KR102125129B1 - Internal chucking cutter sleeve structure with safety chucking device - Google Patents

Abstract

The present invention is an outer sleeve; An inner sleeve fixed concentrically within the outer sleeve, wherein a tool holder slot is formed between them; A columnar sub-supporting component located in the inner sleeve; A plurality of first locating steel balls held on side walls of the inner sleeve; A first spring for pressing the column-shaped lower-supporting component, the column-shaped lower-supporting component pressing the first locating steel and partially projecting into the tool holder slot; A second locating steel ball held on the inner wall of the outer sleeve; A locating rod movably positioned in the outer sleeve; A second spring for pressing the locating rod, the tool retaining end of the locating rod comprising a second spring, in contact with the second locating steel part protruding partially into the inner space of the inner sleeve, An inner chucking cutter sleeve structure with a safety chucking device is provided.

Description

INTERNAL CHUCKING CUTTER SLEEVE STRUCTURE WITH SAFETY CHUCKING DEVICE

The present invention relates generally to a cutter sleeve structure, and more particularly to an internal chucking cutter sleeve structure of an innovative structure type, with a safety chucking device.

CNC machine tools are indispensable equipment in the current automated production and manufacturing industry for integrated automation design needs, which are used for automated tool mounting and tool change and automatic return of tool holders. , Tool magazine, tool guide and tool changer. A common tool mounting and tool changing method secures multiple tool holder sleeves within the tool magazine, and each tool holder sleeve is provided with a tool holder slot for inserting a tool holder therein. The tool holder sleeve and tool holder are connected by a positioning mechanism. The positioning mechanism, in each tool holder sleeve, has a radial through hole connected to the tool holder slot, and the radial through hole has a steel ball and a spring for pressing the steel ball. It is provided. A slot for selectively embedding the steel ball is provided at one end of the holder, and the steel ball is protruded or retracted through the radial through hole according to the tool holder position, so that the tool holder and the tool holder sleeve are locked. Goes into or goes off.

However, known tool holder sleeves still have the following problems according to actual experience. After prolonged use, the spring and steel ball wear out, and even because the spring has deflection and insufficient restoring force, the steel ball cannot be firmly embedded in the slot of the tool holder, and the tool holder and tool holder are also locked. The sleeve may still fall. In order to avoid the above problem, a positioning mechanism is provided to strengthen the locking relationship between the tool holder and the tool holder sleeve, so that the spring is tightly compressed, and the restoring force tightly and firmly embeds the steel ball into the slot of the tool holder. Although possible, however, it is difficult to remove the tool holder from the tool holder sleeve, as the aforementioned restoring force must be overcome before the tool holder is removed.

The main object of the present invention is to provide an inner chucking cutter sleeve structure with a safety chucking device. The technical problem to be solved above is stopped through a method of developing a new type of inner chucking cutter sleeve structure with a safety chucking device having more ideal practicality.

In view of the technical features of the present invention for solving a problem, the inner fixed cutter sleeve structure with a safety chucking device is an inner sleeve and an inner sleeve concentrically fixed in the outer sleeve, with a tool holder slot formed therebetween. Will be; A columnar under-prop component located in the inner sleeve; A plurality of first locating steel balls held on the side walls of the inner sleeve; A first spring for pressing the columnar bottom-supporting component, the columnar bottom-supporting component pressing the first locating steel to partially project into the tool holder slot; A second locating steel ball held on the inner wall of the outer sleeve; A locating rod movably positioned in the outer sleeve; And a second spring for pressing the locating rod, wherein the tool retaining end of the locating rod contacts a second locating steel part protruding partially into the inner space of the inner sleeve.

1 is a combined three-dimensional view of a preferred embodiment of the present invention.
FIG. 2 is an exploded view of FIG. 1.
FIG. 3 is a cross-sectional view of FIG. 1.
4 is a cross-sectional view from another viewing angle of FIG. 1.
5 is a sectional view from another viewing angle of FIG. 1;
6 is a view showing the operation of FIG. 3.
7 is a sectional view from another viewing angle of FIG. 6.
8 is a schematic view of positioning the tool holder in the tool holder slot according to FIG. 6.
9 is a schematic diagram of another implementation method of the present invention.
10 is a schematic diagram of another method of implementing the present invention.

1-5 show a preferred embodiment of an internal chucking cutter sleeve structure with a safety chucking device of the present invention, but the embodiment is merely exemplary, and the present patent application is not limited to this structure. The inner chucking cutter sleeve structure with a safety chucking device includes an outer sleeve 10, a radial through hole 11, a retaining channel 12, an inner sleeve 20, a columnar lower-supporting component 30, It includes a plurality of first locating steel balls 31, a first spring 32, a locating rod 40, a second locating steel ball 41, a second spring 42, and a fixing portion 43 .

