along the 122. These movement guides 131 and 132 may have various shapes according to the shape of each guide rail 121 and 122.

As shown in FIG. 1, when the guide rails 121 and 122 are LM guides, the first and second moving guides 131 and 132 may be in the form of bearings conforming to the LM guides. Although not shown, it may be in the form of a wheel that runs along the guide rail.

The slide bar 140 is installed to be spaced apart from the upper surface 111 of the surface plate 110 by a predetermined distance, and guides the left and right directions (B; FIG. 3) of the first and second dial gauges 161 and 166. do. One end of the slide bar 140 is coupled to the first movement guide 131 and the other end is coupled to the second movement guide 132. Therefore, the slide bar 140 may be moved in the front-rear direction A in a state parallel to the guide rails 121 and 122.

On the other hand, the configuration of the slide bar 140 according to the present invention is not limited to the above. That is, the slide bar 140 according to the present invention may be formed in the form of a bridge in which moving means such as moving guides are integrally coupled to both ends thereof.

The first and second position adjusting guides 151 and 156 support the first and second dial gauges 161 and 166, respectively, and are installed to allow the left and right directions B to be moved to the slide bar 140. do. Each positioning guide 161, 166 is composed of a support portion 162, 167, a moving portion 163, 168 and a fixing screw 154, 159. As shown in FIG. 1, the support part 152 of the first positioning guide 151 has a long groove 152a, and the support part 157 of the second positioning guide 156 also has a long groove (not shown). Have The connecting portions 163a and 168a of the dial gauges 161 and 166 are screwed into each of the long grooves 152a. Since each of the long grooves 152a is formed in the vertical direction in a predetermined size, the dial gauges 161 and 166 are adjusted by adjusting the installation positions of the respective dial gauges 161 and 166 in the long grooves 152a. The distance spaced apart from the upper surface 111 of the surface plate 110 can be adjusted.

And, as shown in Figure 1, the moving parts 153 and 158 are provided with insertion holes 153a and 158a, respectively. Each of the moving parts 153 and 158 is installed to allow the slide bar 140 to be moved to the left and right directions B (see FIG. 3) in a form in which the slide bar 140 is inserted into the insertion holes 153a and 158a. .

In addition, fixing screws 154 and 159 for fixing the moving parts 153 and 158 to the slide bar 140 are provided behind the moving parts 153 and 158, respectively. The fixing screws 154 and 159 penetrate the rear of each of the moving parts 153 and 158 to closely contact the slide bars 140 inserted into the insertion holes 153a and 158a.

Therefore, after moving each of the moving parts 153 and 158 along the slide bar 140 in the horizontal direction B, the positions of the moving parts 153 and 158 are adjusted using the fixing screws 154 and 159. Can be fixed

The first and second dial gauges 161 and 166 are installed in the first and second position adjustment guides 151 and 156, respectively. Each dial gauge 161, 166 is a conventional dial gauge, which protrudes below the bodies 163 and 168 on which the instructions 162 and 167 are installed and below the bodies 163 and 168. Spindles 164 and 169, respectively. Rear portions of the dial gauges 161 and 166 are provided with connecting portions 163a and 168a coupled to the positioning guides 151 and 156, respectively. Each of the connecting portions 163a and 168a is coupled to the supporting portions 152 and 157 of the positioning guides 151 and 156 through fastening means such as bolts and nuts. The dial gauges 161 and 166 may be adjusted in height from the upper surface 111 of the surface plate 110 according to the installation position in the long groove 152a.

In addition, the apparatus 100 for measuring thickness deviation of a stone panel according to an exemplary embodiment of the present invention includes a zero block 170 and a measurement block 180. The zero block 170 is for zeroing the measurement reference values of the respective dial gauges 161 and 166, and the measuring block 180 measures the angles of the stone panel and the dial gauges 161 and 166 when the thickness of the stone panel is measured. It is interposed between the spindles 164 and 169 to assist in measuring thickness deviation of the stone panel. At zero setting of each dial gauge 161, 166 the height of the lower end of the spindle 164, 169 is adjusted to be greater than the thickness of the stone panel to be measured. This is because when the stone panel is placed on the upper surface 111 of the surface plate 110 for thickness measurement, the front, rear, left and right movements of the dial gauges 161 and 166 are disturbed by the contact of the stone panels with the spindles 164 and 169. It is to avoid receiving.

On the other hand, the stone panel thickness deviation measuring apparatus 100 according to the present invention, the slide bar 140 may be provided in various numbers, such as two, three, the number of dial gauges supported by the slide bar 140 2 It is not limited to a dog, and may be provided in various numbers such as one, three, or four.

