KR20230044390A - anti-vibration structure of CNC machine - Google Patents

Abstract

The present invention provides a vibration transfer prevention structure for a two-spindle machine tool, which comprises: a first spindle and a second spindle arranged symmetrically to each other; a gantry which transfers the material from the first spindle to the second spindle; a first support fixed to the first spindle to support the gantry; and a second support fixed to the second spindle and supporting the gantry. According to the present invention, as each support supporting the spindle is connected to a side auxiliary beam, a gap is formed between the support and the bed unit, and because a gap is formed between the bed units of both spindles, there is an advantage in that the transmission of vibration occurring when one spindle is operated to the other spindle is reduced, thereby improving the processing completeness of a workpiece.

Description

Anti-vibration structure of CNC machine

The present invention relates to an anti-vibration structure for preventing vibration generated from one spindle from being transmitted to the other spindle in the operation of a two-spindle machine tool equipped with two spindles.

As shown in FIG. 1, a general two-spindle machine tool has a first spindle 10 and a second spindle 20 arranged symmetrically with each other, and transfers the material from the first spindle 10 to the second spindle 20. It includes a gantry 30, an IN stocker for supplying materials, and an OUT stocker for storing processed materials.

According to this prior art, the material stored in the IN stocker is supplied to the first spindle 10 by the gantry 30, and the supplied material is first processed in the first spindle 10, and then the gantry 30 again The material is transferred to the second spindle 20 by and the material processed in the second spindle 20 is stored in the OUT stocker.

On the other hand, in this prior art, the first spintle 10 and the second spindle 20 are connected to each other, and the gantry 30 is the bed portion 12, 22 of each spindle 10, 20 Since it is supported by the supports 14 and 24 fixed to the ), the vibration generated during operation of the spindle 10 on one side travels to the spindle 20 on the other side through the supports 14 and 24 and the gantry 30. It is transmitted and affects each spindle (10) (20).

Therefore, according to the prior art, there is a problem in that unexpected defects occur due to the influence of vibration transmitted from the other spindle 20 to the workpiece processed by the spindle 10 on one side.

The present invention is to solve the above-mentioned problems, and at the same time as forming a gap between the bed part of each spindle and the support, a gap is also formed between each bed part of each spindle so that vibration between each spindle during operation An object of the present invention is to provide a structure for preventing vibration transition of a two-spindle machine tool that can prevent transition.

In order to achieve the above object, the structure for preventing vibration transition of a two-spindle machine tool according to the present invention includes a first spindle and a second spindle arranged symmetrically with each other, and a gen for transferring material from the first spindle to the second spindle. It includes a tree, a first supporter fixed to the first spindle to support the gantry, and a second supporter fixed to the second spindle to support the gantry.

In addition, it is connected to the first support and includes a side auxiliary beam fixed to the ground, and the first support is connected to the side auxiliary beam, and the support bracket at the lower end is connected to the upper surface of the bed of the first spindle. It is separated from and forms a gap.

In addition, it is connected to the second support and may include a side auxiliary beam fixed to the ground, and the second support is connected to the side auxiliary beam, and the support bracket at the lower end thereof is the bed part of the second spindle. It is spaced apart from the upper surface to form a gap.

Also, the bed portion of the first spindle and the bed portion of the second spindle are spaced apart from each other to form a gap.

The present invention may include a support pad detachably attached to the lower surface of the support bracket at the lower end of the first support and selectively interposed in the gap between the support bracket and the upper surface of the bed of the first spindle.

The present invention may include a support pad detachably attached to the lower surface of the support bracket at the lower end of the second support and selectively interposed in the gap between the support bracket and the upper surface of the bed of the second spindle.

The present invention may include a gap plate that is selectively fitted into a gap between the bed part of the first spindle and the bed part of the second spindle, and the gap plate is connected to the bed part of the first spindle. A plate portion having a thickness smaller than the width of the gap between the bed portions of the second spindle, and a plate portion formed at an upper end of the plate portion, the thickness of which is greater than the width of the gap between the bed portion of the first spindle and the bed portion of the second spindle. is made of a thick hooking end.