There is an opening 13 at the front end of the outer sleeve 10. The radial through hole 11 is formed in the radial direction of the outer sleeve 10 from the outer sleeve 10. The first end 111 of the radial through hole 11 extends from the outer circumference of the outer sleeve 10. The second end 112 of the radial through hole 11 is connected to the second retaining portion 22 of the inner sleeve 20. The inner sleeve 20 is fixed concentrically within the outer sleeve 10. The tool holder slot 50 for the tool holder 60 is formed between the inner and outer sleeves 20, 10. The tool holder slot 50 is connected to the opening 13. The inner space of the inner sleeve 20 has a first holding portion 21 and a second holding portion 22. A plurality of first punch holes 211 are provided on a side wall of the first holding portion 21, and the first punch holes 211 are symmetrically spaced from each other. The first punch hole 211 holds the first locating steel ball 31.

The columnar bottom-supporting part 30 is located in the inner sleeve 20. The columnar lower-supporting part 30 in the first retaining portion 21 is surrounded by a wedge-shaped flange 301. The first spring 32 is located in the inner sleeve 20 to press the columnar lower-supporting component 30, and also the wedge-shaped flange 301 of the columnar lower-supporting component 30 is Since the first locating steel ball 31 is pressed outward, the first locating steel ball 31 partially protrudes into the tool holder slot 50 through the first punch hole 211.

The second locating steel ball 41 is retained at the second end 112 of the radial through hole 11. The first end 121 of the retaining channel 12 extends from the outer circumference of the outer sleeve 10. The second end 122 of the retaining channel 12 extends into the outer sleeve 10 and is cross-connected to the radial through hole 11. In another execution mode, the retaining channel 12 can be positioned obliquely to the outer sleeve 10. 10 shows another implementation of the invention. The port of the first end 121 of the retaining channel 12 can be located at either the front side end of the outer sleeve 10 and the two side ends (construction line).

The locating rod 40 is located within the retaining channel 12 and includes a tool retaining end 401, a tool retract slot 402, and a convex pin 403. The tool holding end 401 is located on the body of the locating rod 40 corresponding to the second locating steel ball 41. The tool retract slot 402 is located on the body of the locating rod 40 close to the tool holding end 401. The convex pin 403 extends outwardly from the end of the locating rod 40 away from the tool retaining end 401 and protrudes from the port of the first end 121 of the retaining channel 12. The fixing portion 43 is located in the port of the first end 121 of the retaining channel 12 to limit the range of movement of the locating rod 40 in the retaining channel 12. The second spring 42 is located in the retention channel 12 to press the locating rod 40. The tool retaining end 401 of the locating rod 40 contacts the second locating steel 41, so that the second locating steel 41 has a second end of the radial through hole 11 ( Partially protrudes through the port of 112 into the second retaining portion 22 of the inner sleeve 20. When the convex pin 403 of the locating rod 40 is pressed, the locating rod 40 moves toward the second end 122 of the holding channel 12, so that the second locating steel ball 41 Is retained in the tool retract slot 402. In addition, a guide plane 404 is provided on the opposite side of the locating rod 40 near the tool holding end 401, and a guide member is provided at a position near the first end 111 of the radial through hole 402. (44) is provided. By directing and guiding the locating rod 40, the tool retaining end 401 and tool retract slot 402 of the locating rod 40 can be accurately aligned with the second locating steel 41 during operation. To ensure that, the guide member 44 is suspended from the guide plane 404.

Based on the structural component design described above, the operation of the present invention is described below. 6 and 7, when the tool holder 60 (not shown) is secured to the present invention, the convex pin 403 of the locating rod 40 is pressed to locate the locating rod 40 ) Moves toward the second end 122 of the retaining channel 12, a second locating tool 41 is retained in the tool retract slot 402, and the second locating tool 41 is released. . Then, as shown in FIG. 8, when the tool holder 60 is inserted into the tool holder slot 50, the outer edge of the tool holder 60 presses the first locating steel ball 31 inside Moving toward the first retaining portion 21 of the sleeve 20, the first locating steel 31 presses the columnar lower-supporting part 30 to a second retaining part of the inner sleeve 20 (22). When the tool holder 60 passes through the first locating steel ball 31, the first spring 32 moves the columnar lower-supporting component 30 of the inner sleeve 20 for its return operation. By pressing toward the first retaining portion 21, the columnar lower-supporting part 30 and the first locating steel ball 31 are restored, that is, the first locating steel ball 31 is the first punch hole Partially protrudes into the tool holder slot 50 through 211. Finally, as the return operation of the second spring 42 continues to press the locating rod 40 towards the first end 121 of the retaining channel 12, the convexity of the locating rod 40 The acting force on the pin 403 is released, the locating rod 40 is restored, and the tool retaining end 401 of the locating rod 40 contacts the second locating steel ball 41, The second locating steel ball 41 is restored, firmly positioning the columnar sub-supporting component 30 as shown in FIGS. 4 and 5. Accordingly, since the first locating steel ball 31 clamps the tool holder 60, the present invention can accurately lock the tool holder 60 as shown in FIG.

