KR101168690B1 - Stone ultra slim cutting machine - Google Patents

Abstract

PURPOSE: An ultra-slim stone cutting machine is provided to cut a stone plate to a small thickness by detecting the pressure and impact exerted on the stone plate being cut. CONSTITUTION: An ultra-slim stone cutting machine comprises a staple-shaped port frame(1), two slide blocks(7,13), a plurality of saw blades(12), a motor(15), a speed reducer(14), a raw material cart(10), and a control unit. The port frame includes two column parts and a top frame which connects the top of two columns installed on the ground. The two slide blocks are installed in the middle of the two column parts and moved up and down by first and second vertical lead screws(5,16). The plurality of saw blades are installed in parallel at regular intervals on a main shaft(8) and cut a stone plate. The motor and the speed reducer rotate and reduce the speed of the saw blades. The raw material cart is horizontally moved by the torque of the motor on a ground track(11). The control unit detects the pressure and impact exerted on the stone plate when the saw blades cut the stone plate and controls the rotating speed and cutting pressure of the saw blades in order to prevent damage to the stone plate.

Description

Stone ultra slim cutting machine

The present invention is to install a plurality of saw blades in parallel to cut a plurality of slabs, when the saw blade cut the slabs by detecting the pressure and the amount of impact acting on the slabs stone slabs that can be cut to a thin thickness without breaking the slabs It is about a cutter.

Conventional stone cutters could not control the rotational speed and cutting pressure of the saw blade by detecting the pressure and the amount of impulse applied to the slab, it was impossible to produce large slabs of about 5T thickness.

And the conventional stone cutting machine is relatively many in the same kind of equipment because of the market demand. However, neglecting the stability of the mechanical principle and the automation of the machine speed control, the efficiency of the equipment during the production process decreased and the product was frequently damaged.

Therefore, it is urgent to develop a device capable of producing a large slab with a thickness of about 5T since the rotation speed and cutting pressure of the saw blade are controlled by sensing the pressure and the amount of impulse applied to the slab.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art. The purpose is as follows.

Firstly, a plurality of saw blades are installed in parallel to cut a plurality of slabs, and when the saw blade cuts slabs, the stone ultrathin cutting machine can cut the slabs to a thin thickness without damaging the pressure and impact applied to the slabs. To provide.

Second, it is possible to provide mass production of large slabs of about 5T thickness without damage at the same time to provide a stone ultra-slim cutter with excellent productivity and economy.

Third, it is possible to produce a slab of a predetermined quality even for unskilled workers with a simple structure and mechanism to provide a stone ultra-slim cutter with excellent safety.

In order to solve the above technical problem, the present invention is a stone cutting machine, which is installed on the ground, the bottom of the U-shaped form comprising an upper frame installed by connecting the left and right two pillars and the top of the two pillars Port frame (1) of the; Two slide blocks (7, 13) installed at the two column stops and movable up and down through the first vertical lead screw (5) and the second vertical lead screw (16); A plurality of saw blades 12 installed in parallel while maintaining a predetermined interval between the main shaft 8 by cutting the main shaft 8 and the slabs connected and installed between the two slide blocks (7, 13); A motor (15) and a reduction device (14) installed on the slide block (13) to rotate and decelerate the saw blade (12); A raw material vehicle 10 horizontally moving on a ground path 11 installed on the ground below the saw blade 12 with a driving force of a motor (not shown); A feed frame 9 installed above the raw material vehicle 10; And a controller (not shown) for detecting the pressure and the amount of impact acting on the slab when the saw blade 12 cuts the slab to adjust the rotation speed and the cutting pressure of the saw blade 12 so that the slab is not damaged. Consists of including

The feed frame 9 is installed on the support (9-1), the support (9-1) in the lower portion of the two pairs of mutually opposite vertical bar (9-3), a pair of vertical bar ( 9-3) is provided between the slab gripper (9-2) is installed between the lower and lower sides of the slab is installed between the plurality of vertical bars vertically erected in parallel to the plurality of vertical bar (9-3) Provided is a stone ultra-slim cutter, characterized in that the cutting of two slabs at the same time.