Hereinafter, the thickness deviation measuring operation and method of the stone panel thickness deviation measuring apparatus 100 according to the preferred embodiment of the present invention will be described with reference to FIGS. 4 and 5A to 5D.

First, before placing the stone panel on the upper surface 111 of the surface plate 110, the zero point of each dial gauge (161, 166) should be set. To this end, as shown in FIG. 3, the zero block 170 is set on the upper surface 111 of the surface plate 110 and the spindle 164 of the first dial gauge 161 is brought into contact with the zero block 170. The distance at this time is set as a reference value (S10). Similarly, the zero point is set in the same manner with respect to the second dial gauge 166.

When zero setting of each dial gauge 161 and 166 is completed, as shown in FIG. 5A, the stone panel 200 to measure the thickness is placed on the surface plate 110 (S20). Then, the measurement block 180 is placed on the first position P1 of the stone panel 200 and the slide bar 140 and the first position adjustment guide 151 are moved in the front-rear direction (A) and the left-right direction (B). By adjusting, the spindle 164 of the first dial gauge 161 contacts the measurement block 180 at the first position P1 (S30). In addition, by reading the guideline 162 at this time, the height at the first position P1 is measured (S40) to obtain a deviation value from the reference value, and the deviation value is added to or subtracted from the reference value to calculate the thickness deviation of the stone panel 200. (S50).

When the thickness deviation measurement of the first position P1 is completed as described above, as shown in FIG. 5B, the measurement block 180 is moved to the second position P2 of the stone panel 200, and then 2, the positioning guide 156 is moved in the left and right directions B so that the spindle 169 of the second dial gauge 166 is in contact with the measurement block 180 (S30). Then, the guide 169 at this time is read, the height at the second position P2 is measured (S40) to obtain a deviation value from the reference value, and the deviation value is added to or subtracted from the reference value to the thickness at the second position P2. The deviation is calculated (S50).

When the measurement of the thickness deviation of the stone panel 200 at the second position P2 is completed, as shown in FIG. 5C, the measurement block 180 is moved to the third position P3 of the stone panel 200. The first and second movement guides 131 and 132 and the slide bar 140 are moved in the front-rear direction A so that the spindle 164 of the first dial gauge 161 contacts the moved measurement block 180. (S30). Then, at this time, the guide 162 of the first dial gauge 161 is read to measure the height at the third position P3 (S40), and the thickness deviation of the stone panel 200 at the third position P3. Is calculated (S50).

When the thickness deviation measurement of the stone panel 200 at the third position P3 is completed, finally, as shown in FIG. 5D, the measurement block 180 is moved to the fourth position P4 of the stone panel 200. By calculating the thickness deviation of the stone panel 200 at the fourth position (P4) through the second dial gauge 166 in the same manner as described above (S50).

The first to fourth positions P1, P2, P3, and P4 of the stone panel 200 having the thickness deviation calculated above are arbitrarily selected positions, and anchor bolts 410 to the stone panel 200 are illustrated in FIG. 7. Are combined). If you want to measure the thickness deviation in more parts of the stone panel 200, each dial gauge 161 (using the slide bar 140 and the first and second position adjustment guides 151, 156) ( The thickness deviation at various positions of the stone panel 200 may be measured by moving 166 in the front, rear, left, and right directions (A) and (B).

On the other hand, the thickness deviation measuring apparatus of the stone panel according to the present invention can use a variety of other distance measuring apparatus without using a dial gauge as a measuring means. Another embodiment of such a stone panel thickness deviation measuring apparatus is shown in FIG. 6. In the thickness measuring apparatus 300 according to another exemplary embodiment of the present invention shown in FIG. 6, the configuration of the remaining parts except for the first and second digital distance measuring devices 361 and 366 is preferred. It is the same as the thickness measuring apparatus 100 by an example. That is, the stone panel thickness deviation measuring apparatus 300 according to another embodiment of the present invention includes a surface plate 310 on which the stone panel 200 is placed, and first and second plates installed on both sides of the surface plate 310 in parallel with each other. 2 guide rails 321 and 322, first and second movement guides 331 and 332 movably installed on the guide rails 321 and 322, and both ends of each of the movement guides 331 ( A slide bar 340 coupled to 332, first and second position adjustment guides 351 and 356 movably mounted to the slide bar 340, and respective position adjustment guides 351 and 356, respectively. And first and second digital ranging devices 361 and 366 coupled thereto.

