KR101299723B1 - Power locking apparatus for face to face fixing of elements precisely - Google Patents

Abstract

PURPOSE: A power locking device for bonding faces of precise components is provided to completely remove the joining tolerance between two components, thereby preventing damage on the components caused by shear force. CONSTITUTION: A power locking device (100) for bonding faces of precise components includes a through-hole (110), a recessed groove (120), an expansion sleeve (130), a pressing sleeve (140), a control bolt (160), and a push plate (170). The through-hole is formed on a first component (A). The recessed groove is formed on a second component (B) by being matched with the through-hole and includes a screw hole (122) on the center. The expansion sleeve is fitted into the through-hole and the recessed groove, and the diameter of the expansion sleeve is enlarged or reduced by an external force in a radial direction. The pressing sleeve is fitted into the tapered inner periphery of the expansion sleeve. The adjusting bolt is inserted into a fitting hole of the pressing sleeve and joined to the screw hole of the second component. The pushing plate is formed on the underside of a heat unit (164) of the upper side of the adjusting bolt to be integrated and closely adheres to the top surface of the pressing sleeve.

Description

POWER LOCKING APPARATUS FOR FACE TO FACE FIXING OF ELEMENTS PRECISELY}

The present invention relates to a power locking device for precisely fixing the relative position of two parts by surface joining, and more particularly, to completely eliminate the coupling tolerance between two plate-shaped parts using the principle of collet. The present invention relates to a power locking device for precision part surface joining, which is capable of precise positioning between two parts and precise control of relative position, and prevents part damage by strongly resisting shear force generated between two parts.

In general, the power lock is a power transmission element for transmitting power by fixing the shaft to the housing. As an example of such a conventional power lock, the "power lock and inner ring manufacturing method for power lock" of the Republic of Korea Patent Publication No. 10-1098255 is presented.

As shown in FIG. 1, the wedge portion 21 of the inner ring 20 is fitted into the hollow part 11 of the outer ring 10, and the bolt 30 is formed by the inner ring (FIG. 1). The inner ring 20 and the outer ring 10 are coupled by the bolt 30 by being fastened to the fastening hole 12 of the outer ring 10 through the bolt hole 26 formed in the flange portion 25 of the 20. When the fastened bolt 30 is tightened, the wedge portion 21 of the inner ring 20 is contracted and compressed to a shaft (not shown), and the outer ring 10 having the cutout 13 is expanded while the pulley, gear, It is compressed to a hollow portion of a driven means (not shown), such as a flywheel, a cam, and the like, so that the power of the shaft can be transmitted to the driven means.

Therefore, such a conventional power lock 1 is used to mount the shaft and the driven means to precisely fix the shaft and the driven means at the concentric position, and transmit the rotational force (torque) to process the shaft.

However, such a conventional power lock 1 has a limitation in that it cannot be used when it is necessary to contact and fix the surfaces of two components, rather than a component such as a shaft.

FIG. 2 shows the structure of a conventional bolt fixture 50 that is in contact with the surfaces of two components and secures them to each other.

Such a conventional bolt fixture 50, for example, if it is assumed that the two plate-like parts (A, B) to be bonded, the bolt diameter so that the bolt 60 penetrates through one plate-like part (A) The through-hole 70 is formed in the same shape, and the other plate-like part B is formed with a screw hole 80 screwed to the bolt 60 to form two plate-shaped parts A with the bolt 60. , B) are fixed by an interview.

That is, the through holes 70 and the bolt holes 80 of the two plate-shaped parts A and B coincide with each other, and then the bolt 60 is passed through the through-hole 70 of one plate-shaped part A. Insert the two bolts (60) into the threaded hole 80 of the other plate-like part (B) by joining the two plate-like parts (A, B) to each other.

However, such a conventional bolt fixture 50, when the force in the shear direction acts on the two plate-like parts (A, B), if there is a coupling tolerance (C), vibration or shock occurs and due to this cause It can also lead to breakage of (A, B).

That is, even when the inner diameter of the through-hole 70 of the sheet-shaped part A is manufactured to a size corresponding to the diameter of the bolt 60, the two plate-shaped parts (A, B) in use, the arrow in FIG. When the force in the shear direction as shown in Figure 3, the coupling tolerance (C) occurs between the through hole 70 and the bolt 60 of the sheet-like part (A), such a coupling tolerance (C) is The relative position between the two plate-shaped parts (A, B) cannot be maintained accurately, and fatigue breakage is caused by being vulnerable to the shear stress of the bolt 60 or the two plate-shaped parts (A, B) by external vibration or shock. Has the problem that results.

