KR101212644B1 - Machine of bridge type for processing stone panel - Google Patents

Abstract

The present invention relates to a bridge-type slab processing machine that can perform slab polishing, slab smoothing (so-called smoothing, doradak, etc., including all methods such as hammer type or roller type), or sawing. The transfer table 60 is disposed between the two left vertical columns LP; LP1 and LP2 and the two right vertical columns RP; RP1 and RP2, and the first and second left vertical columns LP1 and LP2. Both ends of the bridge frame BF are seated on the left beam LF that connects the first beam LF and the right beam RF that connects the first and second right vertical columns RP1 and RP2, and are mounted to the bridge frame BF. The processing unit 50 is disposed above the transfer table 60, the front beam FB1 is connected to the upper end of the first left vertical column LP1 and the upper end of the first right vertical column RP1, and the front beam The first and second thickness measuring devices 70 and 75 are disposed at FB1 so that the first and second thickness measuring devices 70 and 75 are transferred. The thickness t1 of the left end and the thickness t2 of the right end of the slab W supplied to the table 60 are respectively measured, and the measurement signals of the first and second thickness measuring devices 70 and 75 are It is input to the calculating device 80, by calculating the two measurement signals in the calculating device 80 to control the operation of the horizontal adjusting device 90, the transfer table 60 by the horizontal adjusting device 90 is a slab Left and right inclination is adjusted by the left and right thickness difference of the ash (W).

Description

Bridge type slab processing machine {MACHINE OF BRIDGE TYPE FOR PROCESSING STONE PANEL}

The present invention relates to a bridge-type slab processing machine that can perform slab polishing, slab smoothing (so-called smoothing, doradak, etc., including all methods such as hammer type or roller type), or sawing. More specifically, it relates to a bridge-type slab processing machine that can adjust the left and right height of the transfer table to place the slab when processing the slab.

1 and 2, the conventional bridge-type slab processing machine is disposed between the left vertical column 11 and the right vertical column 12, the transfer table 13 is placed on the slab, the left vertical column 11 Both ends of the bridge frame 14 are connected to the upper end of the vertical column and the right side of the right vertical column 12, the bridge frame 14 is disposed on the upper portion of the transfer table 13, the processing unit 15 to the bridge frame 14 ), The processing unit 15 is to process the slab (W) placed on the transfer table (13).

However, in the conventional bridge-type slab processing machine as described above, since the left and right frames 13a and 13b of the transfer table 13 are fixed to the left and right vertical columns 11 and 12, as shown in FIG. When the left side thickness t1 and the right side thickness t2 of the slab W placed in 13) are different from each other, mechanical vibration and noise are severe, so that a breakdown occurs frequently, and the thinner side is poor in processing and relatively thin. The thicker side caused a serious problem of the wear of the processing unit.

Therefore, an object of the present invention is to adjust the left and right height of the transfer table for placing the slab when processing the slab, the upper surface of the slab can always be in contact with the processing unit vertically, thereby improving the work quality and productivity It is to provide a bridge-type slab processing machine that can be.

One example of the bridge-type slab processing machine according to the present invention for achieving the above object is a transfer table disposed between two left vertical columns and two right vertical columns, connecting the first and second left vertical columns Both ends of the bridge frame are seated on the right beam connecting the left beam and the first and second right vertical pillars, and a processing unit mounted to the bridge frame is disposed on the upper portion of the transfer table, and the top and the first of the first left vertical pillars 1 The front beam is connected to the upper end of the right vertical column, and the first and second thickness measuring devices are arranged on the front beam, so that the thickness and the right side of the left end of the slab to which the first and second thickness measuring devices are supplied to the transfer table. The thicknesses of the stages are respectively measured, and the measurement signals of the first and second thickness measuring devices are input to the calculating device, and the two measuring signals are calculated by the calculating device. By controlling the copper, it characterized in that the left and right tilt adjustment by Tea transfer table the left and right thick slab material by the leveling device.

Another example of the bridge-type slab processing machine according to the present invention is a transfer table disposed between two left vertical pillars and two right vertical pillars, and a left beam connecting the first and second left vertical pillars and the first and the first 2 Wheels mounted on both ends of the front bridge frame and the rear bridge frame on the right beam connecting the right vertical column, rails are mounted in the longitudinal direction of the front bridge frame and the rear bridge frame, and the rails are mounted on both ends of the movable frame. This arrangement allows the wheel to be moved along the rail by the drive means, and a transfer table is disposed between the two left vertical pillars and the two right vertical pillars, and the left beam connects the first and second left vertical pillars. Both ends of the front bridge frame and the rear bridge frame are seated on the right beam connecting the first and second right vertical pillars, and the front bridge The rail is mounted in the longitudinal direction of the frame and the rear bridge frame, and wheels mounted at both ends of the movable frame are disposed on the rail, so that the wheel can be moved along the rail by driving means, and a plurality of processing units are provided on the movable frame. Is mounted, the processing unit is arranged on the upper part of the transfer table, the front beam is connected to the upper end of the first left vertical column and the upper end of the first right vertical column, and the first and second thickness measuring devices are connected to the front beam. Disposed, the first and second thickness measuring devices respectively measure the thickness of the left end and the right end of the slab supplied to the transfer table, and the measurement signals of the first and second thickness measuring devices are input to the computing device; , The two measuring signals are calculated by the calculating device to control the operation of the leveling device. The apostle is characterized by being controlled.

