KR200466285Y1 - Spindle structure with bearing controlling apparatus - Google Patents

Abstract

The present invention relates to a spindle structure provided with a device for restraining in one direction so that a bearing for a high speed spindle used in a machine tool or the like can receive a preload.
Spindle structure with a bearing restraint device according to the present invention, the case 10 to form an appearance; A fixing bush 20 provided inside the case 10 and formed in a cylindrical shape and fixed to an inner surface of the case 10 integrally; A ball bush (30) provided inside the fixing bush (20) and having a plurality of balls (32) inserted at equal intervals; A bearing (40) provided at an inner central portion of the case (10) and supporting the inner spindle axis to be rotatable; It is installed to be operable from the outside of the case 10, and consists of a restraining device 100 forcing the bearing 40 to receive a force to one side. According to the present invention, there is an advantage that the processing accuracy is maintained even when used for a long time.

Description

Spindle structure with bearing control apparatus

The present invention relates to a spindle structure provided with a device for restraining in one direction so that a bearing for a high speed spindle used in a machine tool or the like may receive a preload. That is, the present invention relates to a spindle structure for solving the problem caused by the play of the bearing by freely constraining the bearing in one direction from the outside.

Generally, a spindle for a machine tool is provided with a bearing therein. Therefore, when the spindle is used for a long time, play occurs in the bearing due to wear, etc., and thus, there is a problem in that precise machining becomes difficult.

Therefore, in recent years, a configuration for giving a preload by applying a force in one direction to the bearing has emerged. That is, the compression spring is provided with a force applied in one direction to the inside of the spindle, so that the compression spring directly presses the bearing.

However, in such a structure, since a compression spring for applying a force in one direction is provided inside the spindle, it is impossible to adjust the preload using a spring during use, and a preload of a predetermined predetermined magnitude is continuously applied. Therefore, in order to adjust or change the preload, it is difficult to disassemble the spindle and replace or repair the tension with another compression spring.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide a spindle structure having a bearing restraining device which is always preloaded to a bearing provided inside the spindle.

Another object of the present invention is to provide a spindle structure equipped with a bearing restraint device that can adjust the pressure applied to the inner bearing from the outside, and can freely adjust the restraint pressure applied to the bearing during the initial use.

Spindle structure is provided with a bearing restraint device according to the present invention for achieving the object as described above, and a case forming an appearance; A fixing bush provided inside the case and formed in a cylindrical shape and fixed to an inner surface of the case; A ball bush provided inside the fixing bush and inserted with a plurality of balls at equal intervals; A bearing provided at an inner central portion of the case and supporting the inner spindle shaft to be rotatable; A spring cover which is provided on one side of the ball bush and serves as a power source for receiving the force in one direction, and is provided to be spaced apart from each other on the left and right of the spring member to surround the outer side of the bearing and have a symmetrical shape. A cover, a force pin that is in close contact with the outer surface of the left cover and pushes the left cover to one side, and a transmission member that transmits the compressive force of the spring member applied to the force pin to the bearing; It is installed to be operable, and the restraining device forcing the bearing to be forced to one side; characterized in that it comprises a.

One end of the outer surface of the transmission member is formed to protrude outwardly the transmission jaw to which the force pin is mounted, and one end of the inner surface of the transmission member is formed to protrude inwardly the engaging jaw contacting one end of the bearing; Fastening grooves for screwing the force pin is formed in the transfer jaw through the left and right; One end of the force pin is formed so that the contact protrusion in contact with the left cover is protruded to one side, the other end of the force pin is formed so that the wrench groove in which the hexagon wrench is inserted inward.

On the side of the transfer member, the oil sphere from which oil is introduced from the outside is formed to protrude to one side; An oil passage is formed inside the transfer member to guide oil introduced from the oil sphere to the bearing.

In the spindle structure with a bearing restraint device according to the present invention, a preload is always applied to a bearing provided in the spindle. Therefore, even when a play occurs between the bearings due to prolonged use or external shock (vibration), the bearing adheres to the correct position.

In addition, in the present invention, it is configured to be able to control the internal compression spring from the outside. That is, the user can easily adjust the preload applied to the internal bearing by a simple operation of rotating the forced pin with a hexagon wrench. Therefore, the preload adjustment applied to the bearings at any time during the initial setting, as well as during use, can be adjusted, so that the ease of use is improved and the work efficiency is increased.

