KR20130085683A - Ground level adjusting device for non-slip of machine tools - Google Patents

Abstract

PURPOSE: A level adjusting device for preventing the slip of a machine tool is provided to firmly support the machine tool in spite of the vibration and impact of the machine tool by increasing friction coefficient between a floor surface and the underside of a leveling block with first and second concave portions and first and second convex portions. CONSTITUTION: A level adjusting device for preventing the slip of a machine tool comprises a leveling bolt (10), a leveling nut (20), and a leveling block (30). The leveling nut fixes the leveling bolt on a bed (2). A fixing groove is arranged on the top of the leveling block so that the bottom of the leveling block can be placed. A first concave portion (32) and a first convex portion (33) are formed on the underside of the leveling block to prevent slip on a floor surface (50). The first concave part is a Y-shape based on the line of gravity of the underside of the leveling block.

Description

Ground level adjusting device for non-slip of machine tools

The present invention relates to a level adjustment device applied to the installation of the machine tool on the ground, and more particularly, by the structure of the bottom surface of the leveling block to increase the frictional force with the ground, the vibration and impact during operation of the machine tool A level adjusting device for preventing slip of a machine tool for preventing the machine from slipping to improve the product yield of the machine tool.

A wide range of machine tools, including turning centers, machining centers, doormat machining centers, swiss turns, electric discharge machines, horizontal NC boring machines and CNC lathes, are widely used in a variety of industrial applications to suit their application.

In general, when installing a machine tool, a bed of a machine tool is installed at the bottom of the installation site. The level measuring instrument is then placed on the guide surface of the bed or on the table top to achieve the basic level of the machine tool as a whole. However, the machine tool has a heavy load and it takes a lot of manpower and time to adjust the level of these machine tools.

In general, the friction force (F, 摩擦力) means a force that interferes with the movement along the contact surface when the two objects are in contact with the movement. This frictional force is calculated as the product of the normal force (N), the coefficient of friction (μ), which is the force that the floor supports to the object (Equation 1).

F = μ × N --- Equation 1

These frictional forces are classified into (F) maximum static frictional force (F _S ) at the moment when a stationary object is just starting to move and motion frictional force (F _K ) that blocks the movement of an object when it is in contact with the surface of another object. can do. Therefore, the maximum static frictional force (F _S ) (Equation 2) and the motion frictional force (F _K ) (Equation 3) are the values of the friction coefficient (μ _s : maximum static friction coefficient), μ _k : kinematic friction coefficient in the above equation 1 Is changed.

F _S = μ _s × N --- Equation 2

F _K = μ _k × N --- Equation 3

These coefficients of friction depend on the material of the object, the smoothness of the surface, and the presence and absence of lubricants. In an ideal state, the frictional force is independent of the area of the contact surface.

Also, in general, a machine tool generates a lot of vibrations or shocks during operation, and the machine tool slides when the friction coefficient between the leveling block and the bottom surface is low due to the vibrations or shocks. If the machine tool slips during the operation of the machine tool, there is a problem that the machining error of the workpiece is out of tolerance to reduce the product yield and increase the production cost.

Moreover, in the case where ultra-precision machining is required today, if the machine tool slides even minutely due to vibration during the operation of the machine tool, there is a difference in the machining of the work piece, which significantly increases the defective parts and increases the production cost and production time. There is a problem to increase.

The present invention is to solve the above problems, the present invention is the first concave portion and the first convex portion formed on the lower surface of the leveling block, the second concave portion and the second concave portion formed in addition to the first convex portion An object of the present invention is to provide a level adjusting device for preventing slippage of a machine tool by increasing the friction coefficient between the bottom surface and the contact surface of the leveling block by the convex portion.

In order to achieve the object of the present invention, a level adjusting device for preventing slippage of a machine tool according to the present invention includes a leveling bolt having a thread on an outer circumferential surface thereof and fastened to a bed; A leveling nut having a screw groove corresponding to the thread of the leveling bolt on an inner circumferential surface to fix the leveling bolt to the bed; And a leveling block having a fixing groove in an upper surface to seat the lower end of the leveling bolt, and having a first concave portion and a first convex portion in a lower surface to prevent sliding with a bottom surface. 1 The recess is formed in a Y shape with respect to the center of gravity line of the lower surface of the leveling block.