According to the present invention, the following effects are expected.

Firstly, a plurality of saw blades are installed in parallel to cut a plurality of slabs, and when the saw blade cuts slabs, the stone ultrathin cutting machine can cut the slabs to a thin thickness without damaging the pressure and impact applied to the slabs. To provide.

Second, the large-size slab of about 5T thickness can be mass-produced at the same time without damage, thereby providing a stone ultra-slim cutter having excellent productivity and economy.

Third, it is possible to produce slabs of a predetermined quality even for unskilled workers with a simple structure and mechanism to provide a stone ultra-slim cutter with excellent safety.

1 is a front view of a stone ultrathin cutter of the present invention.
2 is a plan view of a feed frame in the present invention.
3 is a cross-sectional view of C in FIG. 2.
4 is an enlarged view of D in FIG. 2.
5 is an enlarged view of E in FIG. 2.
FIG. 6 is an enlarged view of F in FIG. 3.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view of a stone ultrathin cutter of the present invention, Figure 2 is a plan view of a feed frame in the present invention.

Stone ultra-thin cutter of the present invention is a stone cutter, the bottom of the U-shaped port frame is configured to be installed on the ground, including the upper frame is installed by connecting the left and right two pillars and the top of the two pillars ( One); Two slide blocks (7, 13) installed at the two column stops and movable up and down through the first vertical lead screw (5) and the second vertical lead screw (16); A plurality of saw blades 12 installed in parallel while maintaining a predetermined interval between the main shaft 8 by cutting the main shaft 8 and the slabs connected and installed between the two slide blocks (7, 13); A motor (15) and a reduction device (14) installed on the slide block (13) to rotate and decelerate the saw blade (12); A raw material vehicle 10 horizontally moving on a ground path 11 installed on the ground below the saw blade 12 with a driving force of a motor (not shown); A feed frame 9 installed above the raw material vehicle 10; And a controller (not shown) for detecting the pressure and the amount of impact acting on the slab when the saw blade 12 cuts the slab to adjust the rotation speed and the cutting pressure of the saw blade 12 so that the slab is not damaged. Consists of including

The feed frame 9 is installed on the support (9-1), the support (9-1) in the lower portion of the two pairs of mutually opposite vertical bar (9-3), a pair of vertical bar ( 9-3) is installed between the slab gripper (9-2) for pressing and fixing the slabs on both sides of the lower and lower,

It is characterized by cutting a plurality of slabs which are vertically erected in parallel to the plurality of vertical bars 9-3.

As shown in FIG. 1, the upper frame of the port frame 1 is further provided with a motor 2, a lead screw 3 installed at both ends of the motor 2, and the lead screw 3 being formed of the first frame. The first vertical lead screw 5 and the second vertical lead screw 16 may be connected to the bevel gear set 4.

5 is an enlarged view of E in FIG. 2.

Nuts 9-9 are installed on the vertical bar 9-3, feed screw nuts 9-14 are installed on the slabs, and the nuts 9-9 and the feed screw are installed on the slabs. Since the nut 9-14 is connected to the nut III (9-13) and the bevel gears (9-11, 9-12), it is characterized in that to reduce the amount of impact applied to the slab while fixing the slab. Can be.

The control unit (not shown), (1) a sensing module for sensing the pressure and impact amount acting on the slab; (2) an analysis module for analyzing the sensed pressure and impact amount in real time; And, (3) a control module for adjusting the rotational speed and the cutting pressure of the saw blade 12 based on the analyzed results; it may be characterized in that it comprises a.

The present invention will be described in detail as follows.

The slab precision cutter of the present invention shown in FIG. 1 includes a port frame 1, a saw blade 12, a feed frame 9, a raw material vehicle 10, and a ground track 11.

