KR19980067527A - Expansion shaft - Google Patents

Abstract

It prevents the stiffness of the expansion shaft which requires a hollow pupil inside, and prevents the central part from bending even when the shaft is long, and prevents the trabble caused by air leakage. It prevents inclining laterally and fixes the annular or cylindrical member at a certain position of the expansion shaft with accurate and sufficient supporting force.

It has an entrance on the outer circumferential surface of the shaft 1 and has both sides inclined in a wide direction toward the bottom, and on both sides there is a long groove 2 in the axial direction with an angle symmetrical from the bottom and fitted into the groove 2. And a long rack 3 having a bottom inclined surface 3b formed of an elastic body having an angle of inclination less than the angle of both sides of the groove 2 is mounted on the surface of the shaft 1, and is placed in contact with the bottom of the shaft 2 from the end of the shaft 1 to the bottom of the groove 2. When the fluid flow passage 4 is installed and the guide passage 4 is interposed between the bottom of the groove 2 and the bottom of the bottom inclined surface 3b of the long lance 3, the angle of both sides of the bottom of the groove 2 and the bottom inclined surface when injecting the fluid The long rack 3 is stroked within the distance by the difference of the angle of 3b, and it returns itself by the elasticity of the bottom inclined surface 3b at the time of pressurized fluid discharge.

Description

Expansion Shaft

1 is a cross-sectional view of an expansion shaft that is equipped with an annular or cylindrical member showing an embodiment of the present invention.

2 is a schematic side cross-sectional view of an expansion shaft showing an embodiment of the present invention.

(A) (B) of FIG. 3 is operation explanatory drawing which showed embodiment of this invention.

* Description of the symbols for the main parts of the drawings *

1: expansion shaft 2: groove

2a: inclined braking surface 3: long rack

3a: Tip side 3b: Bottom inclined surface

3c: rear section 4: fluid guide passage

4a: fluid guide groove 4b: fluid inlet

a: annular or uncontrolled absence

The present invention, for example, in the equipment for manufacturing and processing metal, paper, plastic film, etc., when winding the material in the form of a roller, the outer surface of the shaft and the yellow or control phase member such as the core of the coil and roller Separetta desk, etc., when the coil is wound in a spiral or cylindrical member such as a guide device for winding the edge of the processing material when winding the coil and the roller or the roller is wound in multiple strands. When an enlarged, fixed or reduced loosened or cylindrical member such as a yellow or cylindrical member of a slitter or a knife of a splitter is squeezed to a rotating shaft, that is, a yellow or cylindrical member of these mounted on the outer periphery of the shaft is attached to the shaft. In expansion shafts used for fixing purposes, especially those connected to the outer circumferential surface of the shaft by long racks mounted on the outer circumferential surface of the shaft. Toward the inner circumferential surface of the cylinder-like member or the outside it relates to the hwangsang or cylinder-like member jeopseol in the radial pressure to the expansion chuksya tufted securing at a predetermined position of the outer peripheral surface of the tufted Shah.

In facilities for manufacturing and processing metals, papers, plastic films, etc., when winding their materials onto rollers, when fixing coils and cores on a rotating shaft, the edges of the processing materials when winding coils and rollers are aligned. Separetta desk or knife of the splitter is fixed to the rotating shaft when the coil is wound with a guide device or a plurality of strands for winding the coil. The splitter's knife and Separatadesk have a method of fastening the nut at the end of the shaft by inserting a spatula in the middle of them.However, when changing the knife and the disc, the knife and the Separatades and the Spesa are removed from the shaft. In order to solve this problem, it is very inconvenient and an expansion shaft with an axial expansion method called an air shaft is used.

The expansion shaft which consists of this air shaft is a hollow cylinder shape of the shaft, and the air tube into which the compressed air was injected is inserted in the axial direction of the hollow inside of the shaft. This air tube has a structure in which it is compressed by the injected air pressure. In addition, a plurality of long holes divided into short lengths are formed in the axial direction and the circumferential direction of the outer circumferential surface on the hollow cylinder of the shaft, and a short length is formed in each of the long holes. It is installed in the outer diameter direction.

Thus, each short rack on the outer circumferential surface of the expansion shaft is pushed outward by the tubing which is pressurized by air pressure as it is expanded by the air pressure of the tub inserted into the hollow of the expansion shaft. Fixing the mounted yellow or cylindrical member in a fixed position on the outer circumferential surface of the expansion shaft by radially pressing the inner circumferential surface of the annular or cylindrical member such as a ring and a core connected to the outer circumferential surface of the expansion shaft toward the outside It becomes the structure to say.

Therefore, there is a problem in the expansion shaft referred to as the air shaft described above.