In addition, in the present invention, a ball bush in which a plurality of balls (ball) is built in the outer side of the bearing is further provided. Therefore, in the case where heat is generated in the bearing and expansion and contraction occur, the ball bush acts as a buffer, so that the rotational accuracy of the spindle is more accurately maintained.

1 is a partial cutaway perspective view showing the configuration of a preferred embodiment of a spindle structure provided with a bearing restraint device according to the present invention.
FIG. 2 is an enlarged view of a portion 'A' of FIG. 1.
Figure 3 is a partial cutaway perspective view for explaining the use state of the spindle structure with a bearing restraint device according to the present invention.

Hereinafter, a preferred embodiment of a spindle structure provided with a bearing restraint device according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 illustrate an embodiment of a spindle structure with a bearing restraint according to the present invention in a partially cutaway perspective view and a partially enlarged view.

As shown in these figures, the spindle structure provided with a bearing restraint device according to the present invention, the case 10 to form the appearance, and the fixing bush 20 is formed in a cylindrical shape integrally fixed to the inner surface of the case 10 ), A ball bush 30 in which a plurality of balls 32 are inserted at equal intervals, a bearing 40 supporting the inner spindle shaft to be rotatable, and the bearing 40 being forced to one side. It is composed of a restraining device 100 and the like to force receiving.

The case 10, as shown, is made of a cylindrical shape having a predetermined thickness, the inside of the case 10 is provided with a plurality of parts including a bearing (40).

The fixing bush 20 is provided inside the case 10, and the fixing bush 20 also has a cylindrical shape like the case 10.

In addition, the ball bush 30 is further provided inside the fixing bush 20, and the ball bush 30 is provided with a plurality of balls 32 at equal intervals.

A plurality of balls 32 provided in the ball bush 30 is rotatably mounted to guide the left and right flow of the transmission member 140 to be described below more smoothly. Therefore, even when heat is generated in the bearing 40 due to the long time use of the spindle, the transfer member 140 is smoothly moved left and right. That is, even when the volume of the bearing 40 and the transmission member 140 is expanded due to heat generation, the ball 32 provided in the ball bush 30 plays a buffer role, so that the transmission member 140 The left and right flows smoothly.

The bearing 40 is provided at an inner central portion of the case 10. That is, the bearing 40 is provided to be spaced inside the ball bush 30. The bearing 40 is more preferably made of an angular contact ball bearing as shown.

Therefore, such a bearing 40 is composed of an inner angular ball 46, an outer ring 42, an inner ring 44, and the like that surround the outside and the inside of the angular ball 46. Therefore, the transmission member 140 to be described below is in contact with the outer ring 42 of the bearing 40 to apply a force to the left.

The restraint device 100 is installed to be operable from the outside of the case 10 so that the bearing 40 is pushed to receive a force to the left.

Looking in more detail, the restraining device 100 is a spring member 110 which is a power source for the bearing 40 to receive a force in one direction, and the spring member 110 is provided spaced apart from each other on the left and right of the bearing The left cover 120 and the right cover 122 surrounding the outside of the 40, a force pin 130 for pushing the left cover 120 to the right, and the spring member applied to the force pin 130 ( It consists of a transmission member 140 for transmitting the compression force of the 110 to the bearing (40).

The spring member 110, as shown, made of a compression spring, is located on the left side of the ball bush (30). The spring member 110 is a source of the force to push the bearing 40 to the left by the compression force of the spring.

Left and right sides of the spring member 110 are provided with a left cover 120 and a right cover 122 symmetrical to each other. The left cover 120 has a cylindrical shape in which the left side is shielded and the right side is opened as shown, and surrounds the left side of the spring member 110. In addition, the right cover 122 has a cylindrical shape in which the right side is shielded and the left side is opened, and surrounds the right side of the spring member 110.

The left cover 120 and the right cover 122 are spaced apart from each other to have a predetermined interval. The right end of the right cover 122 is in contact with the fixing bush 20 as shown, and the left end of the left cover 120 is in contact with the force pin 130.

