CN212682544U - Tool withdrawal groove milling equipment capable of automatically cleaning scraps in groove - Google Patents

Abstract

The utility model relates to a mill the equipment field, specifically be a tool withdrawal groove that relates to an automatic cleaning inslot sweeps mills equipment, including: milling a cutting table; the clamping tool is arranged on the milling table; the working end of the gyrator is vertically arranged at the bottom end of the milling working part of the milling table downwards; the milling part and the negative pressure rotating cleaning part are arranged on two sides of the working end of the gyrator in a way that the working end is vertically downward through a right-angle frame; the negative pressure rotating member includes: the output end of the servo motor is downwards arranged on one side of the working end of the gyrator through the right-angle frame; the rotating end of the rotating joint is downwards arranged at one end of the right-angle frame, and the top end of the rotating joint is communicated with the negative pressure port through a hose; the hollow pipe is coaxially and fixedly connected with the rotating end of the rotating joint; the hollow brush holder is coaxially arranged at the top end of the hollow pipe; the synchronous belt transmission mechanism is used for synchronously transmitting and connecting the hollow pipe and the output end of the servo motor, and the device can timely clean waste chips in the tool withdrawal groove after milling and is high in cleaning degree.

Description

Tool withdrawal groove milling equipment capable of automatically cleaning scraps in groove

Technical Field

The utility model relates to a mill the equipment field, specifically relate to an automatic tool withdrawal groove of clean inslot sweeps mills equipment.

Background

Milling is a method of cutting a workpiece using a rotating multi-edge tool, and is a highly efficient machining method. During operation, the cutter rotates (performs main motion), the workpiece moves (performs feed motion), and the workpiece can also be fixed, but the rotating cutter also needs to move (performs the main motion and the feed motion simultaneously). The milling machine tool comprises a horizontal milling machine or a vertical milling machine and also comprises a large-scale planer type milling machine. These machines may be ordinary machines or numerically controlled machines. And a rotary milling cutter is used for cutting and processing the cutter. Milling is generally carried out on milling or boring machines, suitable for machining planes, grooves, various shaped surfaces (such as spline milling keys, gears and threads), special surfaces of dies, and the like.

Chinese patent CN201811378426.5 discloses a high-strength self-fastening steel structure joint and a manufacturing method thereof, the steel structure joint is composed of three parts, the first part is a steel matrix with a hole adaptive to the second part in the center and high strength, the second part is low carbon alloy steel which is matched with the steel matrix and is subjected to surface carburization and central drilling, and the third part is hard curable hard filler which is injected and cured through the central hole of the second part; the bottom of the second part is provided with a deformable conical ring, and the side surface of the bottom of the second part can be deformed into a positive conical surface when the conical ring is flattened and can not be separated from the first part.

In the structure joint, after a rigid base body is milled, scraps can be remained in the internal tool withdrawal groove, if the scraps are not timely cleaned, the scraps are accumulated in the groove to influence subsequent installation, and the tool withdrawal groove milling equipment capable of automatically cleaning the scraps in the groove is needed

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that an equipment is milled in tool withdrawal groove of automatic cleaning inslot sweeps is provided, this technical scheme has solved the interior tool withdrawal groove sweeps and has remained the problem.

In order to solve the technical problem, the utility model provides a following technical scheme:

an escape milling device for automatically cleaning scraps in a groove comprises: milling a cutting table; the clamping tool is arranged on the milling table workbench; the working end of the gyrator is vertically arranged at the bottom end of the milling working part of the milling table downwards; the milling part and the negative pressure rotating cleaning part are arranged on two sides of the working end of the gyrator in a way that the working end of the milling part faces downwards vertically through a right-angle frame; the negative pressure rotating member comprises: the output end of the servo motor is downwards arranged on one side of the working end of the gyrator through a right-angle frame; the rotating end of the rotating joint is downwards arranged at one end of the right-angle frame, and the top end of the rotating joint is communicated with the negative pressure port through a hose; the hollow pipe is coaxially and fixedly connected with the rotating end of the rotating joint; the hollow brush holder is coaxially arranged at the top end of the hollow pipe; and the hollow pipe and the output end of the servo motor are in synchronous transmission connection through the synchronous belt transmission mechanism.