The ground track 11 is installed on the ground below the port frame 1, the feed frame 9 is installed on the raw material vehicle 10, and the raw material vehicle 10 is installed on the ground track 11. The raw material vehicle 10 is provided with a motor (not shown) which drives the motion on the ground track 11 of the raw material vehicle 10.

Both posts of the port frame (l) are provided with vertical tracks (6), the right vertical track (6) is provided with a slide block (7), the left vertical track (6) has a slide block ( 13) is installed. The slide block 13 is provided with a motor 15 and a reduction device 14 and the reduction device 14 is connected to the motor 15, the saw blade 12 is fixed to the main side (8) in parallel Several are installed. The right side of the main shaft 8 is connected to the slide block 7, the left side of the main shaft 8 is connected to the reduction gear 14, and the feed frame 9 is located below the main shaft 8.

Three vertical lead screws (5, 16, 17) are installed in the port frame (l), and the slide block (7) is connected to the first vertical lead screw (5) in the form of a screw pattern, and the slide block (13). Is connected to the second vertical lead screw 16 in the form of a screw pattern.

The upper frame of the port frame 1 is provided with a horizontal lead screw 3 and a motor 2 responsible for the rotation of the horizontal lead screw 3. The first vertical lead screw 5, the second vertical lead screw 16, and the third vertical lead screw 17 are connected to the horizontal lead screw 3 through one bevel gearset 4, respectively.

The bevel gearset 4 of course comprises two interlocking bevel gears.

3 is a cross-sectional view of C in FIG. 2.

As shown in Figs. 2 and 3, the feed frame 9 includes a fixed frame and several slab grippers 9-2. The slab gripper 9-2 is formed with a slab groove for installing a slab, and the fixing frame includes a support 9-1 and a vertical bar 9-3 installed on the support 9-1. A pair of vertical bar (9-3) is connected to one slab gripper (9-2), and a top of each end of the slab gripper (9-2) is connected to one adjacent vertical bar (9-3). There is a suspension installed.

4 is an enlarged view of D in FIG. 2, and FIG. 6 is an enlarged view of F in FIG. 3.

4 and 6,

The suspension includes a sliding plate 9-10, a sleeve 9-5 and a shaft 9-4. One side of the shaft 9-4 is fixed to the upper end of the lithographic gripper 9-2, the other side of the shaft 9-4 is installed in the sleeve 9-5, and the sleeve 9-5. ) Is fixed to the upper end of the sliding plate (9-10). The sliding plate 9-10 holds the vertical bar 9-3.

The position adjusting device I is provided above the slab gripper 9-2, and the position adjusting device II is provided below the slab gripper 9-2.

4 and 6, the position adjusting device I includes a nut I 9-6, a handle I 9-7 and a rack pinion 9-15.

The rack pinion (9-15) is fixed to the upper portion of the slab gripper (9-2), the nut I (9-6) is rotatably connected to the vertical bar (9-3), the handle I (9-7) ) And gears 9-16 are fixed to both ends of nut I 9-6. The axial direction of the nut I 9-6 is the same as the longitudinal direction of the slab groove on the slab gripper 9-2.

4 and 5,

Position adjuster II uses nut II (9-9), nut III (9-13), feed screw nut (9-14), handle II (9-8) and bevel gears (9-11, 9-12). Include.

The nut II (9-9) and the vertical bar (9-3) are connected in the form of a screw pattern. The handle II (9-8) and the bevel gear (9-11) are connected at both ends of the nut II (9-9). The nut III (9-13) is connected to the feed screw nut (9-14).

The feed screw nut 9-14 is fixed under the slab gripper 9-2, the bevel gear 9-12 is fixed to the nut III 9-13, and the nut III 9-13. The axial direction of is perpendicular to the longitudinal direction of the slab groove on the slab gripper 9-2.