In addition, the first convex portion of the level adjusting device for preventing slip of the machine tool according to the present invention is formed symmetrically with respect to the center of gravity line.

Further, in another preferred embodiment of the present invention, the first convex portion of the level adjusting device for preventing slippage of the machine tool may further include a second concave portion and a second convex portion.

In addition, in another preferred embodiment according to the present invention, the level adjusting device for slipping of the machine tool comprises an anchor fixedly inserted into the bottom surface; A stud bolt that is engaged with the anchor through a cavity formed in the center of the leveling bolt and a through hole formed from the fixing groove of the leveling block to the first recess of the Y shape; And a stud nut for fastening the stud bolt to the leveling bolt.

The present invention can easily adjust the height of the machine tool by a simple operation of rotating the leveling bolt. In addition, the present invention increases the coefficient of friction between the bottom surface and the lower surface of the leveling block by the first, second concave portions and the first and second convex portions formed on the lower surface of the leveling block, which is generated during the operation of the machine tool. The machine tool can be firmly supported against vibration and shock, and the machine tool can be prevented from slipping. Furthermore, the present invention has the effect of preventing slipping during operation of the machine tool, enabling precision machining of the machine tool, and improving the product yield of the machine tool.

1 shows a schematic view of a machine tool with a level adjusting device for preventing slippage of the machine tool according to the present invention.
FIG. 2 shows a detailed sectional view of the level adjusting device for preventing slippage of the machine tool shown in FIG. 1.
3 shows a cross-sectional view of the leveling block shown in FIG. 2.
4 shows a bottom view of the leveling block shown in FIG. 2.
Figure 5 shows a detailed cross-sectional view of another preferred embodiment of a level adjusting device for preventing slippage of a machine tool according to the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to components of each drawing, the same components are designated by the same reference numerals.

1 shows a schematic view of a machine tool 1 with a level adjusting device 3 for preventing slippage of a machine tool according to the invention. FIG. 2 shows a detailed sectional view of the level adjusting device 3 for preventing slippage of the machine tool shown in FIG. 1. 3 and 4 show a cross-sectional view and a bottom view of the leveling block 30 shown in FIG. 2.

A level adjusting device 3 for preventing slippage of a machine tool according to the present invention will be described with reference to the drawings of FIGS. 1 to 4. The level adjusting device 3 for preventing slippage of a machine tool according to the present invention comprises a leveling bolt 10, a leveling nut 20, and a leveling block 30.

In a preferred embodiment of the present invention, threads are formed on the outer circumferential surface of the leveling bolt 10. A tab (not shown) is formed in the bed 2 to which the leveling bolt 10 can be fastened, and a thread groove corresponding to the thread of the leveling bolt 10 is formed inside the tab. Therefore, the leveling bolt 10 and the bed 2 are coupled by the thread and the thread groove of the leveling bolt 10 and the bed. A thread groove corresponding to the thread of the leveling bolt 10 is formed on the inner circumferential surface of the leveling nut 20. The leveling nut 20 prevents the leveling bolt 10 from leaving the bed 2. The level of the machine tool is increased by rotating the head of the leveling bolt 10 to move the leveling bolt 10 downward of the bed 2, and when the head of the leveling bolt 10 is rotated in reverse, the leveling bolt 10 Moves upwards of the bed 2, resulting in a lower level of the machine tool. Therefore, the non-slip level adjusting device 3 of the machine tool according to the present invention can adjust the level (height) of the machine tool 1 by a simple operation of rotating the leveling bolt 10, thereby attracting manpower during the level adjustment operation. And the effect of reducing time.

The leveling block 30 has a fixing groove 31 on which the lower end of the leveling bolt 10 can be seated. The fixing groove 31 is fixed so that the leveling bolt 10 does not move on the upper surface of the leveling block 30, thereby adjusting the level of the machine tool. The first concave portion 32 and the first convex portion 33 are formed on the lower surface of the leveling block 30 to prevent sliding with the bottom surface 50. Preferably, the first concave portion 32 is formed in a Y shape with respect to the center of gravity line A of the lower surface of the leveling block 30. More preferably, the first convex portion 33 is formed at three portions of the lower surface of the leveling block 30 except for the first concave portion 32, and is formed symmetrically based on the center of gravity line A. have. In other words, they are formed symmetrically with respect to the Y-shaped first concave portion 32.