Preferably, the hollow brush holder comprises: the fixing sleeve is coaxially arranged at the bottom end of the hollow pipe; the diameter of the first thin ring is larger than that of the top end of the fixed sleeve, and the first thin ring is coaxially arranged at the bottom end of the fixed sleeve through a first connecting strip along the radial direction; the diameter of the second connecting strip is the same as that of the first thin ring, and the second connecting strip is coaxially arranged at the bottom end of the first thin ring along the axial direction; and the first fine hairbrush is arranged outside the second connecting strip along the axial direction.

Preferably, the inner circumferential surface of the fixing sleeve is provided with threads along the axial direction, and the fixing sleeve is coaxially screwed at the bottom end of the hollow pipe through the threads.

Preferably, a third connecting strip is radially arranged in the second thin ring, and a second thin brush is arranged at the bottom end of the third connecting strip.

Preferably, a transparent protective cover is arranged outside the synchronous belt transmission mechanism.

Preferably, the milling element comprises: the output shaft of the motor direct-coupled main shaft device is arranged on one side of the rotary working end of the gyrator downwards; and the milling end of the milling head is downwards coaxially arranged at the output end of the direct-coupled motor main shaft device.

Compared with the prior art, the utility model beneficial effect who has is:

the milling table working end can be translated and lifted, the clamping tool is used for clamping a rigid base body in the milling process, the rotator is equipment of which the working end can rotate for a certain specified angle, and the structures of the milling table, the clamping tool and the rotator are common and are not introduced;

during working, the rigid base body is placed on the working surface of the milling table, so that the rigid base body is clamped through the clamping tool, and the rigid base body is prevented from moving in the machining process, so that the milling is not accurate or can not be performed; after the rigid matrix is fixed, the gyrator is driven to make the working end of the gyrator rotate so that the milling end of the milling part is positioned right above the milling point of the rigid matrix, and the milling platform is started to make the working end of the milling part descend, so that the milling part with the working end rotating at a high speed mills an inner groove on the rigid matrix; after milling, the working end of the milling table resets, and more scraps are contained in the groove of the steel substrate at the moment, the working end of the gyrator gyrates, so that the working end of the negative-pressure rotary cleaning piece is positioned right above the inner groove of the steel substrate, the hollow tube enters the inner groove through the milling table, a servo motor is started, and the output shaft of the gyrator drives the hollow tube to coaxially rotate on the right-angle frame, the top end of the rotary joint is connected with a negative pressure port, so that the scraps in the inner groove of the steel substrate are sucked out under the action of negative pressure, the hollow brush frame and the hollow tube rotate coaxially at high speed, so that the working end of the hollow brush frame continuously sweeps the scraps adhered in the groove, the scraps are sucked out through the negative pressure, and the hollow brush frame enables the scraps not to be easily accumulated on the hollow brush frame due to the hollow structure in the rotating.

The device can in time clear up sweeps in the tool withdrawal groove after milling, and clean degree is high.

Drawings

Fig. 1 is a perspective view of the present invention;

FIG. 2 is a view of the milling element and the negative pressure rotary cleaning element of the present invention;

FIG. 3 is a perspective view of the negative pressure rotary cleaning element of the present invention;

fig. 4 is a perspective view of a milling member of the present invention;

fig. 5 and 6 are perspective views of the hollow brush holder of the present invention at two viewing angles.