The force pin 130, as shown, is in close contact with the left outer surface of the left cover 120 to push the left cover 120 to the right.

Looking in more detail, the right end of the force pin 130, the contact protrusion 132 in contact with the left cover 120 is formed to protrude to the right. That is, as shown, the contact pin 132 of a predetermined size protrudes to the right side of the force pin 130, it is in direct contact with the outer surface of the left cover 120.

At the left end of the steel pin 130, the wrench groove 134 into which the hexagon wrench is inserted is formed to be recessed inwardly (right). That is, the force pin 130 is configured to be rotated by the user from the outside, for this purpose, a wrench groove 134 of a predetermined size is formed.

The wrench groove 134, as shown, is formed to have a hexagonal cross section, it is configured to be inserted into the hexagon wrench. Hex wrench (allen wrench, 六 角) is a tool that is easy to rotate the hexagonal bolts, because it is a commonly used mechanism, detailed description thereof will be omitted here.

A thread is formed on the outer surface of the steel pin 130. Therefore, such a force pin 130 is screwed to the transmission jaw 142 of the transmission member 140 to be described below.

The transmission member 140 serves to guide the compression force of the spring member 110 to be transmitted to the bearing 40, and is formed in a cylindrical shape having a predetermined thickness as shown in the drawing.

Looking in more detail, the transmission member 140 is provided inside the ball bush (30). Therefore, the outer surface of the transfer member 140 is in contact with the ball 32 of the ball bush (30).

At one end of the outer surface of the transmission member 140, the transmission jaw 142 on which the force pin 130 is mounted is formed to protrude outward. That is, a transmission jaw 142 having a width of a predetermined size is formed to protrude outward (upper side in FIG. 1) at the left end of the outer circumferential surface of the transmission member 140.

The force pin 130 is mounted on the transmission jaw 142. That is, the fastening groove 146 is formed in the transmission jaw 142 penetrates from side to side, and the forced pin 130 is screwed to the fastening groove 146. Therefore, the fastening groove 146 is formed on the inner surface of the thread tab corresponding to the thread formed on the outer surface of the steel pin 130.

At one end of the inner surface of the transmission member 140, the locking step 144 in contact with one end of the bearing 40 is formed to protrude inward. That is, as illustrated, the locking jaw 144 of a predetermined size is formed to protrude inward at the right end of the inner surface of the transmission member 140.

Therefore, when the right end of the bearing 40 is supported by the locking jaw 144, and the compressive force of the spring member 110 is transmitted, the locking jaw 144 pushes the bearing 40 to the left. will be.

On the left side of the transfer member 140, the oil sphere 150 is introduced to protrude to the left side oil (oil) from the outside. That is, as shown, the oil sphere 150 of a predetermined size is formed on the left side of the transfer member 140, the oil sphere 150 is an oil (oil) flowing from the outside inside the transfer member 140 It will serve as a guide. Therefore, a pipe or the like for guiding oil is connected to the oil ball 150.

In addition, an oil passage 152 is formed inside the transfer member 140 to guide oil introduced from the oil sphere 150 to the bearing 40. That is, oil introduced from the oil sphere 150 should be supplied to the bearing 40 to serve as lubricating oil. Therefore, an oil passage 152 having a '-' shape (in FIG. 1) is formed in the transmission member 140 to guide the external oil into the bearing 40.

Hereinafter, with reference to Figure 3 with respect to the action of the spindle structure provided with a bearing restraint device of the present invention having the configuration as described above.

First, the user rotates the hex wrench from the outside into the wrench groove 134 of the forced pin 130. In this case, since the force pin 130 is screwed to the transmission member 140, when the force pin 130 is rotated, the force pin 130 flows to the left and right.

For example, when the force pin 130 is rotated clockwise (when viewed from the left side of FIG. 3), the force pin 130 moves forward to the right, and the force pin 130 is counterclockwise ( In the case of rotating to the left side of Figure 3) the forced pin 130 is retracted to the left.

First, the case in which the force pin 130 is rotated in the clockwise direction will be described. At this time, since the force pin 130 is moved to the right, the left cover 120 in contact with the contact protrusion 132 is pushed to the right.

In addition, since the right cover 122 is in close contact with the fixing bush 20 and stops, the left cover 120 and the right cover 122 may be moved by the repulsive force (compression force) of the spring member 110. Likewise, the force in the left and right directions is generated.