According to the present invention, since the support for supporting each spindle is connected to the side auxiliary beam, a gap is formed between the support and the bed part, and a gap is also formed between the bed parts of both spindles, so that the vibration generated during operation of one spindle is reduced to the other side There is an advantage in that the phenomenon transmitted to the spindle is reduced and the degree of completeness of the workpiece is improved.

Figure 1: A diagram showing the vibration transition state of a conventional two-spindle machine tool
Figure 2: A view showing a state in which side auxiliary beams are applied in the present invention
Figure 3: A view showing the shape of a side auxiliary beam applied to the present invention
Figure 4: A view showing the vibration transition prevention state in the state where the side auxiliary beam is applied to the present invention
Figure 5: A view showing a structure in which a gap is formed between bed parts of both spindles in the present invention
Figure 6: A view showing the configuration of the support pad applied to the present invention
Figure 7: A view showing a state in which the support pad is attached in the present invention
8: A view showing a state in which a gap plate is applied in the present invention
9: A view showing the configuration of a gap plate applied to the present invention

Hereinafter, specific details for the implementation of the present invention will be described in detail with reference to FIGS. 2 to 9 .

The structure for preventing vibration transition of a two-spindle machine tool according to the present invention includes a first spindle 10 and a second spindle 20 arranged symmetrically with each other, as shown in FIG.

A gantry 30 for transferring the material from the first spindle 10 to the second spindle 20;

A first support 14 fixed to the first bed portion 12 of the first spindle 10 to support the gantry 30;

A second support 24 fixed to the second bed portion 22 of the second spindle 20 to support the gantry 30;

It is connected to the first support 14 and includes a side auxiliary beam 40 fixed to the ground.

In the state in which the first support 14 is connected to the side auxiliary beam 40, the support bracket part 141 at the lower end is spaced apart from the upper surface of the first bed part 12 of the first spindle 10 to form a gap ( 14a).

As shown in FIG. 3, the side auxiliary beam 40 exemplarily connects a pair of post portions 42 and 42 and the both post portions 42 and 42 to increase structural strength by connecting a horizontal portion ( 44), and a side bracket portion 421 connected to the support 14 is provided on the side surface of each of the holding parts 42 and 42, and the lower end of the holding part 42 and 42 is anchored to the ground It may be made of a structure in which the bottom bracket portion 422 is formed.

According to the present invention, in a state in which the second support 24 is connected to the side auxiliary beam 40, the lower support bracket part is spaced apart from the upper surface of the second bed part 24 of the second spindle 20 to close the gap It may also be configured to achieve (drawing omitted).

In addition, the side auxiliary beam 40 may be configured to be connected to both the first support 14 and the second support 24, and even at this time, the lower end of the first support 14 and the second support 24 The support bracket portion of is configured to form a gap by being spaced apart from the upper surface of the first bed portion 12 of the first spindle 10 and the upper surface of the second bed portion 22 of the second spindle 20, respectively. (not shown)

Further, according to the present invention, the first bed portion 12 of the first spindle 10 and the second bed portion 22 of the second spindle 20 are spaced apart from each other to form a gap 12a. (See Fig. 5)

The operation of the present invention will be described as follows.

First, as shown in FIG. 4, when the side auxiliary beam 40 is connected to the first support 14, the first support 14 and the first bed portion 12 of the first spindle 10 Since are spaced apart from each other, vibration generated during operation of the first spindle 10 is not directly transferred from the first bed part 12 to the first support 14 .

Therefore, the vibration generated in the first spindle 10 is transferred to the second spindle 20 via the first support 14 and the gantry 30 and affects the operation of the second spindle 20. this will be greatly reduced.

Similarly, when the side auxiliary beam 40 is connected to the second support 24, the second support 24 and the second bed portion 24 of the second spindle 20 are spaced apart, so that the second Vibration generated during operation of the spindle 20 is not directly transferred from the second bed portion 22 to the second support 24, and vibration generated from the second spindle 20 is transmitted to the first spindle 10. Phenomenon affecting operation is greatly reduced. (Figure omitted)

When the side auxiliary beam 40 is connected to both the first support 14 and the second support 24, the vibration generated during operation of each spindle 10 and 20 affects each spindle 10 ( 20) The phenomenon of mutual transmission is greatly reduced. (Figure omitted)

Therefore, in the present invention, as a result, it can be seen that the configuration in which the side auxiliary beam 40 is connected to both the first support 14 and the second support 24 has the greatest vibration reduction effect.

