KR200436418Y1 - Jig for Spindle Pressure - Google Patents

Abstract

The present invention improves the pressing jig for applying a force to the spindle to a new type to accurately grasp the mechanical rigidity of the spindle by using the bending of the spindle.

According to the pressurizing jig for measuring the rigidity of the spindle of the machine tool of the present invention, it is possible to accurately measure the rigidity even when the spindle is rotating at high speed, and it is possible to change the direction so that it is troublesome due to the overall readjustment installation of the pressing jig according to the direction of force This provides the convenience of measuring the rigidity of the spindle by instantly applying force in any direction without any lag or time delay.

The present invention is a hub tool coupled to the spindle, the upper surface of the worktable in the pressing jig for measuring machine tool spindle rigidity is detachably fixed to apply the force to the hub tool to measure the rigidity of the spindle, the lower side of the pressing jig The base is provided with a fastening screw to be detachably fixed while being stably placed on the worktable; A shaft disposed vertically by a predetermined height while being coupled to the base to be rotatably inserted into the lower portion; A load cell fixed to the fastening form to be in close contact with the upper outer surface of the shaft and interlock with each other; A joint housing fastened and fixed to the load cell corresponding to the shaft, and having a joint inserted into the joint to be exposed to one side; A press jig for measuring machine tool spindle stiffness, which is correspondingly coupled to a coupling protrusion protruding to one side of the joint, is composed of a bearing housing in which a bearing is coupled therein so as to apply a force even during rotation of a hub tool.

Factory, machine, rigidity, spindle, bending, measuring, jig, shock absorbing, shock, absorption, force

Description

Jig for Spindle Pressure for Measuring Machine Tool Spindle Rigidity

1 is a view schematically showing a state of measuring the rigidity of the spindle using a general pressing jig.

2 is a view showing a state of measuring the rigidity of the spindle using the pressure jig of the present invention.

Figure 3a is a plan view showing the Figure 2, Figure 3b is a plan view showing a state in which the force applied in any direction by rotating the pressing jig of the present invention.

<Explanation of symbols for the main parts of the drawings>

10 spindle 12 hub tool

14: working table 16,30: pressure jig

18: pressure projection 20: stiffness measuring system

32,46,50,56: fastening member 34: base

36: guide ball 38: shaft

40: guide member 42: coupling portion

44: lower step 48: shaft cap

52: upper step 54: load cell

58: tightening housing 60: fastening bolt

62: coupling groove 64: joint

66 disc shaped buffer member 68 shaft portion

70: engaging projection 72: bearing

74: bearing housing

The present invention relates to a pressurizing jig for measuring machine tool spindle rigidity, and more specifically, to accurately measure the rigidity even when the spindle is rotating at high speed, and the direction can be changed, and the overall readjustment of the pressing jig according to the direction in which the force is applied. It is possible to measure the rigidity of the spindle by immediately applying force in any direction without installation.

In general, the hub tool 12 is coupled to the spindle 10 of the machine tool in order to determine the degree of rigidity that the spindle resists deformation when applying external pressure to the spindle provided in the machine tool. The press jig 16 is firmly fixed to the upper surface of the work table 14 provided in the machine tool. At this time, the pressing protrusion 16 provided on one side of the pressing jig is aligned with the hub tool 12 so that the pressing direction of the force is positioned to have straightness.

When positioned as above, the operator artificially pushes the work table 14 to apply a force in a state in which the pressing projection 18 of the pressing jig 16 is in close contact with the hub tool 12, the spindle 10 by the force By measuring the degree of mechanical stiffness using the deflection of), it helps the worker in thread processing.

For reference, one side of the spindle 10 is disposed to measure the conventional stiffness measurement system 20 which is generally used to display the rigidity as a numerical value.

However, when the pressing jig 16 is fixed to the work table 14 as shown in FIG. 1, the pressing protrusion 18 of the pressing jig 16 exerts a force only in a single direction by a fixing structure facing in one direction. At this time, if the force is to be applied in any other direction as necessary, it is necessary to disassemble from the work table 14 and install it again in any other direction to apply the force.

Accordingly, the installation time according to the re-installation of the pressure jig 16 takes time, hassle caused by disassembly and assembly, there was a lot of inconvenience in measuring the rigidity.

In addition, it is difficult to measure the rigidity while the spindle 10 is rotating. Because, when the pressing projection 18 of the pressing jig 16 is in close contact with the outer surface of the hub tool 12 to be rotated in conjunction with the spindle 10, the friction is generated so severe that it is unstable to apply a force, at the same time Since the phenomenon of pushing down the jig 16 is unstable to apply more force, there is a problem that it is impossible to measure the rigidity.

The present invention is designed to solve the above problems, it is possible to accurately measure the stiffness even during the high speed rotation of the spindle, and the direction can be changed according to the direction of the force to apply the force immediately in any direction spindle The purpose is to allow the stiffness to be measured.