Another example of a bridge-type slab processing machine according to the present invention is a transfer table disposed between two left vertical columns and two right vertical columns, a left support frame is disposed between two left vertical columns, and two right The right support frame is disposed between the vertical pillars, both ends of the bridge frame are seated on the left support frame and the right support frame, and a processing unit mounted on the bridge frame is disposed on the upper portion of the transfer table, and the top of the first left vertical pillar is And the front beam is connected to the upper end of the first right vertical column, and the first and second thickness measuring devices are arranged on the front beam, so that the thickness of the left end of the slab to which the first and second thickness measuring devices are supplied to the transfer table. Measure the thicknesses of the and right ends, respectively, and the measurement signals of the first and second thickness measuring devices are input to the computing device, By computing the signal thereby to control the operation of the leveling device, it is characterized in that the right and left inclination adjustable by primary transfer table the left and right thick slab material by the leveling device.

The processing unit is characterized in that any one of the saw for cutting, single head grinder, double head grinder, slab smoothing.

The transfer table may be any one of a conveyor belt device and a roller table.

In addition, the transfer table has a pin and a second bracket and a pin, in which the conveyor belt is disposed between the left frame and the right frame so that the conveyor belt is supported by the left frame and the right frame, and the first bracket of the left frame is mounted on the left vertical column. It is coupled by, the right frame is connected to the leveling device by the third bracket, characterized in that the arrangement height of the right frame is adjusted by the leveling device.

Alternatively, the transfer table has a lower beam connected to the bottom of the left vertical pillar and the right vertical pillar, and a fourth bracket mounted on the lower beam and a fifth bracket mounted on the lower surface of the left frame are joined by pins. , The right frame is coupled to the horizontal adjustment device mounted on the lower beam, characterized in that the height of the arrangement of the right frame is adjusted by the horizontal adjustment device.

The first thickness measuring device includes a housing mounted to a slider that can move along a front beam, an air cylinder disposed inside the housing, a vertical rod connected to a connecting rod of the air cylinder, and a vertical rod. The roller is mounted to the lower end of the, characterized in that consisting of an encoder disposed inside the housing for measuring the lifting height of the vertical rod.

In another alternative, the first thickness measuring device is fitted with a vertical rod in a box-shaped housing so that the vertical rod can be lifted and lowered, a roller is mounted at the bottom of the vertical rod, and a spring is disposed inside the housing so that the top of the spring is vertical. It is connected to the upper mounting part of the rod, the lower end of the spring is mounted on the lower surface of the housing, and an encoder placed inside the housing measures the rising height of the vertical rod, and a stopper is mounted inside the housing, perpendicular to the stopper. The upper mounting portion of the rod is locked, the fall of the vertical rod is limited by the stopper.

The first thickness measuring device is equipped with a horizontal pedestal at the bottom of the movable frame of the elevating device, the slider is disposed at one end of the horizontal pedestal so that the height of the housing is determined by the elevating device mounted in the middle of the front beam The housing is mounted on the slider.

The lifting device is equipped with a fixed bearing support to the front beam, a screw shaft is rotatably mounted to the fixed bearing support, the output gear of the reducer connected to the motor is coupled to the screw shaft, the movable frame is mounted to the reducer When the motor is driven, the motor and the reducer are lowered along the screw shaft, so that the movable frame mounted on the reducer is lowered.

Alternatively, the elevating device is mounted with a connecting rod of a cylinder on top of a fixed frame mounted to the front beam, and a movable frame is mounted on the cylinder, so that when the connecting rod is drawn into the cylinder, the cylinder is lowered relatively. It is characterized in that the movable frame mounted on the cylinder is lowered.

The second thickness measuring device is configured in the same manner as the first thickness measuring device.

The computing device compares the output signal of the first thickness measuring device with the output signal of the second thickness measuring device, and if the measured value of the first thickness measuring device is larger than the measured value of the second thickness measuring device (ie, the left side of the slab material). If the end is thicker than the right end), the negative output terminal is output to the second magnetic contactor for driving the geared motor of the leveling device, and the geared motor of the leveling device is reversed, so that the right frame of the transfer table If the placement height is lowered, the upper surface of the slab is in contact with the processing unit perpendicularly, and the measured value of the first thickness measuring device is smaller than the measured value of the second thickness measuring device (that is, the right end of the slab W). Thicker than the left end), the positive output terminal is output to the first magnetic contactor for driving the geared motor of the leveling device, and the geared motor of the leveling device is rotated forward, The right frame of the song table is arranged higher than the height of the left side frame, and the slab material upper surface being in contact perpendicularly with the machining unit.

The horizontal adjusting device is a worm gear mounted on the output shaft of the geared motor is disposed inside the gearbox, the worm gear is interlocked with the worm, the lifting shaft is fitted to the hollow portion of the worm, the spiral portion of the lifting shaft and the circumference of the hollow portion of the worm A spiral formed in the shaft is engaged, an upper end of the lifting shaft is connected by a sixth bracket and a pin, a sixth bracket is connected to the right frame of the transfer table, and a seventh bracket is mounted on the lower surface of the gearbox, and a seventh bracket It is characterized in that coupled by the eighth bracket and the pin mounted on the upper surface of the support pillar.

Gearboxes are respectively disposed at both ends of the output shaft, and the power of the output shaft is simultaneously transmitted to two gearboxes.

Alternatively, the leveling device has one end of the tenth bracket in which the eighth bracket of the support pillar and the ninth bracket mounted on the bottom of the cylinder are connected by pins, and the connecting rod of the cylinder is mounted on the right frame of the transfer table. It is characterized in that connected to.

In another alternative, the leveling device is rotatably mounted to the output shaft of the geared motor on an eleventh bracket mounted to the lower beam, the eccentric cam is fitted to the output shaft, and the eccentric cam moves the right frame of the transfer table. It is characterized by being supported.

The drive means is mounted on the reducer motor mounted to the movable frame, the output shaft fitted to the gearbox of the reducer motor, the pinion mounted to both ends of the output shaft, the front bridge frame and the rear bridge frame, respectively, It is characterized by consisting of a rack gear to be engaged.

The driving means is mounted on the left beam, the first cylinder and the second cylinder, respectively, characterized in that the connecting rod of the first cylinder is connected to the housing of the wheel, the connecting rod of the second cylinder is characterized in that connected to the housing of the wheel .