The reference numbers in the figures are:

1. milling a cutting table;

2. a clamping tool;

3. a gyrator;

4. milling a part; 4a, directly connecting a motor with a main shaft device; 4b, milling the head;

5. a servo motor;

6. a rotary joint;

7. a hollow tube;

8. hollowing out the brush holder; 8a, a fixing sleeve; 8a1, screw thread; 8b, a first connecting strip; 8c, a first thin ring; 8d, a second connecting strip; 8e, a second thin ring; 8e1, third connecting strip; 8e2, second fine hair brush; 8f, a first fine hairbrush;

9. a synchronous belt transmission mechanism; 9a, a transparent protective cover.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 6, an escape milling apparatus for automatically cleaning scraps in a tank includes:

a milling table 1;

the clamping tool 2 is arranged on the workbench of the milling table 1;

the working end of the gyrator 3 is vertically arranged at the bottom end of the milling working part of the milling table 1 downwards;

the milling part 4 and the negative pressure rotating cleaning part are arranged on two sides of the working end of the gyrator 3, wherein the working end of the milling part faces downwards vertically through a right-angle frame;

the negative pressure rotating member comprises:

the output end of the servo motor 5 is downwards arranged on one side of the working end of the gyrator 3 through a right-angle frame;

the rotating end of the rotating joint 6 is downwards arranged at one end of the right-angle frame, and the top end of the rotating joint 6 is communicated with the negative pressure port through a hose;

the hollow pipe 7 is coaxially and fixedly connected with the rotating end of the rotating joint 6;

the hollow brush holder 8 is coaxially arranged at the top end of the hollow tube 7;

and the synchronous belt transmission mechanism 9 is used for synchronously transmitting and connecting the hollow pipe 7 and the output end of the servo motor 5 through the synchronous belt transmission mechanism 9.

The milling table 1 is provided with a working end capable of translating and lifting, the clamping tool 2 is used for clamping a rigid base body in the milling process, the rotator 3 is a device with a working end capable of rotating for a certain specified angle, and the structures of the milling table 1, the clamping tool 2 and the rotator 3 are common and are not introduced;

during working, the rigid matrix is placed on the working surface of the milling table 1, so that the rigid matrix is clamped by the clamping tool 2, and the rigid matrix is prevented from moving in the machining process, so that the milling is not accurate or can not be performed; after the rigid matrix is fixed, the rotator 3 is driven to rotate the working end of the rotator so that the milling end of the milling part 4 is positioned right above the milling point of the rigid matrix, the milling table 1 is started to lower the working end of the milling part, and therefore the milling part 4 with the working end rotating at a high speed mills an inner groove on the rigid matrix; after milling, the working end of the milling table 1 is reset, more scraps are contained in the groove of the steel substrate at the moment, the working end of the gyrator 3 is rotated, the working end of the negative-pressure rotary cleaning piece is located right above the inner groove of the steel substrate, the hollow tube 7 enters the inner groove through the milling table 1, the servo motor 5 is started, the output shaft of the gyrator drives the hollow tube 7 to coaxially rotate on the right-angle frame, the top end of the rotary joint 6 is connected with a negative pressure port, the scraps in the inner groove of the steel substrate are sucked out under the action of negative pressure, the hollow brush holder 8 and the hollow tube 7 coaxially rotate at high speed, the working end of the hollow brush holder 8 continuously sweeps the scraps adhered in the groove, the scraps are sucked out through the negative pressure, and the hollow brush holder 8 is not easy to accumulate on the hollow brush holder 8 due to the hollow structure in the rotating process, so that the tool withdrawal groove is convenient to clean.

As shown in fig. 5 and 6, the hollow brush holder 8 includes: the fixed sleeve 8a is coaxially arranged at the bottom end of the hollow tube 7; the diameter of the first thin ring 8c is larger than that of the top end of the fixed sleeve 8a, and the first thin ring is coaxially arranged at the bottom end of the fixed sleeve 8a through a first connecting strip 8b along the radial direction; the second connecting strip 8d is coaxially arranged at the bottom end of the first thin ring 8c through the second connecting strip 8d along the axial direction, and has the same diameter as the first thin ring 8 c; and the first fine hairbrush 8f is arranged outside the second connecting strip 8d along the axial direction.