In this case, since the right cover 122 is fixed, the compression force of the spring member 110 pushes the left cover 120 to the left, and the compression force of the spring member 110 is reversed. Is passed to 130.

Therefore, since the force in the left direction transmitted to the force pin 130 is transmitted to the transmission member 140 which is screwed again, the force in the left direction such as an arrow acts on the transmission member 140.

The leftward force acting on the transmission member 140 thus acts on the bearing 40 and pushes the bearing 40 to the left. That is, the outer ring 42 of the bearing 40 in contact with the locking jaw 144 formed at the right end of the transmission member 140 is pushed by the locking jaw 144 to move to the left side. Therefore, the bearing 40 is continuously formed with a preload in the left direction.

On the contrary, when the forced pin 130 is rotated counterclockwise, the forced pin 130 is moved to the left. Therefore, in this case, the repulsive force (compression force) of the spring member 110 is relatively weak.

As such, when the force pin 130 rotates counterclockwise, and the repulsive force of the spring member 110 is weakened, such a relatively weakened force is applied to the bearing 40 through the transfer member 140. Is passed on. Therefore, the force in the left direction acting on the bearing 40 becomes relatively small.

As such, by rotating the force pin 130 from the outside, the amount of preload acting on the bearing 40 is adjusted. Therefore, when wear occurs in the bearing 40 due to long time use, the user can arbitrarily adjust the preload acting on the spring member 110 by tightening the force pin 130.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications will be possible to those skilled in the art based on the present invention.

For example, in the above embodiment, but the compression spring is used as an example of the spring member 110, it will be possible to use another member instead of such a compression spring. That is, as long as the repulsive force can be formed, other parts may be changed regardless of the type and shape.

In addition, in the above embodiment, the wrench groove 134 is formed on the left end of the force pin 130, but it is formed to use a hexagon wrench, of course, the configuration can be changed. That is, of course, other modifications are possible such that the bolt head is formed to protrude to the outside of the forced pin 130 to use a wrench or the like instead of using a hexagon wrench.

10. Case 20. Fixed bushing
30. Ball Bush 40. Bearing
100. Restraint device 110. Spring member
120. Left cover 122. Right cover
130. Force pin 140. Transmission member
150. Oil balls

Claims (3)

A case 10 forming an appearance;
A fixing bush 20 provided inside the case 10 and formed in a cylindrical shape and fixed to an inner surface of the case 10 integrally;
A ball bush (30) provided inside the fixing bush (20) and having a plurality of balls (32) inserted at equal intervals;
A bearing (40) provided at an inner central portion of the case (10) and supporting the inner spindle axis to be rotatable;
It is provided on one side of the ball bush 30 and the spring member 110 is a power source for receiving the force in one direction, the bearing 40, and the left and right of the spring member 110 are provided spaced apart from each other bearing 40 Left cover 120 and the right cover 122 and the outer cover of the symmetrical shape surrounding each other and the outer side of the left cover 120, the push pin 130 to push the left cover 120 to one side And, including a transmission member 140 for transmitting the compressive force of the spring member 110 applied to the force pin 130 to the bearing 40, is installed to be operable from the outside of the case 10 And a restraining device 100 for forcing the bearing 40 to be forced to one side;
At one end of the outer surface of the transmission member 140, the transmission jaw 142 on which the force pin 130 is mounted is formed to protrude outward, and at one end of the bearing 40 on one end of the inner surface of the transmission member 140. The engaging jaw 144 is formed to protrude inward;
A fastening groove 146 through which the force pin 130 is screwed is formed through the transmission jaw 142 from side to side;
One end of the force pin 130 is formed so that the contact protrusion 132 in contact with the left cover 120 is protruded to one side, the other end of the force pin 130 wrench groove 134 is inserted into the hexagon wrench. ) Is formed to be recessed inward; spindle structure with a bearing restraint characterized in that. The method of claim 1, wherein the side of the transfer member 140,
An oil sphere 150 into which oil is introduced from the outside is formed to protrude to one side;
Inside the transfer member 140,
And an oil flow path 152 for guiding oil flowing from the oil hole 150 to the bearing 40; delete

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