Wheels are mounted at lower ends of the left support frame and the right support frame, respectively, and the wheels are moved along the rails.

Thereby, the bridge-type slab processing machine according to the present invention can adjust the left and right height of the transfer table on which the slab is placed when processing the slab, so that the upper surface of the slab can always be perpendicular to the processing unit. In addition, work quality and productivity can be increased, and the wear of the processing unit can be reduced.

1 is a side view showing a conventional bridge-type slab processing machine
Figure 2 is a cross-sectional view taken along the line AA of Figure 1 showing a conventional bridge-type slab processing machine
Figure 3 is a perspective view schematically showing a bridge-type slab processing machine according to a first embodiment of the present invention
Figure 4 is a block diagram showing the relationship between the first and second thickness measuring device, arithmetic device, leveling device
Figure 5 is a cross-sectional view taken along line AA of Figure 3 showing an example in which the transfer table is adjusted left and right by the horizontal adjustment device.
Figure 6 is a front view showing another example in which the transfer table is adjusted left and right inclination by the horizontal adjustment device
7 is a side view schematically showing another example of the first thickness measuring device;
8 is a front view showing the mounting structure of the first and second thickness measuring devices;
9 is a cross-sectional view taken along line aa of FIG. 8 showing a mounting structure of the first thickness measuring device.
10 is a cross-sectional view showing another mounting structure of the first thickness measuring device;
Figure 11 is a side view schematically showing a bridge-type slab processing machine according to a first embodiment of the present invention
12 is a cross-sectional view taken along the line BB of FIG. 11 showing a horizontal adjustment device
13 is a front view showing another example of the horizontal adjustment device
14 is a plan view schematically showing a bridge-type slab processing machine according to a second embodiment of the present invention
15 is a side view showing a bridge-type slab processing machine according to a second embodiment of the present invention.
16 is a side view showing another example of a drive device;
17 is a plan view schematically showing a bridge-type slab processing machine according to a third embodiment of the present invention
18 is a plan view taken along line CC of FIG. 17 schematically showing a bridge-type slab processing machine according to a third embodiment of the present invention.
19 is a plan view schematically showing a bridge-type slab processing machine according to a fourth embodiment of the present invention
20 is a cross-sectional view taken along line DD of FIG. 19 schematically showing a bridge-type slab processing machine according to a fourth embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. When the embodiments of the present invention are described with reference to the drawings, the same reference numerals will be used for the same elements for convenience of description.

3 and 4, the bridge-type slab processing machine according to the first embodiment of the present invention between two left vertical columns (LP; LP1, LP2) and two right vertical columns (RP; RP1, RP2) The transfer table 60 is disposed at the right side, and the right beam connecting the first and second left vertical pillars LP1 and LP2 to the left beam LF and the first and second right vertical pillars RP1 and RP2. Both ends of the bridge frame BF are seated on the RF, and the processing unit 50 mounted on the bridge frame BF is disposed above the transfer table 60, and the upper end of the first left vertical column LP1 is disposed. And the front beam FB1 is connected to the upper end of the first right vertical column RP1, and the first and second thickness measuring devices 70 and 75 are disposed on the front beam FB1, and thus the first and second thicknesses are arranged. The measuring device 70, 75 measures the thickness t1 of the left end and the thickness t2 of the right end of the slab W which is supplied to the transfer table 60, respectively. (70, The measuring signal of 75 is input to the calculating device 80, and the two measuring signals are calculated by the calculating device 80 to control the operation of the horizontal adjusting device 90, thereby being transferred by the adjusting device 90. The left and right inclination is adjusted by the table 60 by the left and right thickness difference of the slab W. As shown in FIG.

In the bridge-type slab processing machine according to the first embodiment of the present invention configured as described above, when the slab W is supplied to the transfer table 60, the first and second thickness measuring devices 70 and 75 are slabs. When the thicknesses of the left and right ends of the ashes W are respectively measured and the output signals of the first and second thickness measuring devices 70 and 75 are input to the calculating device 80, the calculating device 80 receives the first thickness. When the output signal of the thickness measuring device 70 and the output signal of the second thickness measuring device 75 are compared, and the measured value of the first thickness measuring device 70 is larger than the measured value of the second thickness measuring device 75. (That is, when the left end of the slab W is thicker than the right end), the operation of the horizontal adjusting device 90 is controlled to adjust the height of the right frame 63 of the transfer table 60 to the left frame 62. Lower than the height of the arrangement, the upper surface of the slab (W) is in contact with the processing unit 50 vertically. When the measured value of the first thickness measuring device 70 is smaller than the measured value of the second thickness measuring device 75 (that is, when the right end of the slab W is thicker than the left end), the horizontal adjusting device By controlling the operation of the 90, the height of the placement of the right frame 63 of the transfer table 60 is higher than the height of the placement of the left frame 62, whereby the upper surface of the slab W is processed. Make sure it is perpendicular to

The processing unit 50 is introduced in the "Saw blade vertical adjustment device of the stone cutting machine" of the Republic of Korea Patent No. 10-0983863 (registered September 16, 2010) of the applicant, the detailed description thereof will be omitted here. . However, the processing unit 50 is a cutting saw for cutting introduced in the Republic of Korea Patent No. 10-0983863 (name of the invention: the saw blade vertical adjustment device of the stone cutting machine), the single head grinder shown in Figure 3, the double head grinder, It may be any one of slab smoothing (so-called smoothing, dolaking, etc., including all manners such as hammer type or roller type).

The conveying table 60 is shown with a conveyor belt device in FIG. 3, but the present invention is not limited thereto and also includes a roller table.