An object of the present invention is to solve the above-mentioned conventional problems, when the two parts are to be joined to the joint, it is possible to completely eliminate the coupling tolerance between the two parts, by the shear force generated between the two parts The present invention provides a power locking device for precision part joining to completely prevent damage to parts.

In addition, another object of the present invention is to improve the precision positioning between the two parts, the precise positioning between the two parts, the precise positioning between the two parts can be precision assembly between the two parts to improve precision In providing a locking device.

In order to achieve the above object, the present invention provides a device for joining two parts,

A circular through hole formed in the first part;

A circular recess formed in the second part in correspondence with the through hole, and a screw hole formed in the center of the recess;

An expansion sleeve in which a cylindrical outer circumferential surface is fitted over the through hole and a concave groove, a tapered inner circumferential surface is formed therein, and a longitudinal incision groove is formed to expand and contract a diameter by external force in a radial direction;

A pressurized sleeve having a tapered outer circumferential surface having a slope corresponding to the tapered inner circumferential surface of the expansion sleeve to be fitted to the tapered inner circumferential surface of the expansion sleeve, and having a fitting hole formed therein; And

And a adjusting bolt inserted into the fitting hole of the pressing sleeve and screwed to the screw hole of the second component, and a pressing plate integrally formed at a lower portion of the head to be in close contact with the upper end of the pressing sleeve. When screwing into the threaded hole of the part, the pressing plate pushes the pressure sleeve into the expansion sleeve to enlarge the diameter of the expansion sleeve, and the enlarged diameter of the expansion sleeve in the through hole of the first part and the concave groove of the second part. Provided is a power locking device for precision part joining, configured to remove the joining tolerance in order to join the first and second parts.

Preferably, in the present invention, the through hole of the first part and the concave groove of the second part have the same inner diameter, and the outer sleeve has the outer diameter corresponding to the through hole and the inner diameter of the concave groove. The tapered inner peripheral surface of the maximum inner diameter is formed on the upper side, the minimum outer diameter is formed on the lower side, the tapered outer peripheral surface of the pressing sleeve is formed the maximum outer diameter of the upper side, the minimum outer diameter is formed on the lower side, A tapered inner circumferential surface of the expansion sleeve and a tapered outer circumferential surface of the pressure sleeve provide a power locking device for precision part surface joining having the same slope as each other.

In addition, the present invention preferably the maximum outer diameter of the tapered outer peripheral surface of the pressing sleeve is larger than the maximum inner diameter of the tapered inner peripheral surface of the expansion sleeve, the minimum outer diameter of the tapered inner peripheral surface of the pressing sleeve It is formed to be larger than the minimum inner diameter to insert the tapered outer peripheral surface of the pressing sleeve to the tapered inner peripheral surface of the pressing sleeve provides a power locking device for precision parts interfacing the upper end of the pressing sleeve protrudes above the upper side of the expansion sleeve.

And the present invention preferably provides a power locking device for the precision part surface joining is made of a washer of the adjusting plate is fitted to the adjusting bolt, the diameter of the pressing sleeve is larger than the fitting hole.

In addition, the present invention preferably the first part and the second part is made of a plate-like part, or each made of cylindrical parts, the cylindrical second part is coaxial in the interior of the cylindrical first part (coaxial) It is inserted into a), and provides a power locking device for the precision component surface joining configured to couple the inner circumferential surface of the cylindrical first part and the outer circumferential surface of the cylindrical second part by surface joining.

According to the power locking device for precision part surface joining according to the present invention, the through hole of the first part and the concave groove of the second part coincide, and the expansion sleeve is fitted over the through hole and the concave groove, and the tapered inner peripheral surface of the expansion sleeve is provided. The pressure sleeve is inserted into the screw, and the adjusting bolt is screwed into the screw hole of the second part by inserting the adjusting bolt into the fitting hole of the pressure sleeve. In this process, the adjustment bolt is the pressure plate to enter the pressure sleeve into the expansion sleeve to enlarge the diameter of the expansion sleeve, the enlarged diameter of the expansion sleeve is coupled in the through hole of the first part and the concave groove of the second part The tolerances are eliminated so that the first and second parts are completely interviewed without engagement tolerances.

