CN221054567U - Support foot with antidetonation spiral structure - Google Patents

Abstract

The utility model relates to a supporting foot with an anti-seismic spiral structure, which comprises a spiral support and a spiral column, wherein the spiral support and the spiral column are of an integrated structure, a lifting support block is sleeved on the spiral column, a damping rubber cushion is arranged on the lifting support block, and a locking screw is inserted into the upper thread of the spiral column. The utility model aims to provide a supporting foot with an anti-vibration spiral structure, wherein a spiral column and a spiral support are integrated into a whole, so that a zero-clearance loosening deformation effect can be achieved, and the upper end surface of a damping rubber cushion is attached to and tightly pressed against a supporting surface at the bottom of a machine tool to achieve an anti-vibration and anti-vibration effect.

Description

Support foot with antidetonation spiral structure

Technical Field

The utility model relates to the field of machine tool supporting structures, in particular to a supporting foot with an anti-seismic spiral structure.

Background

Most of the existing common machine tool foundation types only play a role in horizontal adjustment, no shock resistance and no looseness prevention occur, and the support stability is unstable due to the use of the ground environment; greatly reduces the machining usability level of the machine tool.

The loosening of the supporting feet is caused by the machine tool in the processing process; particularly, the heavy cutting machining (the heavy cutting machining refers to vibration generated by overlarge area of a cutter contacting a workpiece when the cutter cuts the workpiece), and the vibration can lead to loosening of a supporting foot support rod or a supporting surface at the bottom of a machine tool for a long time, thereby affecting the machining precision and the smoothness of the machine tool and even prolonging the service life; the supporting foot vibration is generated because the supporting surface at the bottom of the machine tool is contacted with the supporting surface of the supporting foot, and under the condition of the contact surface, the environment under the ground belongs to foam or the machine tool is installed on the floor surface, so that the whole vibration of the machine tool is influenced, and the finish of the machine tool processing is influenced; the unstable support of the support foot is caused by the fact that the support foot base surface and the ground are not parallel to each other after the machine tool is placed horizontally and the forced locking foot rod is placed on the ground, so that the rod body and the foot base surface are bent and deformed, the non-comprehensive contact between the foot base surface and the ground is directly affected, the horizontal precision position of the machine tool is changed, and the source of unstable machining precision factors used in the later stage of the machine tool is caused.

Disclosure of utility model

The utility model aims to provide a supporting foot with an anti-vibration spiral structure, wherein a spiral column and a spiral support are integrated into a whole, so that a zero-clearance loosening deformation effect can be achieved, and the upper end surface of a damping rubber cushion is attached to and tightly pressed against a supporting surface at the bottom of a machine tool to achieve an anti-vibration and anti-vibration effect.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a support lower margin with antidetonation spiral structure, includes screw support and screw column, screw support and screw column structure as an organic whole, the screw column on cup jointed the lift supporting shoe, the lift supporting shoe on be provided with the shock attenuation cushion, and the upper end screw thread plug bush of screw column has locking screw.

Preferably, the locking screw rod is sleeved with an anti-loosening pressing sheet, and annular teeth are arranged at the lower part of the anti-loosening pressing sheet.

Preferably, the side surface of the lifting support block is provided with a jackscrew and an adjusting screw, and the jackscrew is used for clamping the lifting support block on the screw column.

Preferably, the lower part of the spiral support is provided with a spherical base, and the upper part of the spherical base is hemispherical and is arranged in a hemispherical notch of the lower part of the spiral support.

The utility model has the technical effects that:

The screw column and the screw support are integrated into a whole, so that the zero-clearance loosening deformation effect can be achieved, and the upper end surface of the damping rubber cushion is attached to and pressed against the supporting surface at the bottom of the machine tool, so that the damping effect is achieved.

The anti-loosening pressing sheet is designed to have the technical effect that annular teeth are tightly pressed on the foot body at the bottom of the machine tool through the locking screw rod to be engaged with the foot body so as to never loosen; the jackscrew is locked and pressed to the spiral column to lock the lifting support block, so that the lifting support block is prevented from loosening; the bottom of the spiral support is provided with a spherical concave surface and a spherical base convex surface which are matched with each other to play a role in automatically correcting the fixed angle of the foundation in the non-parallel environment of the ground and the machine tool, and the situation that the supporting foundation is not firmly contacted with the ground is prevented.