However, if the side auxiliary beams 40 are connected to both supports 14 and 24 on both sides, the overall cost of manufacturing the device increases, so vibration may occur according to the operating characteristics of the spindles 10 and 20. If the side auxiliary beam 40 is connected only to the support 14 of any one spindle 10 having a large factor, it is possible to obtain an effective anti-vibration transition effect while minimizing cost increase factors.

In the present invention as described above, the side auxiliary beam 40 is applied after being transported and installed to a place of use after the manufacture of the machine tool is completed, so that vibration generated during operation of the machine tool is prevented from being transferred. do.

In addition, according to the present invention, as shown in FIG. 5, a gap 12a is formed between the first bed portion 12 of the first spindle 10 and the second bed portion 22 of the second spindle 20, thereby Vibration transmitted between both bed parts 12 and 22 is also reduced.

On the other hand, in the present invention, as shown in FIG. 6, when the side auxiliary beam 40 is connected to the first support 14, the support pad on the bottom surface of the support bracket portion 141 at the bottom of the first support 14 (5) may be detachably attached by a bolt coupling method or the like.

As shown in FIG. 7 , the support pad 5 serves to support the support 14 in the process of being applied after the machine tool is manufactured and transported to a place of use, and is removed after the machine tool is installed.

In addition, according to the present invention, as shown in FIGS. 8 and 9, the gap between the first bed portion 12 of the first spindle 10 and the second bed portion 22 of the second spindle 20 ( 12a) may be fitted with a gap plate 50, the gap plate 50 is the first bed portion 12 of the first spindle 10 and the second bed portion 12 of the second spindle 20 A plate part 52 whose thickness is thinner than the width of the gap 12a between the bed parts 22, and formed at the upper end of the plate part 52, and whose thickness is thicker than the width of the gap 12a. It consists of an end (54).

The gap plate 50 is applied after the machine tool is manufactured and transported to a place of use, and the plate part 52 forms a gap 12a between the bed parts 12 and 22 of the respective spindles 10 and 20. ), it prevents the phenomenon of collision between the bed parts 12 and 22 due to the gap 12a in the transfer process of the machine tool, and is removed after the installation of the machine tool is completed do.

10: first spindle 12: first bed part
14: first support 30: gantry
40: side auxiliary beam 50: gap plate

Claims (4)

A first spindle having a first bed part and a second spindle having a second bed part disposed symmetrically with each other, a gantry for transferring material from the first spindle to the second spindle, and fixed to the first spindle, the gen In a two-spindle machine tool including a first support for supporting a tree and a second support for supporting the gantry by being fixed to the second spindle,

It includes a side auxiliary beam connected to the first support and fixed to the ground and a side auxiliary beam connected to the second support and fixed to the ground,

The first support is connected to the side auxiliary beam, and the support bracket part of the lower end thereof is spaced apart from the upper surface of the first bed part of the first spindle to form a gap, and the second support is connected to the side auxiliary beam. The support bracket portion of the second spindle is spaced apart from the upper surface of the second bed portion to form a gap,

A support pad detachably attached to the bottom surface of the support bracket at the bottom of the first support and selectively interposed in the gap between the support bracket and the upper surface of the first bed of the first spindle, and a support at the bottom of the second support Support pad detachably attached to the bottom surface of the bracket unit and selectively interposed in the gap between the support bracket unit and the upper surface of the second bed unit of the second spindle
Vibration transition prevention structure of a two-spindle machine tool comprising a.
According to claim 1,
The first bed portion of the first spindle and the second bed portion of the second spindle are spaced apart from each other to form a gap
A structure for preventing vibration transition of a two-spindle machine tool, characterized by
According to claim 2,
Comprising a gap plate selectively fitted in the gap between the first bed portion of the first spindle and the second bed portion of the second spindle
A structure for preventing vibration transition of a two-spindle machine tool, characterized by
The method of claim 3, wherein the gap plate
a plate portion having a thickness thinner than a width of a gap between the second bed portion of the first spindle and the second bed portion of the second spindle;
A hooking end portion formed at an upper end of the plate portion and having a thickness greater than the width of the gap.
Vibration transition prevention structure of a two-spindle machine tool, characterized in that consisting of.

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