Therefore, according to the power locking device for precision surface joining according to the present invention, when joining two parts, it is possible to completely eliminate the coupling tolerance between the two parts, which is generated by the shear force generated between the two parts It is possible to completely prevent the breakage of the parts, and the precise positioning between the two parts and the precise relative position control are possible, so that an excellent effect can be obtained so that the precise assembly between the two parts is always possible.

1 is a perspective view and a cross-sectional view showing a power lock according to the prior art.
Fig. 2 is a cross-sectional view showing a bolt fixture for joining two plate members in accordance with the prior art, and is an explanatory view showing a state where a joining tolerance is generated.
Figure 3 is a cross-sectional view showing a power locking device for precision part surface joining according to the present invention.
Figure 4 is an enlarged explanatory view showing the detailed structure of the expansion sleeve, the pressing sleeve and the adjustment bolt provided in the power locking device for precision parts surface contact according to the present invention.
FIG. 5 is an explanatory view illustrating a process order of precisely joining two plate-shaped parts by using a power locking device for precision part joining according to the present invention.
FIG. 6 is an explanatory view in cross-sectional view showing a state in which the precision surface joining between the two plate-shaped components using the power locking device for precision surface joining according to the present invention without generating a joining tolerance.

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

As shown in FIG. 3, the power locking device 100 for precision part surface joining according to the present invention is an apparatus for precisely joining two plate-shaped parts A and B to each other.

The power locking device 100 for precision part surface joining according to the present invention includes a circular through hole 110 formed in the first part A. As shown in FIG.

And a circular concave groove 120 formed in the second part B in correspondence with the through hole 110, and a screw hole 122 formed in the center of the concave groove 120. Here, the through hole 110 of the first component A and the concave groove 120 of the second component B have the same inner diameter.

In addition, the power locking device for joining precision parts 100 according to the present invention includes an expansion sleeve 130 that is fitted over the through hole 110 and the concave groove 120, such an expansion sleeve 130 is shown in FIG. As shown in the enlarged view at 4, the through-hole 110 and the cylindrical outer peripheral surface 132 to be fitted into the recess 120 is provided, the inner tapered inner peripheral surface 134 is formed, and is cut in the longitudinal direction The groove 136 is formed to expand and contract the diameter by the external force in the radial direction.

In addition, the expansion sleeve 130 has an outer diameter that matches the through hole 110 and the inner diameter of the concave groove 120, and the tapered inner circumferential surface 134 of the expansion sleeve 130 has a maximum inner diameter at an upper side thereof. (d1) is formed and the minimum inner diameter d2 is formed in the lower side.

In addition, the power locking device 100 for precision surface joining according to the present invention includes a pressure sleeve 140 that is fitted in correspondence with the tapered inner circumferential surface 134 of the expansion sleeve 130.

As shown in FIG. 4 as an enlarged view, the pressure sleeve 140 forms an inclined tapered outer circumferential surface 142 corresponding to the tapered inner circumferential surface 134 of the expansion sleeve 130 so that the expansion sleeve ( It is fitted to the tapered inner peripheral surface 134 of 130, and the fitting hole 144 is formed therein.

In addition, the press sleeve 140 has a maximum outer diameter d3 of the tapered outer circumferential surface 142 formed at the upper side thereof, and a minimum outer diameter d4 formed at the lower side thereof.

The maximum outer diameter d3 of the tapered outer circumferential surface 142 of the pressing sleeve 140 is greater than the maximum inner diameter d1 of the tapered inner circumferential surface 134 of the expansion sleeve 130, and the pressing sleeve 140 ), The minimum outer diameter d4 of the tapered outer circumferential surface 142 is larger than the minimum inner diameter d2 of the tapered inner circumferential surface 134 of the expansion sleeve 130.

Through such a structure, when the tapered outer circumferential surface 142 is inserted into the tapered inner circumferential surface 134 of the expansion sleeve 130, the upper end of the pressure sleeve 140 is shown in FIG. 3. As described above, the upper side of the expansion sleeve 130 protrudes upward.

In addition, the power locking device 100 for the surface joining of precision parts according to the present invention includes an adjustment bolt 160 inserted into the fitting hole 144 of the pressure sleeve 140, and such an adjustment bolt 160 has a lower portion thereof. The screw portion 162 of the side is screwed into the screw hole 122 of the second component B, and the pressing plate 170 in close contact with the upper end of the pressing sleeve 140 at the lower portion of the upper head 164. ) Is a unitary structure.

As shown in FIG. 4 as an enlarged view, the adjusting bolt 160 has a structure in which the pressing plate 170 is integrally formed with the bolt body 166, or is made of a separate member from the bolt body 166. In this case, the control bolt 160 may be fitted with a washer having a diameter larger than that of the fitting hole 144 of the pressure sleeve 140.