The present invention for achieving the above object, the hub tool is coupled to the spindle, the upper surface of the worktable for measuring the rigidity of the machine tool spindle is detachably fixed so as to measure the rigidity of the spindle by applying a force to the hub tool In the pressurizing jig, the lower part of the pressurizing jig and the base is provided with a fastening screw to be detachably fixed while being placed on the worktable; A shaft disposed vertically by a predetermined height while being coupled to the base to be rotatably inserted into the lower portion; A load cell fixed to the fastening form to be in close contact with the upper outer surface of the shaft and interlock with each other; A joint housing fastened and fixed to the load cell corresponding to the shaft, and having a joint inserted into the joint to be exposed to one side; There is a technical feature in the pressurizing jig for measuring machine tool spindle rigidity, which corresponds to a coupling protrusion protruding from one side of the joint, and is composed of a bearing housing in which a bearing is coupled therein so as to apply a force even during rotation of a hub tool.

In addition, a hollow guide member is placed on the upper surface of the base so as to completely cover the outer circumferential surface of the shaft by a predetermined height and is fixed to the base; A shaft cap penetrating the shaft is placed on the upper surface of the guide member and fixed to the upper surface of the guide member; The upper stepped portion is formed in the upper predetermined portion of the shaft to be in close contact with the bottom surface of the shaft cap, so that the structure does not escape upward from the base and the guide member while guiding the shaft during rotation, so as not to shake Would be desirable.

In addition, the above structure between the joint housing and the joint is a disk-type shock absorbing member is arranged in the form of being penetrated through the shaft portion of the joint, it is preferable that the structure so that the physical impact and shock generated when applying a force to absorb the buffer.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a view showing a state of measuring the rigidity of the spindle using the pressing jig of the present invention, Figure 3a is a plan view showing the Figure 2, Figure 3b is to rotate the pressing jig of the present invention to force in any direction This is a plan view showing how to apply. In addition, the same components as in FIG. 1 are given the same reference numerals to avoid redundant description, and only different parts will be described.

Pressing jig for measuring the rigidity of the machine tool spindle of the present invention is shown in Figures 2 and 3a and 3b.

The lower portion of the pressing jig 30 according to the present invention is provided with a fastening member 32 at each corner portion so that the pressing jig 30 can be stably placed on the work table 14 of the machine tool. The base 34 is arranged, and a guide hole 36 is formed in the center of the base 34. The base 34 also serves to support and fix the shaft 38 and the guide member 40 which will be described later.

In the guide hole 36 formed at the center of the base 34, the coupling part 42 formed at the lower portion of the shaft 38 is rotatably inserted and disposed in the vertical direction, and formed at the coupling part 42. Lower stepped portion 44 is coupled in the form of being placed on the upper surface of the base (34).

In addition, a hollow guide member 40 is placed on the upper surface of the base 34 to cover all of the shaft 38 by a predetermined height, and is fixed in a fastening form through the base 34 and the fastening member 46. It provides a function that can rotate stably without shaking.

The shaft cap 48 is placed on the upper surface of the guide member 40 so as to penetrate the shaft, and is fixed in a fastening form through the guide member 40 and the fastening member 50. At this time, the upper stepped portion 52 formed at an upper predetermined portion of the shaft 38 is caught in a state of being in close contact with the bottom surface of the shaft cap 48 so that the shaft 38 has a base 34 and a guide member ( The structure does not escape from 40).

A portion of the lower end of the load-cell 54 overlaps with each other and is fixed by the fastening member 56 to one side of the upper end of the shaft 38 exposed from the cap 48 of the shaft. Such a load cell 54 exhibits a frame function of supporting the joining housing 58 described later.

The joint housing 58 is fixed to the upper side of the load cell 54 corresponding to the shaft 38 by the fastening bolt 60 and connected to interlock with each other. The engaging groove 62 is formed in the lateral direction corresponding to 38. The coupling groove 62 is inserted in a state in which the part 64 is partially exposed and fastened and fixed by the fastening bolt 60.

 The disk-shaped shock absorbing member 66 is disposed between the joint housing 58 and the joint 64 in a state where the disk-shaped shock absorbing member 66 penetrates through the shaft portion 68 of the joint 64. 64) and the disk-type buffer member 66 to absorb and absorb the shock transmitted by excessively instantaneous shock or physical collision, and the pressure jig 30 and the spindle 10 breakage by such a buffer absorption function It will prevent the occurrence.

Since the disk-type shock absorbing member 66 used here is applied to a conventional one, a description of a specific structure is omitted, and if the shock-absorbing absorbing function as described above can be exerted, even if the disk-shaped shock absorbing member 66 is not provided. Any buffer member may be used.