Referring to FIG. 5, the transfer table 60 has a conveyor belt 61 supported by a left frame 62 and a right frame 63, and the first bracket 64 of the left frame 62 is left vertical. It is coupled by the second bracket 65 and the pin 66 mounted on the pillar LP, the right frame 63 is connected to the leveling device 90 by the third bracket 67, the right frame ( The placement height h1 of 123 is adjusted by the horizontal adjusting device 90.

Referring to FIG. 6, in another alternative, the transfer table 60 is connected to the lower beam FM at the lower ends of the left vertical pillar LP and the right vertical pillar RP, and mounted to the lower beam FM. The fourth bracket 601 and the fifth bracket 602 mounted on the lower surface of the left frame 62 are coupled by the pins 603, and the right frame 63 is mounted on the lower beam FM. In combination with the device 90, the placement height h2 of the right frame 123 is adjusted by the leveling device 90.

Referring again to FIGS. 3 and 4, the first thickness measuring device 70 includes a housing 702 mounted to a slider 701 that can be moved along the front beam FB1, and an interior of the housing 702. An air cylinder 703 disposed on the vertical rod, a vertical rod 706 connected to the connecting rod 704 of the air cylinder 703 by a connecting member 705, and a roller mounted at a lower end of the vertical rod 706 ( 707 and an encoder 708 disposed inside the housing 702 to measure the lifting height of the vertical rod 706.

As a result, when the slab W is supplied to the transfer table 60, the first thickness measuring device 70 causes the vertical rod 706 to rise while the roller 707 rises above the slab W. FIG. The encoder 708 measures the rising height of the vertical rod 706 to provide a measurement signal to the computing device 80, and the connecting rod 704 and the connecting member 705 of the cylinder 703 are vertical rods ( 706 is held to prevent the shaking of the vertical rod 706 when the vertical rod 706 is raised and lowered.

The second thickness measuring device 75 is configured in the same manner as the first thickness measuring device 70.

Referring to FIG. 7, in another alternative, the first thickness measuring device 70 has a vertical rod 712 fitted to the box-shaped housing 711 so as to be lifted and lowered, and a roller at the bottom of the vertical rod 712. 713 is mounted, and a spring 714 is disposed inside the housing 711, such that an upper end of the spring 714 is connected to an upper mounting part 715 of the vertical rod 712, and a lower end of the spring 714. The encoder 716 mounted on the lower surface of the housing 711 and disposed inside the housing 711 measures the rising height of the vertical rod 712 and the stopper 717 inside the housing 711. Is attached, and the top mounting portion 715 of the vertical rod 712 is caught by the stopper 717, thereby lowering the vertical rod 712 by the stopper 717.

8 and 9, the first thickness measuring device 70 is also arranged such that the height of the housing 711 is determined by the elevating device 720 mounted in the middle of the front beam FB1. A horizontal pedestal 726 is mounted at the bottom of the movable frame 725 of the elevating device 720, a slider 727 is disposed at one end of the horizontal pedestal 726, and a housing 711 is mounted to the slider 727. do.

As a result, when the slab W begins to be supplied to the transfer table 60, the housing 711 is lowered by the elevating device 720, and the slab W is transferred to the transfer table 60. When supplied, the vertical rod 712 is raised as the roller 713 is in contact with the upper surface of the slab W, at this time, the encoder 716 measures the rising height of the vertical rod 712. .

The lifting device 720 has a fixed bearing means 721 is mounted to the front beam (FB1), the screw shaft 722 is rotatably mounted to the fixed bearing means 721, the motor 723 and When the output gear (not shown) of the connected reducer 724 is coupled with the screw shaft 722, and the reducer 724 is equipped with a movable frame 725, and the motor 723 is driven, As the reducer 724 is lowered along the screw shaft 722, the movable frame 725 mounted to the reducer 724 is lowered.

The second thickness measuring apparatus 75 is configured in the same manner as the first thickness measuring apparatus 70 and is disposed at the other end of the horizontal pedestal 726 of the elevating apparatus 720.

Alternatively, referring to FIG. 10, the elevating device 720 is mounted with a connecting rod 733 of the cylinder 732 on the top of the fixed frame 731 mounted to the front beam FB1, and the cylinder ( When the movable frame 734 is mounted on the 732 and the connecting rod 733 is led into the cylinder 732, the cylinder 732 is relatively lowered, whereby the movable frame 734 mounted to the cylinder 732 is lowered. do.

Referring to FIGS. 3 and 4 again, the computing device 80 compares the output signal of the first thickness measuring device 70 with the output signal of the second thickness measuring device 75 to determine the first thickness measuring device ( If the measured value of 70 is greater than the measured value of the second thickness measuring device 75 (that is, the left end of the slab W is thicker than the right end), the horizontal adjusting device 90 at the negative output terminal 81 Is outputted to the second magnetic contactor MC2 for driving the geared motor GM of the motor), and the geared motor GM of the horizontal adjusting device 90 is rotated in reverse to thereby rotate the right frame 63 of the transfer table 60. Since the arrangement height is lower than that of the left frame 62, the upper surface of the slab W comes into contact with the processing unit 50 perpendicularly, and the measured value of the first thickness measuring device 70 is determined by the second thickness measuring device ( Less than 75) (i.e., the right end of the slab W is thicker than the left end), the geared motor GM of the leveling device 90 at the positive output terminal 82 Outputted to the first magnetic contactor MC1 for driving, the geared motor GM of the horizontal adjusting device 90 is rotated forward, so that the right frame 63 of the transfer table 60 is arranged more than the left frame 62. As the height is increased, the upper surface of the slab W comes into contact with the processing unit 50 perpendicularly.

In addition, the arithmetic unit 80 is provided with a display means (not shown), and the difference between the measured value of the first thickness measuring device 70 and the measured value of the second thickness measuring device 75 is provided in the display means. Is displayed.