Drawings

FIG. 1 is a perspective view of a support foot with an anti-seismic helical structure.

Fig. 2 is a burst view of a screw mount and a spherical mount.

Fig. 3 is a schematic view of a non-level ground use installation.

The text labels shown in the figures are expressed as: 1. a spiral support; 2. a screw column; 3. lifting the supporting block; 4. damping rubber cushion; 5. locking the screw rod; 6. anti-loosening tabletting; 7. a jackscrew; 8. adjusting a screw; 9. a spherical base.

Description of the embodiments

Embodiments of the present utility model will be described in further detail below with reference to the drawings and examples; the following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1-3, the application relates to a support foot with an anti-vibration spiral structure, which comprises a spiral support 1 and a spiral column 2, wherein the spiral support 1 and the spiral column 2 are of an integrated structure, a lifting support block 3 is sleeved on the bolt column 2, a damping rubber cushion 4 is arranged on the lifting support block 3, a locking screw 5 is sleeved on the upper end thread of the spiral column 2, a locking pressing piece 6 is sleeved on the locking screw 5, annular teeth are arranged on the lower part of the locking pressing piece 6, a jackscrew 7 and an adjusting screw 8 are arranged on the side surface of the lifting support block 3, the jackscrew 7 is used for clamping the lifting support block 3 on the spiral column 2, a spherical base 9 is arranged on the lower part of the spiral support 1, and the upper part of the spherical base 9 is hemispherical and is arranged in a hemispherical notch on the lower part of the spiral support 1.

When the machine tool foot mounting block is specifically used, the height of the lifting support block 3 is adjusted, then the lifting support block 5 is locked through the jackscrew 7, then the machine tool foot mounting block is mounted on the damping foot pad 4, then the machine tool foot mounting block is locked through the locking screw 5 and the anti-loosening pressing piece 6, and further the mounting of the supporting foot and the machine tool foot is completed.

The screw column and the screw support are integrated into a whole, so that the zero-clearance loosening deformation effect can be achieved; the spiral structure and the spiral column are arranged in the lifting support block and can play a role in adjusting the upper and lower heights in a precise matching manner, a damping rubber cushion is arranged above the lifting support block, and the upper end surface of the damping rubber cushion is attached to and tightly pressed with the support surface at the bottom of the machine tool to play a role in absorbing vibration; a locking screw is arranged above the spiral column, and the anti-loosening pressing sheet is designed to have annular teeth which are tightly pressed on the foot body at the bottom of the machine tool through the locking screw to be engaged and never loosened; jackscrews are arranged in the three peripheral surfaces of the lifting support block, and are locked and pressed to the spiral column to lock the lifting support block, so that the lifting support block is prevented from loosening; adjusting screws are arranged on the other circumferential three sides of the lifting supporting block, and the adjusting screws are used for adjusting the height up and down by moving and rotating the lifting supporting block; the spherical base is arranged below the bottom of the spiral support, the spherical concave surface and the convex surface of the spherical base are designed at the bottom of the spiral support to mutually match, so that the ground and the machine tool are in non-parallel environment to automatically adjust the fixed angle of the foundation, and the situation that the supporting foundation is in contact with the ground and unstable is prevented.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed; many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (4)

1. The utility model provides a support foot with antidetonation spiral structure, includes spiral support (1) and screw column (2), its characterized in that, screw support (1) and screw column (2) are integrated into an organic whole structure, screw column (2) on cup joint lift supporting shoe (3), lift supporting shoe (3) on be provided with shock attenuation cushion (4), and the upper end screw thread plug bush of screw column (2) has locking screw rod (5).

2. The supporting foot with the anti-vibration spiral structure according to claim 1, wherein the locking screw (5) is sleeved with an anti-loosening pressing piece (6), and annular teeth are arranged at the lower part of the anti-loosening pressing piece (6).

3. The supporting foot with the anti-seismic spiral structure according to claim 1, wherein a jackscrew (7) and an adjusting screw (8) are arranged on the side face of the lifting supporting block (3), and the jackscrew (7) is used for clamping the lifting supporting block (3) on the spiral column (2).

4. A supporting foot with shock-resistant screw structure according to claim 1, characterized in that the lower part of the screw support (1) is provided with a spherical base (9), the upper part of the spherical base (9) is hemispherical and is fitted into a hemispherical recess in the lower part of the screw support (1).