In addition, a bearing housing 74 having the bearing 72 coupled therein is fixedly coupled to the coupling protrusion 70 protruding to one side of the joint 64. However, the bearing housing 74 does not need to be limited to a structure that fixes the fitting housing. This is just one example for easily explaining the present invention, the bearing housing 74 of the joint 64 may be connected to each other by a fastening means for a firm fixing, or to be fixed by welding or other coupling means Could be

When measuring the rigidity of the spindle by using the pressure jig for measuring the machine tool spindle rigidity of the present invention configured as described above, as shown in Figure 3a, the hub tool 12 is coupled to the spindle 10 of the machine tool as in the prior art In addition, the pressing jig 30 is stably and firmly fixed to the upper surface of the work table 14 by using the fastening member 32 provided in the base 34. At this time, the pressing jig 30 is placed in a straight line between the direction in which the force is applied and the hub tool 12 so that the pressing direction of the force has a straightness.

When the pressing jig 30 is positioned as described above, the pressure jig 30 is placed in the bearing 72 of the pressing jig 30 so as to penetrate the hub tool 12 of the spindle 10, and then the worker works. The table 14 is pushed in the direction of the hub tool 12 to apply a force with the bearing 72 inner surface of the pressing jig 30 being in close contact with the hub tool 12, and the force of the spindle 10 Through the bending, the rigidity measuring system 20 checks the mechanical rigidity.

In addition, in order to change the direction of applying the force, as shown in Figure 3b the bearing housing 74 is connected to enable the rotation by the rotation structure of the shaft 38, so as to disassemble and reinstall as in the prior art Immediate switching adjustments without the hassle or time lag can provide convenience and speed for measurement.

In addition, when the X and Y axes are formed at right angles, when both sides apply a force in an imaginary C axis direction of 45 °, the applied force is divided into two directions by acting in the X and Y axis directions. It will be apparent that all of the deflections can also be measured.

Therefore, when the pressure jig for measuring the rigidity of the machine tool spindle of the present invention is used, the force without the hassle and time delay due to disassembly and reassembly of the pressure jig 16 as in the prior art when adjusting the adjustment in any direction. Arbitrary switching adjustments to the direction of the application are instantaneous, providing quick and easy measurements.

In addition, when the pressure jig for measuring the rigidity of the machine tool spindle of the present invention is used, the disk-type shock absorbing member 66 is provided, and thus, the pressure jig ( It is possible to prevent the breakage of the 30 and the spindle 10.

In addition, when the pressure jig for measuring the rigidity of the machine tool spindle of the present invention is used, even if the hub tool 12 rotates at high speed due to the rotation of the spindle 10, the bearing 72 for applying the force is the hub tool 12. Since it is interlocked with and rotated, it is possible to stably apply the force without causing severe friction and pushing down the pressure jig 30 at the same time as in the prior art. Because of the measurement conditions, it is possible to increase the reliability of the data for the stiffness measurement.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Various modifications and variations can be made within the equivalent scope of the utility model registration claims to be described.

As described above, by improving the pressing jig that applies the force to the spindle to a new type of structure to accurately measure the mechanical rigidity by measuring the bending of the present invention, the arbitrary change of the adjustment of the direction in which the force is applied immediately You can expect the effect to help you measure quickly and easily.

In addition, when the pressure jig of the present invention is used, a disk-type shock absorbing member is provided between the joint and the joint housing, and the shock jig and the impact caused by excessive force or the impact by physical collision are absorbed and absorbed. The effect of preventing the breakage of the spindle can be expected.

Claims (3)

In the pressure jig for measuring machine tool spindle rigidity, the hub tool is coupled to the spindle, and the upper surface of the worktable is detachably fixed so as to measure the rigidity of the spindle by applying force to the hub tool. A base having a fastening screw below the pressing jig so as to be stably placed on a work table and detachably fixed thereto; A shaft disposed vertically by a predetermined height while being coupled to the base to be rotatably inserted into the lower portion; A load cell fixed to the fastening form to be in close contact with the upper outer surface of the shaft and interlock with each other; A joint housing fastened and fixed to the load cell corresponding to the shaft, and having a joint inserted into the joint to be exposed to one side; The jig for machine tool spindle stiffness measurement, corresponding to the coupling projection protruding to one side of the joint, consisting of a bearing housing coupled to the bearing so as to apply a force even during the rotation of the hub tool. The method of claim 1, A hollow guide member is placed on the upper surface of the base to cover the outer circumferential surface of the shaft by a predetermined height and fixed to the base; A shaft cap penetrating the shaft is placed on the upper surface of the guide member and fixed to the upper surface of the guide member; An upper stepped portion is formed in the upper predetermined portion of the shaft to be in close contact with the bottom surface of the shaft cap, so that the shaft does not escape upward from the base and the guide member while guiding the shaft so as not to shake during rotation. Press jig for measuring machine tool spindle rigidity. The method of claim 1, The disk-type shock absorbing member is disposed between the joint housing and the joint so as to penetrate through the shaft portion of the joint, so that the physical impact and shock generated when applying a force can be absorbed and absorbed. Pressurized jig.

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