11 and 12, the horizontal adjusting device 90 is a worm gear 902 mounted on the output shaft 901 of the geared motor (GM) is disposed in the gearbox 903, the worm gear 902 ) Is linked with the worm 904, the lifting shaft 905 is fitted to the hollow portion of the worm 904, the spiral portion 906 of the lifting shaft 905 and the spiral portion formed around the hollow portion of the worm 904 907 is engaged, the upper end of the lifting shaft 905 is connected by the sixth bracket 67 and the pin 908, the sixth bracket 67 to the right frame 63 of the transfer table 60 The seventh bracket 909 is mounted on the bottom surface of the gearbox 903, and the eighth bracket 911 and the pin 912 are mounted on the top surface of the support pillar 910. Combined by).

Gearboxes 903 and 915 are disposed at both ends of the output shaft 901 so that power of the output shaft 901 is simultaneously transmitted to the two gearboxes 903 and 915.

The configuration of the gearbox 915 is the same as the gearbox 903.

As a result, when the power of the output shaft 901 is transmitted to the worm 904 through the worm gear 902, the horizontal adjusting device 90 raises or lowers the lifting shaft 905 by the rotation of the worm 904. Descends. At this time, the upper end of the lifting shaft 905 is coupled to the sixth bracket 67 by the pin 908, so that the lifting shaft 905 does not rotate with the worm 904 to rise or fall. In addition, when the lifting shaft 906 is raised, the sixth bracket 67 is raised, and the right frame 63 of the transfer table 60 coupled to the sixth bracket 67 is raised. Then, the lifting shaft 905 is coupled by the sixth bracket 67 and the pin 908, the seventh bracket 909 of the gear box 903 and the eighth bracket 911 of the support pillar 910 is Coupled by the pin 912, it is possible to respond to the angular change of the lifting shaft 905 occurs when the lifting shaft 905 is raised or lowered.

Referring to FIG. 13, in another alternative, the leveling device 90 includes an eighth bracket 911 of the support pillar 910 and a ninth bracket 921 mounted at the bottom of the cylinder 920. ), And a connecting rod 923 of the cylinder 920 is connected to one end of the tenth bracket 924 mounted to the right frame 63 of the transfer table 60.

Thus, when the connecting rod 923 is pulled out of the cylinder 920, the right frame 63 of the transfer table 60 is raised, and when the connecting rod 923 is drawn into the cylinder 920, the transfer table ( The right frame 63 of 60 is lowered.

Referring again to FIG. 6, in another alternative, the leveling device 90 rotates an output shaft 931 of a geared motor (not shown) in an eleventh bracket 930 mounted to the lower beam FM. Eccentrically mounted, an eccentric cam 935 is fitted to the output shaft 931, and the eccentric cam 935 supports the right frame 63 of the transfer table 60.

As a result, when the long shaft portion of the eccentric cam 935 supports the right frame 63 by the rotation of the output shaft 931, the arrangement height h2 of the right frame 63 becomes high, and the eccentric cam 935 When the short axis portion opposite to the long axis portion of the) supports the right frame 63, the arrangement height of the right frame 63 is lowered.

14 and 15, the bridge-type slab processing machine according to a second embodiment of the present invention between two left vertical columns (LP; LP1, LP2) and two right vertical columns (RP; RP1, RP2) The transfer table 60 is disposed at the right side, and the right beam connecting the first and second left vertical pillars LP1 and LP2 to the left beam LF and the first and second right vertical pillars RP1 and RP2. Both ends of the front bridge frame bf1 and the rear bridge frame bf2 are seated on the RF, and the rails r1 and r2 are mounted in the longitudinal direction of the front bridge frame bf1 and the rear bridge frame bf2, Wheels wh1 and wh2 mounted at both ends of the movable frame DF are arranged on the rails r1 and r2 so that the wheels wh1 and wh2 are driven along the rails r1 and r2 by the driving means 100. It is the same as the bridge-type slab processor according to the first embodiment of the present invention, except that it can be moved.

4, 14 and 15 again, that is, the bridge-type slab processing machine according to the second embodiment of the present invention has two left vertical columns LP; LP1 and LP2 and two right vertical columns RP. The transfer table 60 is disposed between RP1 and RP2, the left beam LF connecting the first and second left vertical columns LP1 and LP2 and the first and second right vertical columns RP1 and RP2; ), Both ends of the front bridge frame bf1 and the rear bridge frame bf2 are seated on the right beam RF connecting the rails, and the rails r1, in the longitudinal direction of the front bridge frame bf1 and the rear bridge frame bf2. r2 is mounted, and wheels wh1 and wh2 mounted on both ends of the movable frame DF are disposed on the rails r1 and r2, and the wheels wh1 and wh2 are moved by the driving means 100 to the rails ( It can be moved along the r1, r2, the transfer table 60 is disposed between the two left vertical columns (LP; LP1, LP2) and two right vertical columns (RP; RP1, RP2), the first and 2nd left The front bridge frame bf1 and the rear bridge frame bf2 are connected to the left beam LF connecting the vertical columns LP1 and LP2 and the right beam RF connecting the first and second right vertical columns RP1 and RP2. ) Both ends are mounted, the rails r1 and r2 are mounted in the longitudinal direction of the front bridge frame bf1 and the rear bridge frame bf2, and the rails r1 and r2 are provided at both ends of the movable frame DF. The mounted wheels wh1 and wh2 are disposed, and the wheels wh1 and wh2 can be moved along the rails r1 and r2 by the driving means 100, and a plurality of processing units ( 50; 50a, 50b, 50c are mounted so that the processing units 50; 50a, 50b, 50c are disposed on the upper portion of the transfer table 60, and the upper end and the first right side of the first left vertical column LP1. The front beam FB1 is connected to the upper end of the vertical column RP1, and the first and second thickness measuring devices 70 and 75 are disposed on the front beam FB1, so that the first and second thickness measuring devices 70 are disposed. , 75) The thickness t1 of the left end and the thickness t2 of the right end of the slab W supplied to the song table 60 are measured, respectively, and the measurement signals of the first and second thickness measuring devices 70 and 75 are measured. Is input to the calculating device 80, the two measuring signals are calculated in the calculating device 80 to control the operation of the horizontal adjusting device 90, the transfer table 60 by the horizontal adjusting device 90 The left and right inclination is adjusted by the left and right thickness difference of the slab W.