The first connecting strip 8b and the second connecting strip 8d are used for fixedly connecting a fixed sleeve 8a, a first thin ring 8c and a second thin ring 8e, the fixed sleeve 8a is coaxially and fixedly arranged at the bottom end of the hollow tube 7, when the hollow tube 7 vertically descends, the first connecting strip 8b and the second thin ring 8e firstly enter the groove, when the hollow tube 7 coaxially rotates, the first thin brush 8f arranged on the second connecting strip 8d coaxially rotates, so that the first thin brush 8f scrapes scraps adhered in the groove, the diameter of the first thin ring 8c and the diameter of the second thin ring 8e are larger than that of the hollow tube 7, so that the first thin brush 8f can scrape the scraps on the wall of the inner withdrawing tool groove, the scraps in the groove are sucked out through the hollow tube 7 in a negative pressure state, and the thin rings are connected through the connecting strips, so that the thin rings are hollowed, so that the scraps are not easy to accumulate, thereby being convenient for cleaning.

As shown in fig. 5, the inner circumferential surface of the fixing sleeve 8a is provided with a screw thread 8a1 along the axial direction, and the fixing sleeve 8a is coaxially screwed on the bottom end of the hollow tube 7 through the screw thread 8a 1.

The fixing sleeve 8a is screwed at the bottom end of the hollow tube 7 through the thread 8a1, so that the hollow brush holder 8 is convenient to replace, and the hollow brush holders 8 with different cleaning diameters are replaced.

As shown in fig. 6, a third connecting strip 8e1 is radially arranged in the second thin ring 8e, and the bottom end of the third connecting strip 8e1 is provided with a second thin brush 8e 2.

The first fine brush 8f is used for cleaning the groove bottom wall scraps by the second fine brush 8e2 installed at the bottom end of the second fine ring 8e, so that the groove bottom scraps are cleaned in a rotating state, thereby facilitating the suction of the scraps by negative pressure.

As shown in fig. 3, a transparent protective cover 9a is provided outside the timing belt transmission mechanism 9.

The synchronous belt transmission mechanism 9 is easy to injure workers in a high-speed driving state, and the transparent protection cover 9a is arranged on the outer side of the synchronous belt transmission mechanism to prevent the synchronous belt transmission mechanism 9 from being separated from the synchronous belt transmission mechanism, so that the workers are injured.

As shown in fig. 4, the milling element 4 comprises: the output shaft of the motor direct-coupled main shaft device 4a is downwards arranged on one side of the rotary working end of the gyrator 3; and the milling end of the milling head 4b is downwards coaxially arranged at the output end of the motor direct-coupled main shaft device 4 a.

During milling, the working end of the gyrator 3 is rotated, so that the working position of the motor direct-coupled spindle device 4a is rotated to be right above the rigid base body, the milling part 4 is started when descending, and a groove is milled on the rigid base body through the milling head 4b rotating at a high speed.

The utility model discloses a theory of operation:

the milling table 1 is provided with a working end capable of translating and lifting, the clamping tool 2 is used for clamping a rigid base body in the milling process, the rotator 3 is a device with a working end capable of rotating for a certain specified angle, and the structures of the milling table 1, the clamping tool 2 and the rotator 3 are common and are not introduced;