(1) Since the shaft is hollow for inserting the air tube into the inside, and the pressing pieces called racks are arranged by installing a plurality of long holes toward the outer circumference of the hollow shaft, the bending of the shaft becomes large and the strength of the long shaft is required. Do not use.

(2) Even if the outer ring separator ring is placed near the end of a short rack, the enlargement operation may cause the ring to cross laterally, resulting in a bad dimension.

(3) Since many short racks are in contact with the outer surface of the air tubing inside the shaft and the expansion and contraction are reversed, the rubber tubing is frequently damaged and ruptures frequently. Alternatively, the tube may deform when the air is released from the tube, causing the short rack to fall inside the hollow shaft.

Their repair is not possible in the field due to the internal structure, there is a need for a return repair in the manufacturing plant.

(4) In connection with the above problems, in the case of an out-of-axis ring that exerts a large external force because of the use of low pressure compressed air in the air tube, there is an absurdity in which the ring crosses.

(5) Winding of paper and film There is an irrationality such as lack of holding power of the core and bending.

The present invention was devised to solve the problem according to the above problems, and its object is to require a hollow cavity inside and to prevent the rigidity of the expansion shaft from deteriorating and to prevent the central shaft from being long. There is no bend and the trouble caused by air leakage can be prevented and again, the circular or cylindrical member is prevented from rubbing or inclining a little laterally. It is to provide an expansion shaft that is fixed by.

In order to achieve the above object, the present invention has an entrance to the outer peripheral surface of the shaft and has both sides inclined in a wide direction toward the bottom, and long grooves are disposed in the axial direction in which the sides are symmetrical with the bottom. A long rack with a bottom inclined surface formed of an elastic body having an angle of inclination smaller than the angles of both sides below the groove is fitted to the groove and is provided with a slidable sliding surface on the surface of the shaft, and a fluid guide passage through the groove at the end of the shaft is provided. When the pressurized fluid is injected into the guide passage between the bottom of the groove and the bottom of the bottom inclined surface of the long rack, the long rack strokes within the distance by the difference between the angle of the bottom side of the groove and the angle of the bottom inclined surface. When the pressurized fluid is discharged, it is a means for returning itself by elasticity at the bottom inclined surface.

The present invention will be described in more detail according to embodiments of the invention described in the drawings.

1 is a cross-sectional view of an expansion shaft equipped with a yellow or cylindrical member. FIG. 2 is a schematic side cross-sectional view of the expansion shaft. FIG. 3 (A) (B) is an explanatory diagram showing an embodiment of the present invention.

According to the drawing, the expansion shaft 1 is a yellow image such as a ring connected to the outer circumferential surface of the shaft 1 by the long rack 3 in the axial direction interlocked with the groove 2 disposed at the same interval on the outer circumferential surface of the shaft 1. Further, the inner peripheral surface of the cylindrical member a is radially pressed toward the outside, and the attached yellow or cylindrical member a is fixed at a fixed position on the outer peripheral surface thereof.

The shaft 1 has a circular cross section, for example, and a plurality of grooves 2 having an entrance on the outer circumferential surface side of the circumference are formed at the same interval around the circumferential surface. Angular grooves 2 formed at equal intervals around the circumferential surface are formed long along the axial direction of the shaft 1. The length of each groove 2 in the axial direction is almost all except the ends of the shaft 1.

Each groove 2 is directed toward the central axis from the outer circumferential surface of the shaft 1, and a wide groove is formed at the entrance of the outer circumferential surface.

Each groove 2 has an inner side at right and left sides perpendicular to the axial direction.

The groove width inner side surfaces on the left and right sides of the groove 2 on the entrance and exit side of the outer peripheral surface of the double shaft 1 are formed in parallel toward the center side. The groove width inner side surfaces of the groove 2 on the left and right sides slide with the left and right sides of the long rack 3.

The inclined braking surfaces 2a which are inclined while being widened in the groove width directions on the left and right sides of the bottom side of the groove width inner side surfaces of the left and right grooves 2 are respectively formed.

The inclined braking surface 2a is elastically deformed to be in close contact with the bottom inclined surface 3b of the long rack 3 described later. Each groove 2 has a width length between the left and right inner side surfaces of the bottom side larger than the width length between the left and right inner side surfaces of the entrance and exit side, and in particular, the inclined braking surfaces 2a on the bottom side have a symmetrical shape.

In this manner, inside the groove 2, which has a wider bottom than the entrance side, long racks 3 are provided in the axial center direction, respectively.

The long rack 3 is a fluid pressure whose tip side 3a protrudes from the entrance side of the groove 2 to the outer peripheral surface side of the shaft 1, and is mounted on the outer peripheral surface of the shaft 1. For example, the inner peripheral surface of the yellow or cylindrical member a, such as a ring, is pressed and fixed to a fixed position.

The long rack 3 is formed in the shape of a straight line whose front end axis 3a is parallel to the left and right sides.