Referring to FIGS. 14 and 15, the drive means 100 includes an reducer motor 101 mounted on a movable frame DF and an output shaft 103 fitted to a gearbox 102 of the reducer motor 101. And pinions 104 and 105 mounted on both ends of the output shaft 103 and mounted on the front bridge frame bf1 and the rear bridge frame bf2, respectively, and mesh with the pinions 104 and 105, respectively. Size words 106 and 107.

As a result, when the output shaft 103 is rotated clockwise by the reducer motor 101, the driving means 100 is equipped with pinions 104 and 105 mounted at both ends of the output shaft 103. By moving to the right along the gears 106 and 107, the processing unit 50 mounted to the movable frame DF is moved to the right, and the output shaft 103 is rotated counterclockwise by the reducer motor 101. Then, the pinions 104 and 105 mounted at both ends of the output shaft 103 are moved to the left along the rack gears 106 and 107 so that the machining unit 50 mounted to the movable frame (DF) is left. Is moved to.

Referring to FIG. 16, in another alternative, the driving means 100 is equipped with a first cylinder 111 and a second cylinder 115, respectively, on the left beam LF, and connecting rods of the first cylinder 111. 112 is connected to the housing 113 of the wheel wh1, and the connecting rod 9316 of the second cylinder 115 is connected to the housing 117 of the wheel wh2.

As a result, when the connecting rod 112 of the first cylinder 111 and the connecting rod 116 of the second cylinder 115 are pulled out, the connecting rods 112 and 116 push the wheel housings 113 and 115. When the wheel of the wheel housing is moved to the right along the rails r1 and r2, the movable frame DF is moved to the right, and the connecting rod 112 of the first cylinder 111 and the second cylinder 115 are moved. When the connecting rod 116 is retracted, the connecting rods 112 and 116 pull the wheel housings 113 and 115 so that the wheels of the wheel housing are moved to the left along the rails r1 and r2, whereby the movable frame DF ) Is moved to the right.

Referring to FIGS. 17 and 18, the bridge type slab processing machine according to the third embodiment of the present invention has a bridge frame BF having a left support frame LSF and a right support frame separately from the vertical columns LP and RP. It is the same as the bridge-type slab processor according to the first embodiment of the present invention, except that it is supported by RSF).

That is, in the bridge-type slab processing machine according to the third embodiment of the present invention, the transfer table 60 is disposed between two left vertical columns LP; LP1 and LP2 and two right vertical columns RP; RP1 and RP2. The left support frame LSF is disposed between two left vertical columns LP; LP1 and LP2, and the right support frame RSF is disposed between two right vertical columns RP; RP1 and RP2. Both ends of the bridge frame BF are seated on the left support frame LSF and the right support frame RSF, and the processing unit 50 mounted to the bridge frame BF is disposed above the transfer table 60. The front beam FB1 is connected to the upper end of the first left vertical column LP1 and the upper end of the first right vertical column RP1, and the first and second thickness measuring devices 70 and 75 are connected to the front beam FB1. ) And the thickness of the left end and the right end of the slab to which the first and second thickness measuring devices 70, 75 are supplied to the transfer table 60. Measuring the respective thicknesses, and measuring signals of the first and second thickness measuring devices 70 and 75 are input to the calculating device 80 (see FIG. 4), and the measuring device 80 calculates two measuring signals to By controlling the operation of the adjusting device 90, the horizontal adjustment device 90 adjusts the left and right inclination degree by the left and right thickness difference of the slab material.

19 and 20, the bridge type slab processing machine according to the fourth embodiment of the present invention is equipped with wheels 111 and 112 at the lower ends of the left support frame LSF and the right support frame RSF, respectively. In addition, except that the wheels (111, 112) are moved along the rails (113, 114) is the same as the bridge-type slab processing machine according to a third embodiment of the present invention.

LP: left vertical column RP: right vertical column
50: processing unit 60: transfer table
BF: right beam 70, 75: first and second thickness measuring devices
80: computing device 90: horizontal adjusting device

Claims (21)