The adjusting bolt 160 is screwed to the threaded hole 122 of the second part (B) of the lower screw portion 162 when the tightening operation, the pressing plate 170, the pressure sleeve 140, the expansion sleeve Push into the inside of 130 and expand the diameter of the expansion sleeve 130 in the radial direction.

In the power locking device 100 for precision part surface joining according to the present invention configured as described above, for example, the first component A and the second component B may be formed of a plate-shaped component. Alternatively, the first component A and the second component B may be formed of cylindrical components, respectively, and the second component B may be coaxially fitted inside the first component A, It can be used for the structure which couples the inner peripheral surface of the 1st component A and the outer peripheral surface of the 2nd component B by surface joining.

As shown in FIG. 5, the power locking device 100 for precision part surface joining according to the present invention does not allow the two iron plates of the first and second parts A and B not to slide at the correct positions with each other. In order to fix the roughly aligned through hole 110 of the first component (A) and the recessed groove (120) of the second component (B), the expansion sleeve 130 is first fitted.

Since the expansion sleeve 130 forms a longitudinal cutting groove 136 on one side like a collet and applies a force radially inward, the diameter thereof decreases, so that the through hole 110 of the first component A is reduced. It is easily inserted into the concave groove 120 of the second component (B).

The inside of the expansion sleeve 130 is given an angle of a predetermined angle through the tapered inner peripheral surface 134.

Next, a pressurized sleeve 140 having a tapered outer circumferential surface 142 that is equal to the angle of the tapered inner circumferential surface 134 of the expansion sleeve 130 is inserted into the expansion sleeve 130.

In this case, when the pressure sleeve 140 is pushed into the expansion sleeve 130, the expansion sleeve 130 opens to concave the through hole 110 and the second component B of the first component A. FIG. It is strongly adhered to the inner diameter side of the groove 120, and the position is fixed very precisely.

When the assembly of the expansion sleeve 130 and the pressure sleeve 140 is completed as described above, the adjustment bolt 160 is inserted into the pressure sleeve 140 to be tightened without tightening the pressure sleeve 140.

At this time, the adjustment bolt 160 is inserted into the fitting hole 144 of the pressure sleeve 140, the lower threaded portion 162 is screwed to the screw hole 122 of the second component (B).

In addition, when the adjusting bolt 160 is tightened, as shown in FIG. 6, the pressing plate 170 pushes the pressure sleeve 140 into the expansion sleeve 130 and enters the diameter of the expansion sleeve 130. Expand radially outward.

In this process, the outer circumferential surface of the expansion sleeve 130 is strongly adhered to the inner diameter side of the concave groove 120 of the through hole 110 of the first component A and the second component B, and eventually the expansion sleeve ( The engagement tolerance C formed between the outer circumferential surface of the 130 and the concave groove 120 of the second component B and the through hole 110 of the first component A is completely removed and the first component ( A) and the second component B are fixed in a very precise engagement position.

As described above, the power locking device 100 for precision surface joining according to the present invention is simple, but when the first and second components A and B are joined by the surface joining, the coupling tolerance C does not exist. Precise positioning between the first and second parts A and B is possible and has a particularly strong resistance to shear forces.

According to the power locking device 100 for precision surface joining according to the present invention as described above, the through hole 110 of the first component (A) and the concave groove (120) of the second component (B) to match, The expansion sleeve 130 is inserted through the through hole 110 and the concave groove 120, and the pressure sleeve 140 is inserted into the tapered inner circumferential surface 134 of the expansion sleeve 130. Insert the adjusting bolt 160 into the fitting hole 144 of the) and screwed to the screw hole 122 of the second component (B).

In this process, the adjustment bolt 160 press plate 170 to enter the pressure sleeve 140 into the expansion sleeve 130 to enlarge the diameter of the expansion sleeve 130, the expansion sleeve 130 The enlarged diameter completely removes the engagement tolerance C in the through hole 110 of the first component A and the concave groove 120 of the second component B, thereby allowing the first and second components A, B) are perfectly interviewed without a joining tolerance (C).

Therefore, according to the power locking device 100 for precision part surface joining according to the present invention, when the two parts (A, B) are to be joined, the joining tolerance (C) between the two parts (A, B) is perfectly. It is possible to eliminate the component damage caused by the shearing force generated between the two components (A, B), and to accurately position the two components (A, B) and precise control of relative position It is possible to obtain an excellent effect whereby precise assembly between the two parts A and B is always possible.