during working, the rigid matrix is placed on the working surface of the milling table 1, so that the rigid matrix is clamped by the clamping tool 2, and the rigid matrix is prevented from moving in the machining process, so that the milling is not accurate or can not be performed; after the rigid matrix is fixed, the rotator 3 is driven to rotate the working end of the rotator so that the milling end of the milling part 4 is positioned right above the milling point of the rigid matrix, the milling table 1 is started to lower the working end of the milling part, and therefore the milling part 4 with the working end rotating at a high speed mills an inner groove on the rigid matrix; after milling, the working end of the milling table 1 is reset, more scraps are contained in the groove of the steel substrate at the moment, the working end of the gyrator 3 is rotated, the working end of the negative-pressure rotary cleaning piece is located right above the inner groove of the steel substrate, the hollow tube 7 enters the inner groove through the milling table 1, the servo motor 5 is started, the output shaft of the gyrator drives the hollow tube 7 to coaxially rotate on the right-angle frame, the top end of the rotary joint 6 is connected with a negative pressure port, the scraps in the inner groove of the steel substrate are sucked out under the action of negative pressure, the hollow brush holder 8 and the hollow tube 7 coaxially rotate at high speed, the working end of the hollow brush holder 8 continuously sweeps the scraps adhered in the groove, the scraps are sucked out through the negative pressure, and the hollow brush holder 8 is not easy to accumulate on the hollow brush holder 8 due to the hollow structure in the rotating process, so that the tool withdrawal groove is convenient to clean.

Claims (6)

1. The utility model provides an escape groove milling equipment of automatic cleaning inslot sweeps which characterized in that, including:

a milling table (1);

the clamping tool (2) is arranged on the workbench of the milling table (1);

the working end of the gyrator (3) is vertically arranged at the bottom end of the milling working part of the milling table (1) downwards;

the milling part (4) and the negative pressure rotating cleaning part are arranged on two sides of the working end of the gyrator (3) through right-angle frames, wherein the working end of the milling part faces downwards vertically;

the negative pressure rotating member comprises:

the output end of the servo motor (5) faces downwards and is arranged on one side of the working end of the gyrator (3) through a right-angle frame;

the rotating end of the rotating joint (6) is downwards arranged at one end of the right-angle frame, and the top end of the rotating joint (6) is communicated with the negative pressure port through a hose;

the hollow pipe (7) is coaxially and fixedly connected with the rotating end of the rotating joint (6);

the hollow brush holder (8) is coaxially arranged at the top end of the hollow tube (7);

synchronous belt transmission mechanism (9), hollow tube (7) and servo motor (5) output pass through synchronous belt transmission mechanism (9) synchronous transmission and connect.

2. An escape milling apparatus for automatically cleaning scraps in a tank as set forth in claim 1, wherein the hollow brush holder (8) comprises: the fixing sleeve (8 a) is coaxially arranged at the bottom end of the hollow pipe (7); the diameter of the first thin ring (8 c) is larger than that of the top end of the fixed sleeve (8 a), and the first thin ring is coaxially arranged at the bottom end of the fixed sleeve (8 a) through a first connecting strip (8 b) along the radial direction; the diameter of the second connecting strip (8 d) is the same as that of the first thin ring (8 c), and the second connecting strip (8 d) is coaxially arranged at the bottom end of the first thin ring (8 c) along the axial direction; and the first thin hair brush (8 f) is arranged outside the second connecting strip (8 d) along the axial direction.

3. The tool withdrawal groove milling equipment for automatically cleaning the scraps in the groove as claimed in claim 2, wherein the inner circumferential surface of the fixed sleeve (8 a) is provided with a thread (8 a 1) along the axial direction, and the fixed sleeve (8 a) is coaxially screwed at the bottom end of the hollow pipe (7) through the thread (8 a 1).

4. An escape milling apparatus for automatically cleaning scraps in a tank as claimed in claim 2, wherein a third connecting strip (8 e 1) is radially arranged in the second thin ring (8 e), and a second thin brush (8 e 2) is arranged at the bottom end of the third connecting strip (8 e 1).

5. An escape milling apparatus for automatically cleaning scraps in a tank as defined in claim 1, wherein a transparent protective cover (9 a) is provided outside the timing belt transfer mechanism (9).

6. An escape milling apparatus for automatically cleaning away scraps in a tank as set forth in claim 1, wherein the milling member (4) comprises: the motor is directly connected with a main shaft device (4 a), and an output shaft is arranged on one side of the rotary working end of the gyrator (3) downwards; and the milling end of the milling head (4 b) is downwards coaxially arranged at the output end of the motor direct-coupled main shaft device (4 a).

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