The first and second digital distance measuring devices 361 and 366 may be ultrasonic range finders or laser beam range finders. The first and second digital distance measuring devices 361 and 366 are moved to various positions on the top of the stone panel 200 by the slide bar 340 and the first and second positioning guides 351 and 356. Can be. Therefore, similarly to the stone panel thickness deviation measuring apparatus 100 according to the preferred embodiment, it is possible to measure the thickness at any part of the stone panel 200. Moreover, these digital distance measuring devices 361 and 366 have an advantage that height measurement is possible without using the measuring block 180 (refer to FIG. 5D) required when using the dial gauge as a measuring means.

On the other hand, the stone panel thickness deviation measurement device 100, 300 as described above may be utilized for various purposes. For example, it is provided in a stone panel manufacturing plant or a company that is supplied with a stone panel can be easily used to inspect the stone panel 200, it can be provided in the construction site to improve the construction efficiency.

When used in the construction site, it is possible to increase the utilization efficiency of the "stone panel shared netting (application number: 20-2003-0017326, application date: June 03, 2003)" filed by the applicant. That is, as shown in Figure 7, between the hanger 420 and the stone panel 200 is installed on the outer wall (W) by measuring the thickness deviation of the portion where the anchor bolt 410 of the stone panel 200 is coupled The size of the distance adjusting member 430 may be determined in advance. In this way, the distance adjusting member 430 having a predetermined size may be coupled to a portion where each anchor bolt 410 is coupled during construction, thereby easily compensating the thickness deviation of the stone panel 200.

On the other hand, the thickness deviation measuring device of the stone panel according to the present invention, it can be used to measure the thickness deviation of various flat panels other than the stone panel.

According to the present invention described above, the thickness deviation of the manufactured stone panel can be measured accurately and easily. Therefore, it is possible to implement a thickness deviation measuring device that can easily perform the inspection of the stone panel.

In addition, according to the present invention, since the operator can perform the thickness correction of the stone panel before the operation of attaching the stone panel to the outer wall of the building, it is possible to obtain an additional effect of improving the construction work efficiency.

While the invention has been shown and described with respect to preferred embodiments for illustrating the principles of the invention, the invention is not limited to the construction and operation as shown and described. Rather, those skilled in the art will appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

1 is a schematic perspective view showing a stone panel thickness deviation measurement device for building exterior according to the present invention,

2 and 3 are a front view and a plan view of FIG. 1, respectively;

Figure 4 is a flow chart showing a thickness deviation measurement method of the stone panel according to a preferred embodiment of the present invention,

5a to 5d is a schematic perspective view for explaining the operation of the thickness deviation measuring device of the building exterior stone panel according to the present invention,

6 is a schematic perspective view showing a stone panel thickness deviation measuring apparatus according to another embodiment of the present invention, and

 7 is a view for explaining the application of the thickness deviation measurement device of the stone panel according to a preferred embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100; thickness deviation measuring device of the stone panel 110;

121,122; First and second guide rails 131 and 132; first and second moving guides

140; Slide bar 151,156; 1st and 2nd position adjustment guide

152,157; Support 153,158;

154,159; Set screw 161,166; 1st, 2nd dial gauge

162,167; Instructions 163,168;

164,169; Spindle 170; zero block

180; Measuring Block

Claims (5)

A plate with a pair of guide rails installed at both ends; A slide bar installed in a bridge shape to be movable along the guide rail; At least one distance measuring means installed on the slide bar so as to measure a height deviation with respect to an arbitrary position of the stone panel placed on the surface plate; . The method of claim 1, The distance measuring means is a thickness deviation measuring device for a building exterior stone panel, characterized in that any one selected from a dial gauge, an ultrasonic range finder and a laser beam range finder. The method of claim 2, The dial gauge is a device for measuring thickness deviation of a building exterior stone panel, characterized in that the reference point is set by the zero block set on the surface plate. In the method for measuring the relative thickness deviation of the plurality of bolt fastening position of the building exterior stone panel, Setting a zero point of the distance measuring means provided in a movable state above the surface plate on which the building exterior stone panel is placed; Setting a stone panel on the surface plate; Calculating height data for each point of the bolt fastening point of the stone panel through the distance measuring means and calculating height data for each point; Comparing the height data for each bolt fastening point of the stone panel to calculate the relative thickness deviation data; Method for measuring the thickness deviation of the building exterior stone panel comprising a. The method of claim 4, wherein The distance measuring means is a thickness deviation measuring method of the building exterior stone panel, characterized in that the zero point is set through a separately provided zero block.