In conclusion, the present invention is installed by cutting a plurality of saw blades in parallel to cut a plurality of slabs, when the saw blade cut the slabs by detecting the pressure and the amount of impact acting on the slabs can be cut to a thin thickness without breaking the slabs. have. In addition, it is possible to mass-produce large scale slabs of 5T thickness without damage at the same time, which is excellent in productivity and economic efficiency, and provides unskilled workers with high-precision slabs with a simple structure and mechanism.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

Therefore, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

1: port frame
2, 15: motor
3: lead screw
4: bevel gearset
5: 1st vertical lead screw
7, 13: slide block
8: headstock
9: feedframe
9-1: Support
9-2: Slab Gripper
9-3: Vertical Bar
9-9: Nut
9-11, 9-12: Bevel Gears
9-13: Nut III
9-14: Feed Screw Nut
10: raw material tea
11: ground clearance
12: saw blade
14: reduction gear
16: 2nd vertical lead screw

Claims (5)

In stone cutting machine,
Port frame (1) of the bottom of the U-shaped opening is configured to be installed on the ground, including the upper frame is installed by connecting the left and right two pillars and the top of the two pillars;
Two slide blocks (7, 13) installed at the two column stops and movable up and down through the first vertical lead screw (5) and the second vertical lead screw (16);
A plurality of saw blades 12 installed in parallel while maintaining a predetermined interval between the main shaft 8 by cutting the main shaft 8 and the slabs connected and installed between the two slide blocks (7, 13);
A motor (15) and a reduction device (14) installed on the slide block (13) to rotate and decelerate the saw blade (12);
A raw material vehicle 10 horizontally moving on a ground path 11 installed on the ground below the saw blade 12 with a driving force of a motor (not shown);
A feed frame 9 installed above the raw material vehicle 10; And,
A controller (not shown) that senses the pressure and impact amount acting on the slab when the saw blade 12 cuts the slab and adjusts the rotational speed and cutting pressure of the saw blade 12 so that the slab is not damaged;
, ≪ / RTI >
The feed frame 9 is installed on the support (9-1), the support (9-1) in the lower portion of the two pairs of mutually opposite vertical bar (9-3), a pair of vertical bar ( 9-3) is installed between the slab gripper (9-2) for pressing and fixing the slabs on both sides of the lower and lower,
Stone super slim cutting machine, characterized in that the vertical cut to the plurality of vertical bar (9-3) is cut at the same time a plurality of slate standing in parallel.
In claim 1,
The upper frame of the port frame 1 is further provided with a motor (2), a lead screw (3) installed on both ends of the motor (2),
The lead screw (3) is stone super slim cutter, characterized in that connected to the first vertical lead screw (5) and the second vertical lead screw (16) and the bevel gearset (4).
3. The method according to claim 1 or 2,
The nut 9-9 is installed on the vertical bar 9-3, and the feed screw nut 9-14 is installed on the slab, and the nut 9-9 and the feed screw nut 9-14 are Since it is connected by nut III (9-13) and bevel gears (9-11, 9-12),
The stone super slim cutter, characterized in that for fixing the slab and at the same time reduce the amount of impact applied to the slab.
3. The method according to claim 1 or 2,
The control unit (not shown),
(1) a sensing module for sensing the pressure and impact amount acting on the slab;
(2) an analysis module for analyzing the sensed pressure and impact amount in real time; And,
(3) a control module for adjusting the rotation speed and cutting pressure of the saw blade 12 based on the analyzed result;
Stone ultrathin cutter, characterized in that configured to include.
4. The method of claim 3,
The control unit (not shown),
(1) a sensing module for sensing the pressure and impact amount acting on the slab;
(2) an analysis module for analyzing the sensed pressure and impact amount in real time; And,
(3) a control module for adjusting the rotation speed and cutting pressure of the saw blade 12 based on the analyzed result;
Stone ultrathin cutter, characterized in that configured to include.

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