The transfer table 60 is disposed between the two left vertical columns LP; LP1 and LP2 and the two right vertical columns RP; RP1 and RP2, and the first and second left vertical columns LP1 and LP2 are disposed. Both ends of the bridge frame BF are seated on the right beam RF connecting the left beam LF and the first and second right vertical pillars RP1 and RP2 to be connected, and a line is mounted on the bridge frame BF. One of the processing units 50 selected from the sawing work saw, the single head grinder, the double head grinder, and the slab smoothing machine is disposed on the upper portion of the transfer table 60, and the upper end of the first left vertical column LP1 The front beam FB1 is connected to the upper end of the first right vertical column RP1, and the first and second thickness measuring devices 70 and 75 are disposed on the front beam FB1 to measure the first and second thicknesses. The apparatus 70, 75 measures the thickness t1 of the left end and the thickness t2 of the right end of the slab W which is supplied to the transfer table 60, respectively, and measures the first and second thickness sides. The measurement signals of the stationary devices 70 and 75 are input to the operation device 80, and the operation device 80 controls the operation of the horizontal control device 90 by calculating two measurement signals. 90) bridge type slab processing machine characterized in that the transfer table 60 is adjusted to the left and right inclination by the left and right thickness difference of the slab (W).
The transfer table 60 is disposed between the two left vertical columns LP; LP1 and LP2 and the two right vertical columns RP; RP1 and RP2, and the first and second left vertical columns LP1 and LP2 are disposed. Both ends of the front bridge frame bf1 and the rear bridge frame bf2 are seated on the right beam RF that connects the left beam LF and the first and second right vertical pillars RP1 and RP2 to connect. The rails r1 and r2 are mounted in the longitudinal direction of the bridge frame bf1 and the rear bridge frame bf2, and the wheels wh1 and wh2 attached to both ends of the movable frame DF on the rails r1 and r2. This arrangement allows the wheels wh1 and wh2 to be moved along the rails r1 and r2 by the driving means 100, and the two left vertical columns LP; LP1 and LP2 and two right vertical columns ( RP; The transfer table 60 is disposed between RP1 and RP2, and the left beam LF connecting the first and second left vertical pillars LP1 and the first and second right vertical pillars RP1, Right connecting RP2) Both ends of the front bridge frame bf1 and the rear bridge frame bf2 are seated on the beam RF, and the rails r1 and r2 are mounted in the longitudinal direction of the front bridge frame bf1 and the rear bridge frame bf2. The wheels wh1 and wh2 mounted at both ends of the movable frame DF are disposed on the rails r1 and r2, and the wheels wh1 and wh2 are connected to the rails r1 and r2 by the driving means 100. It can be moved along, the processing unit (50; 50a, 50b, 50c) selected from the cutting line saw, guillotine grinder, twin head grinder, slab smoothing is mounted on the movable frame (DF), The processing units 50; 50a, 50b, 50c are disposed on the upper portion of the transfer table 60, and the front beams FB1 are disposed on an upper end of the first left vertical pillar LP1 and an upper end of the first right vertical pillar RP1. ) And the first and second thickness measuring devices 70 and 75 are arranged on the front beam FB1, so that the first and second thickness measuring devices 70 and 75 are transferred to the transfer table 60. The thickness t1 of the left end and the thickness t2 of the right end of the supplied slab W are measured, respectively, and the measurement signals of the first and second thickness measuring devices 70 and 75 are calculated. It is input to the, and by calculating the two measurement signals in the calculating device 80 to control the operation of the horizontal adjusting device 90, the transfer table 60 by the horizontal adjusting device 90 of the slab (W) Bridge type slab processing machine characterized in that the left and right inclination is adjusted by the left and right thickness difference.
The transfer table 60 is disposed between the two left vertical columns LP; LP1 and LP2 and the two right vertical columns RP; RP1 and RP2, and between the two left vertical columns LP; LP1 and LP2. The left support frame LSF is disposed, the right support frame RSF is disposed between the two right vertical columns RP; RP1, RP2, and the bridge frame is located at the left support frame LSF and the right support frame RSF. Both ends of the BF are seated, and the processing unit 50 mounted to the bridge frame BF is disposed on the upper portion of the transfer table 60, and the upper end of the first left vertical column LP1 and the first right vertical column. The front beam FB1 is connected to the upper end of the RP1, and the first and second thickness measuring devices 70 and 75 are disposed on the front beam FB1, so that the first and second thickness measuring devices 70 and 75 are disposed. ) Measures the thickness of the left end and the right end of the slab material is supplied to the transfer table 60, respectively, and the sides of the first and second thickness measuring devices 70, 75 The signal is input to the calculating device 80, and the two measuring signals are calculated by the calculating device 80 to control the operation of the level adjusting device 90, whereby the transfer table 60 is controlled by the level adjusting device 90. A bridge-type stone processing machine, characterized in that the left and right inclination is adjusted by the left and right thickness difference of the slab material.
The method of claim 3, wherein
The processing unit 50 is a bridge type slab processing machine, characterized in that any one of the saw cutting line, guillotine type grinder, twin head type grinder, slab smoothing.
The method according to any one of claims 1 to 3,
The transfer table 60 is a bridge type slab processing machine, characterized in that any one of a conveyor belt device or a roller table.
The method according to any one of claims 1 to 3,
The transfer table 60 has a conveyor belt 61 supported by the left frame 62 and the right frame 63, and the first bracket 64 of the left frame 62 is mounted on the left vertical column LP. Coupled by the second bracket 65 and the pin 66, the right frame 63 is connected to the horizontal adjusting device 90 by the third bracket 67, the height of the arrangement of the right frame 123 ( h1) is a bridge-type slab processing machine, characterized in that the adjustment by the horizontal adjusting device (90).
The method according to any one of claims 1 to 3,
The transfer table 60 has a lower beam FM connected to the lower ends of the left vertical pillar LP and the right vertical pillar RP, and the fourth bracket 601 and the left frame (mounted to the lower beam FM). The fifth bracket 602 mounted on the lower surface of the 62 is coupled by the pin 603, the right frame 63 is coupled with the leveling device 90 mounted on the lower beam FM, the right frame Bridge height slab processing machine characterized in that the height of the arrangement (123) is adjusted by the horizontal adjusting device (90).
The method according to any one of claims 1 to 3,