On the rear side of the long rack 3, the bottom inclined surface 3b is gradually widened with its left and right sides facing backward.

The long rack 3 and the bottom inclined surface 3b may be integrally formed or may be combined with each other. The bottom inclined surface 3b is made of an elastic material, and is elastically deformed by injection of a pressurized fluid to form an intimate structure of the inclined braking surface 2a of the electric groove 2.

Thus, the bottom inclined surface 3b is elastically deformed and closely supported to the inner surface, and the fluid which presses the rear end surface 3c of the bottom inclined surface 3b to the rear side of the long rack 3 is sealed to prevent leakage.

The rear side of the long rack 3 is symmetrically shaped by the bottom inclined surface 3b, but the inclination angle A at both ends of the bottom inclined surface 3b is slightly smaller than the inclination angle B of the inclined braking surface 2a of the electric groove 2. It is.

As a result, the long rack 3 is stroked within the distance L by the difference between the inclination angle B of the bottom side of the groove 2 and the inclination angle A of the bottom inclined surface 3b so that the tip shaft 3a emerges from the entrance of the groove 2. .

However, when the pressurized fluid is released and the long rack 3 is immersed in the groove 2, the pressing portion of the bottom inclined surface 3b has a gap L between the inclined braking surface 2a of the groove 2, and the rear portion of the bottom inclined surface 3b is a groove. It is in close contact with the inclined braking surface 2a of 2 to prevent the fluid from leaking. When the pressurized fluid is injected, the bottom inclined surface 3b is forced back to both side inclined braking surfaces 2a of the groove 2 according to the pressure to maintain the sealing.

As the fluid is pushed to the bottom of the groove 2 at the bottom inclined surface 3c of the long rack 3 toward the entrance side of the roll groove 2, the long rack 3 protrudes to the inner peripheral surface of the yellow or cylindrical member a to support the member a. do. When the fluid is discharged, the bottom inclined surface 3b is returned by itself by elasticity, and the long rack 3 is also buried in the expansion shaft 1 outer peripheral surface. Oil, water and air are used for this fluid, for example.

A fluid guide groove 4a is formed in the bottom of each groove 2 of the shaft 1 in the longitudinal direction, and each fluid inlet 4b of one end of the fluid guide passage 4 is connected to the fluid guide groove 4a of the bottom of each groove 2, respectively.

Each fluid inlet 4b at one end of the fluid guide passage 4 is radially branched at the center of the expansion shaft 1, and each fluid inlet 4b at each one end of the branched fluid guide passage 4 is a fluid at the bottom of each groove 2. It is connected to the guide groove 4a.

The other end side of the fluid guide passage 4 extends to one end side of the expansion shaft 1 and is connected to a fluid passage not shown. The fluid passage not shown in the drawings is connected to the pressure oil tank by inserting three strand cocks, for example, which are not shown in the external drawings.

Expansion and reduction of the expansion shaft 1 is performed by opening and closing the three-sided cock.

The fluid rear groove 4a at the bottom of each groove 2 is interlocked through the post inlet 4b and the fluid guide passage 4, and the enclosed fluid of the fluid guide groove 4a at the bottom of each groove 2 is fluid inlet 4b and the fluid guide passage 4 Through the same fluid pressure, the rear end surface 3c of the bottom inclined surface 3b of the long rack 3 in each groove 2 is pressed by the same fluid pressure.

Next, the effect | action according to the structure of embodiment of above-mentioned invention is demonstrated below.

The yellow shaft or cylindrical member a such as a ring is attached to the expansion shaft 1 at predetermined positions, respectively. At this time, each long rack 3 of the expansion shaft 1 is buried in the groove 2 at its tip side 3 and does not protrude from the outer circumferential surface of the expansion shaft 1.

Since the inner diameter of the yellow or cylindrical member a mounted on one expansion shaft 1 is slightly larger than the outer diameter of expansion shaft 1, the tip 3a of each long rack 3 does not protrude from the outer peripheral surface of expansion shaft 1. The fixed shaft 1 can be easily slided to the mounting position.

In this way, after the yellow or cylindrical member a is mounted at a predetermined mounting position, a fluid pressure pump or an air compressor not shown in the drawing installed outside the expansion shaft 1 is operated. When the fluid pressure pump or the air compressor is operated, the fluid is pumped into the fluid passage in a pressure tank not shown in the drawing and flows into the fluid induction groove 4a at the bottom of each groove 2 at each radially branched fluid inlet 4b.

When the fluid flows into the fluid guide groove 4a at the bottom of each groove 2, the rear end surface 3c of the bottom inclined surface 3b of the long rack 3 in each groove 2 is respectively pressed at the same pressure by this flowed fluid. Each long rack 3 starts moving while sliding toward the side of the groove 2 in close contact with the side of the groove 2.