In addition, the present invention is the vibration or shock is transmitted from the outside during use, the adjustment bolt 160 is loosened backwards, or due to external causes the through hole 110 and the second component (B) of the first component (A) When the coupling tolerance (C) is newly generated in the concave groove 120 of the, it is possible to completely remove the coupling tolerance (C) by additionally tightening the adjustment bolt 160 again, thereby always providing two parts (A). Precise assembly between, B) becomes possible.

Although the present invention has been described in detail with reference to specific embodiments thereof with reference to the accompanying drawings, the present invention is not limited to such specific structures. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the following claims. However, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

1: conventional power lock 10: outer ring
11: hollow part 12: fastening hole
13: incision 20: inner ring
21: wedge portion 25: flange portion
26: bolt hole 30: bolt
50: conventional bolt fixture 60: bolt
70: through hole 80: screw hole
100: Power locking device for precision part interview
110: through hole 120: recessed groove
122: screw hole 130: expansion sleeve
132: cylindrical outer peripheral surface 134: tapered inner peripheral surface
136: incision groove 140: pressure sleeve
142: tapered outer peripheral surface 144: fitting hole
160: adjustment bolt 162: screw portion
164: head 166: bolt body
170: pressing plate A, B: parts
C: Combined Tolerance d1: Maximum Inner Diameter
d2: minimum inner diameter d3: maximum outer diameter
d4: minimum outer diameter

Claims (5)

In an apparatus for joining two parts,
A circular through hole formed in the first part;
A circular recess formed in the second part in correspondence with the through hole, and a screw hole formed in the center of the recess;
An expansion sleeve in which a cylindrical outer circumferential surface is fitted over the through hole and a concave groove, a tapered inner circumferential surface is formed therein, and a longitudinal incision groove is formed to expand and contract a diameter by external force in a radial direction;
A pressurized sleeve having a tapered outer circumferential surface having a slope corresponding to the tapered inner circumferential surface of the expansion sleeve to be fitted to the tapered inner circumferential surface of the expansion sleeve, and having a fitting hole formed therein; And
And a adjusting bolt inserted into the fitting hole of the pressing sleeve and screwed to the screw hole of the second component, and a pressing plate integrally formed at a lower portion of the head to be in close contact with the upper end of the pressing sleeve. When screwing into the threaded hole of the part, the pressing plate pushes the pressure sleeve into the expansion sleeve to enlarge the diameter of the expansion sleeve, and the enlarged diameter of the expansion sleeve in the through hole of the first part and the concave groove of the second part. The power locking device for precision component joining, characterized in that configured to join the first and second parts by removing the coupling tolerance. According to claim 1, wherein the through-hole of the first component and the concave groove of the second component is the same inner diameter, the expansion sleeve is the outer diameter of the through hole and the inner diameter of the concave groove, the expansion sleeve of the The tapered inner circumferential surface is formed with a maximum inner diameter at the upper side, a minimum outer diameter is formed at the lower side, and the tapered outer circumferential surface of the pressing sleeve is formed with a maximum outer diameter at the upper side, and a minimum outer diameter is formed at the lower side, and the expansion The tapered inner circumferential surface of the sleeve and the tapered outer circumferential surface of the pressurized sleeve have the same inclination with each other. 3. The maximum outer diameter of the tapered outer circumferential surface of the pressing sleeve is larger than the maximum inner diameter of the tapered inner circumferential surface of the expansion sleeve, and the minimum outer diameter of the tapered outer circumferential surface of the pressing sleeve is the minimum of the tapered inner circumferential surface of the expansion sleeve. Forming a larger than the inner diameter of the tapered inner peripheral surface of the expansion sleeve when the tapered outer peripheral surface of the pressurized sleeve, the upper end of the pressurized sleeve is characterized in that the protruding toward the upper side than the upper end of the expansion sleeve power locking device. The power locking device of claim 1, wherein the pressing plate of the adjusting bolt is fitted to the adjusting bolt and is formed of a washer having a diameter larger than that of the pressing sleeve. The method of claim 1, wherein the first part and the second part is made of a plate-like part, or each consists of cylindrical parts, the cylindrical second part in the interior of the cylindrical first part is a coaxial (coaxial) Is inserted into the power locking device for precision component joining, characterized in that configured to couple the inner peripheral surface of the cylindrical first component and the outer peripheral surface of the cylindrical second component by an interface.

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