The first thickness measuring device 70 includes a housing 702 mounted to the slider 701 that can be moved along the front beam FB1, an air cylinder 703 disposed inside the housing 702, and The vertical rod 706 connected to the connecting rod 704 of the air cylinder 703 by the connecting member 705, the roller 707 mounted at the lower end of the vertical rod 706, and the housing 702 of the housing 702. Bridge-type slab processing machine, characterized in that consisting of an encoder 708 disposed inside to measure the lifting height of the vertical rod (706).
The method according to any one of claims 1 to 3,
In the first thickness measuring device 70, the vertical rod 712 is fitted into the box-shaped housing 711 so that the vertical rod 712 can be lifted and lowered. Spring 714 is disposed in the interior thereof, the upper end of the spring 714 is connected to the upper mounting portion 715 of the vertical rod 712, the lower end of the spring 714 is mounted to the lower surface of the housing 711 The encoder 716 disposed inside the housing 711 measures the rising height of the vertical rod 712, and the stopper 717 is mounted inside the housing 711 to be perpendicular to the stopper 717. A bridge type slab processing machine, characterized in that the lowering of the vertical rod 712 is limited by the stopper 717 by catching the upper mounting portion 715 of the rod 712.
The method of claim 8,
The first thickness measuring device 70 is movable frame 725 of the elevating device 720 such that the height of the housing 711 is determined by the elevating device 720 mounted in the middle of the front beam FB1. A horizontal slab 726 is mounted at the bottom, a slider 727 is disposed at one end of the horizontal cradle 726, and the housing 711 is mounted on the slider 727.
11. The method of claim 10,
The lifting device 720 has a fixed bearing means 721 is mounted to the front beam (FB1), the screw shaft 722 is rotatably mounted to the fixed bearing means 721, the motor 723 and When the output gear of the connected reducer 724 is coupled with the screw shaft 722 and the movable frame 725 is mounted on the reducer 724, and the motor 723 is driven, the motor 723 and the reducer 724 are A bridge-type slab processing machine, characterized in that the movable frame 725 attached to the reducer 724 is lowered by being lowered along the screw shaft 722.
11. The method of claim 10,
The lifting device 720 is mounted with a connecting rod 733 of the cylinder 732 on the upper end of the fixed frame 731 mounted on the front beam (FB1), the movable frame 734 is mounted on the cylinder 732 When the connecting rod 733 is introduced into the cylinder 732, the cylinder 732 is relatively lowered so that the movable frame 734 attached to the cylinder 732 is lowered. .
The method according to any one of claims 1 to 3,
The second thickness measuring device (75) is a bridge-type slab processing machine, characterized in that configured in the same way as the first thickness measuring device (70).
The method according to any one of claims 1 to 3,
The calculating device 80 compares the output signal of the first thickness measuring device 70 with the output signal of the second thickness measuring device 75, so that the measured value of the first thickness measuring device 70 measures the second thickness. If greater than the measured value of the device 75 (ie, the left end of the slab W is thicker than the right end), the geared motor GM of the leveling device 90 is driven at the negative output terminal 81. Output to the second magnetic contactor (MC2), the geared motor (GM) of the horizontal adjusting device 90 is rotated in reverse, so that the right frame 63 of the transfer table 60 is disposed higher than the left frame (62) If the upper surface of the slab (W) is in contact with the processing unit 50 perpendicularly, and the measured value of the first thickness measuring device 70 is smaller than the measured value of the second thickness measuring device 75 (that is, , If the right end of the slab (W) is thicker than the left end), the first electromagnetic contact for driving the geared motor (GM) of the leveling device 90 at the positive output terminal 82 When the geared motor GM of the horizontal adjusting device 90 is rotated forward by outputting to the machine MC1, the arrangement height of the right frame 63 of the transfer table 60 becomes higher than that of the left frame 62, and the slab material Bridge type slab processing machine, characterized in that the upper surface of (W) is in contact with the processing unit 50 perpendicular to.
The method according to any one of claims 1 to 3,
The horizontal adjusting device 90 is a worm gear 902 mounted on the output shaft 901 of the geared motor (GM) is disposed in the gearbox 903, the worm gear 902 is interlocked with the worm 904 The lifting shaft 905 is fitted to the hollow portion of the worm 904, the spiral portion 906 of the lifting shaft 905 and the spiral portion 907 formed around the hollow portion of the worm 904 are engaged with each other. The upper end of the 905 is connected by the sixth bracket 67 and the pin 908, the sixth bracket 67 is connected to the right frame 63 of the transfer table 60, the gearbox 903 The seventh bracket 909 is mounted on the lower surface, and the seventh bracket 909 is coupled by the eighth bracket 911 and the pin 912 mounted on the upper surface of the support pillar 910. Bridge type slab processing machine.
The method of claim 15,
The gearboxes 903 and 915 are disposed at both ends of the output shaft 901 so that the power of the output shaft 901 is simultaneously transmitted to the two gearboxes 903 and 915. Processing machine.
The method according to any one of claims 1 to 3,
The horizontal adjustment device 90 is connected to the eighth bracket 911 of the support pillar 910 and the ninth bracket 921 mounted at the bottom of the cylinder 920 by a pin 922, the cylinder 920 Bridge rod slab processing machine, characterized in that the connecting rod 923 is connected to one end of the tenth bracket (924) mounted on the right frame (63) of the transfer table (60).
The method according to any one of claims 1 to 3,
The horizontal adjusting device 90 is rotatably mounted to the output shaft 931 of the geared motor to the eleventh bracket 930 mounted to the lower beam (FM), the eccentric cam 935 on the output shaft 931 Bridged slab processing machine, characterized in that the eccentric cam (935) supports the right frame (63) of the transfer table (60).
The method of claim 2,
The drive means 100 includes a reduction gear motor 101 mounted on the movable frame DF, an output shaft 103 fitted into the gearbox 102 of the reduction gear motor 101, and an amount of the output shaft 103. Consists of pinions 104 and 105 attached to the end, and rack gears 106 and 107 mounted to the front bridge frame bf1 and the rear bridge frame bf2, respectively, and engaged with the pinions 104 and 105. Bridge-type slab processing machine, characterized in that.
The method of claim 2,
The driving means 100 has a first cylinder 111 and a second cylinder 115 mounted on the left beam LF, respectively, and the connecting rod 112 of the first cylinder 111 has a housing of the wheel wh1. And a connecting rod 116 of the second cylinder 115 is connected to the housing 117 of the wheel wh2.
The method of claim 3, wherein
Wheels 111 and 112 are mounted at lower ends of the left support frame LSF and the right support frame RSF, respectively, and the wheels 111 and 112 are moved along the rails 113 and 114. Bridge type slab processing machine.

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