As can be seen in FIGS. 3 and 4, in another preferred embodiment of the present invention, the first convex portion 33 further includes a second concave portion 34 and a second convex portion 35. Preferably, the second convex portion 35 is formed as a quadrangle, but is not necessarily limited thereto, and the maximum stop friction coefficient may be affected by affecting the roughness of the surface of the bottom surface 50 and the lower surface of the leveling block 30. It can be in various forms that can be increased. By the first and second concave portions 32 and 34 and the first and second convex portions 33 and 35, the lower surface of the leveling block 30 increases the surface roughness with the bottom surface 50, thereby providing maximum stopping. It increases the coefficient of friction (μ _s ). Therefore, the maximum frictional friction force F _S between the lower surface and the bottom surface 50 of the leveling block 30 is increased to prevent the machine tool from slipping due to vibration and impact during operation of the machine tool, thereby making ultra-precision machining possible. It is possible to improve the yield of the product. A plurality of such level adjusting devices 3 may be installed in the bed 2 of the machine tool according to the size, weight, or shape of the bottom surface 50 of the machine tool 1.

Fig. 5 shows a detailed sectional view of another preferred embodiment of the level adjusting device 3 for preventing slippage of a machine tool according to the present invention. According to another preferred embodiment of the present invention, the level adjusting device 3 for preventing slippage of a machine tool further includes an anchor 41, a stud bolt 42, and a stud nut 43. The anchor 41 is fixedly inserted into the bottom surface 50 during the compaction operation of the bottom surface 50. The leveling bolt 10 has a cavity formed in the center thereof, and a through hole 36 is formed from the fixing groove 31 of the leveling block 30 to the first concave portion 32 having a Y shape. do. The stud bolt 42 is inserted from the upper end of the leveling bolt 10 through the cavity of the leveling bolt 10 and the through hole 36 of the leveling block 30, and the stud bolt 42 is formed on the bottom surface ( 50 is fastened to the anchor 41 fixedly inserted. The stud nut 43 is fastened to the upper end of the stud bolt 42 to fasten the stud bolt 42 to the leveling bolt 10. Accordingly, the machine tool 1 is immovably fixed to the bottom surface 50, and the first and second recesses 32 and 34 and the first and second convex portions formed on the lower surface of the leveling block 30 are fixed. It is possible to prevent the machine tool from slipping during operation of the machine tool by increasing the maximum static friction coefficients 33 and 35 and the bottom surface 50.

The present invention is not limited to the modifications shown in the drawings and the embodiments described above, but may be extended to other embodiments falling within the scope of the appended claims.

1: machine tool, 2: bed,
3: level adjusting device, 10: leveling bolt,
11: cavity, 20: leveling nut,
30: leveling block, 31: fixing groove,
32: first concave portion, 33: first convex portion,
34: second concave portion, 35: second convex portion,
36: through hole, 41: anchor,
42 stud bolt, 43 stud nut,
50: bottom surface, A: center of gravity line.

Claims (4)

A leveling bolt (10) having threads on the outer circumferential surface and fastened to the bed (2);
A leveling nut (20) for securing the leveling bolt (10) to the bed (2) by providing a screw groove corresponding to the thread of the leveling bolt (10) on an inner circumferential surface; And
The lower surface of the leveling bolt 10 is provided with a fixing groove 31 on the upper surface, and the first concave portion 32 and the first convex portion on the lower surface to prevent sliding with the bottom surface 50 A leveling block 30 having a 33;
The first concave portion (32) is a level adjustment device for preventing slip of the machine tool, characterized in that formed in the Y-shape on the basis of the center of gravity (A) of the lower surface of the leveling block (30).
The method of claim 1,
The first convex portion (33) is a level adjustment device for preventing slip of the machine tool, characterized in that formed on the basis of the center of gravity (A) symmetrical.
The method according to claim 1 or 2,
The first convex portion (33) further comprises a second concave portion (34) and the second convex portion (35) characterized in that the level adjustment device for preventing slip of the machine tool.
The method of claim 3,
An anchor 41 is fixedly inserted into the bottom surface 50;
The anchor is formed by passing through the cavity formed in the center of the leveling bolt 10 and the through hole 36 formed from the fixing groove 31 of the leveling block 30 to the first concave portion 32 having a Y shape. A stud bolt 42 engaged with 41; And
And a stud nut (43) for fastening the stud bolt (42) to the leveling bolt (10).

Images