Also, the above-described steps are reversed to remove the tool holder 60, so that the tool holder 60 can be quickly released.

9 shows another mode of execution of the present invention, the main difference from the preferred embodiment is that of the columnar sub-support part 30 near the second retaining portion 22 of the inner sleeve 20. The end is provided with a buried portion 302. The buried portion 302 is provided for clamping the second locating steel ball 41.

The "internal chucking cutter sleeve structure with safety chucking device" described in the present invention includes an outer sleeve, an inner sleeve, a columnar lower-supporting component, a first spring, a radial through hole, a second locating steel ball, a locating rod Compared to the known technology proposed in the prior art, the present invention locates to accurately lock and quickly release the tool holder, as it has innovative unique types and technical features, such as a retaining channel, a fixed part, and a second spring. Rod and corresponding structure designs can be used, which have practical advancements.

Claims (5)

As an internal chucking cutter sleeve structure with a safety chucking device:
An outer sleeve with an opening at the front end;
An inner sleeve concentrically fixed to the outer sleeve, wherein a tool holder slot for a tool holder is formed between the inner sleeve and the outer sleeve, and the tool holder slot is connected to the opening;
A columnar lower-supporting component positioned in the inner sleeve, the end of the columnar lower-supporting component retained in a first retaining portion surrounded by a wedge-shaped flange;
A first spring positioned in the inner sleeve to press the columnar lower-support component;
A radial through hole formed in the outer sleeve in the radial direction of the outer sleeve;
A second locating steel ball held at the second end of the radial through hole;
A retention channel located in the outer sleeve;
A locating rod located in the retaining channel and comprising a tool retaining end, a tool retract slot, and a convex pin;
A fixed portion located in the port of the first end of the retaining channel to limit the range of movement of the locating rod in the retaining channel; And
A second spring located in the holding channel to press the locating rod,
The inner space of the inner sleeve has a first retaining portion and a second retaining portion, a plurality of first punch holes are provided on the side wall of the first retaining portion, and the first punch holes are symmetrically spaced from each other, respectively The first punch hole of the first retaining steel ball,
Since the wedge flange of the columnar lower-supporting part presses the first locating steel outward, the first locating steel partially protrudes into the tool holder slot through the first punch hole,
The first end of the radial through hole extends from the outer circumference of the outer sleeve, and the second end of the radial through hole is connected to the second retaining portion of the inner sleeve,
The first end of the retaining channel extends from the outer circumference of the outer sleeve, and the second end of the retaining channel extends into the outer sleeve, crossing the radial through hole,
The tool holding end is located in the body of the locating rod corresponding to the second locating steel ball, the tool retracting slot is located in the locating rod body near the tool holding end, and the convex pin is the locating pin Extending outwardly from the tool retaining end from the end of the tinting rod, protruding from the port of the first end of the retaining channel,
Since the tool retaining end of the locating rod contacts the second locating steel ball, the second locating steel ball is through the port of the second end of the radial through hole, and the second retaining of the inner sleeve Partially projecting into the portion, when the convex pin of the locating rod is pressed, the locating rod moves toward the second end of the retaining channel, so that the second locating ball is in the tool retract slot. An internal chucking cutter sleeve structure with a retaining, safety chucking device. According to claim 1,
A guide plane is provided on the opposite side of the locating rod near the tool holding end, a guide member is provided at a position near the first end of the radial through hole, and the guide member is suspended from the guide plane, Internal chucking cutter sleeve structure with safety chucking device. The method of claim 1 or 2,
The retaining channel is positioned at an angle to the cutter sleeve, an internal chucking cutter sleeve structure with a safety chucking device. The method of claim 3,
An inner chucking cutter sleeve structure with a safety chucking device, wherein the port at the first end of the retaining channel is located at the front side end of the outer sleeve and at one of the two side ends. The method of claim 4,
An end portion of the columnar sub-supporting part near the second retaining portion of the inner sleeve is provided with a buried portion, and the buried portion is provided for clamping the second locating steel, with a safety chucking device. Internal chucking cutter sleeve structure.

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