At this time, both ends of the rear side of the large bottom inclined surface 3b of the large plate shape are closer to both ends of the rear side of the large inclined braking surface 2a of the groove 2 than the inclination angle A of the entire side of the bottom inclined surface 3b. Since the inclination angle B of the front side of the inclined braking surface 2a is large and there is a gap L between the front side of the bottom inclined surface 3b and the front side of the inclined braking surface 2a (see FIG. 3 (A)), the rear end surface 3C is a fluid. The bottom inclined surface 3b to be pressed by the center starts to deform in the center of the rear end surface 3c into an arc-shaped arc, and the whole side of the bottom inclined surface 3b is in close contact with the full side of the inclined braking surface 2a.

When the center of the rear end surface 3c of the bottom inclined surface 3b is deformed into an arc shape, the front surface of the elastically deformed bottom inclined surface 3b is extruded to the entrance side of the groove 2 as a whole and the front end side 3a of the long rack 3 is grooved. Protrudes outside from the entrance side of 2.

The front end side 3a of each long rack 3, which is extruded and moved toward the entrance side of the groove 2, protrudes from the inside of the groove 2 to the outside and is attached to the inner circumferential surface of the yellow or cylindrical member a mounted on the outer circumferential surface of the expansion shaft 1.

When the fluid pressure pump is operated again to increase the pressure of the fluid, all the sides of the bottom inclined surface 3b are deformed and completely adhered to the all sides of the inclined braking surface 2a. However, the inclination angle A and the inclined braking surface of all the sides of the bottom inclined surface 3b are inclined. The inclination angle B of all sides of 2a is matched, and the fluid leakage is prevented between the bottom inclined surface 3b and the inclined braking surface 2a.

In addition, the front end side 3a of each long rack 3 protrudes from the inside of the groove 2 to the outside again and presses the inner circumferential surface of the yellow or cylindrical member a radially outward from the inner center of the expansion shaft 1 to a certain position. Each annular or cylindrical member a mounted on the is fixed at that position.

At this time, since each long rack 3 is long in the axial direction of the expansion shaft 1, the end may be slid horizontally across the end of the yellow or cylindrical member a like the conventionally divided and short rack. Is not at all.

Moreover, this invention is not limited to embodiment of the said invention, It can change in the range which does not deviate from the mind of this invention.

According to the expansion shaft according to the present invention as described above in the above description, it is not necessary to be hollow, as the conventional tube is not inserted therein. As a result, the long shaft is not deteriorated in rigidity and thus the shaft is not deteriorated. Even in this long case, when the center portion is rotated without bending, the unreasonable rotation of the center portion does not occur.

And since air is not enclosed in the tube as in the prior art, there is no fear that the tub is broken and the air inside leaks. However, when the long rack is pressed by the fluid pressure, the bottom inclined surface faces in the wide direction toward the bottom of the groove. Since the elastically deformed contact with both inclined inner surfaces, it is possible to reliably prevent the high pressure fluid from leaking between the groove and the bottom inclined surface, and to prevent the trouble caused by the leakage of the fluid in advance.

In addition, since the long rack is long in the axial direction of the expansion shaft, when the rack divided into a plurality of short lengths in the axial direction in the conventional axial direction presses the yellow or cylindrical member, the yellow or cylindrical member is slightly transversed by the end of the rack. It is possible to fix the yellow or cylindrical member at a certain position of the expansion shaft without rubbing or being slightly inclined so as not to fix the annular or cylindrical member at a predetermined position.

As described above, the expansion shaft of the present invention uses a solid shaft, and thus can be used as a contraction shaft because of its axial strength and less shaking.

Moreover, since the long rack which runs in the longitudinal direction of an axis | shaft is used, the adhesiveness of the yellow or cylindrical member of an outer periphery is favorable.

Since it is a rod-shaped rack instead of a pressure tube, it has a long service life and can be exchanged and repaired in the field, and there is no fear of rupture, such as a tubing.

Claims (1)

It has an entrance and exit on the outer circumferential surface of the shaft and has both sides inclined in a wide direction toward the bottom, and long grooves are formed in the axial direction forming an angle symmetrically to both sides and the bottom, and fit into the groove. A long rack having a bottom inclined surface formed of an elastic body having an inclination angle smaller than the angles of both sides is installed on the surface of the shaft in a sliding manner, and a fluid guide passage from the end of the shaft to the bottom of the groove is installed. The long rack is stroked within a slight gap by the difference between the angle of the bottom side of the groove and the angle of the bottom inclined surface during pressure injection between the bottom of the groove and the bottom of the bottom inclined surface of the long rack through the passage. An expansion shaft characterized in that when the pressurized fluid is discharged, the bottom inclined surface is returned by itself with elasticity.