CN218137071U - Six-axis linkage numerical control abrasive belt grinding machine of horizontal multi-abrasive-belt mechanism - Google Patents

Abstract

The utility model discloses a six-axis linkage numerical control abrasive belt grinding machine of many abrasive band mechanisms of level, including the protective housing, the bed body, lifter plate and fixed frame, the utility model discloses an at protective housing top installation motor, motor output runs through and stretches into the protective housing inside and install the threaded rod, threaded rod bottom and lathe bed top swing joint, the inside lifter plate that sets up of protective housing, the threaded hole is seted up at the lifter plate top, the threaded rod is rotatory to be run through this screw hole, it is rotatory to drive the threaded rod through the starter motor, utilize the lead screw structure to promote lifter plate vertical migration, lifter plate side wall contact protective housing inner wall, scrape the metal fillings with protective housing inner wall when the lifter plate removes down, the convenience is thrown the back and is attached to clearing up at the metal fillings of protective housing inner wall to the grinding.

Description

Six-axis linkage numerical control abrasive belt grinding machine of horizontal multi-abrasive belt mechanism

Technical Field

The utility model relates to a numerical control abrasive band grinding machine technical field specifically is a six-axis linkage numerical control abrasive band grinding machine of many abrasive band mechanisms of level.

Background

There are many types of numerically controlled grinders, including a numerically controlled abrasive belt grinder, which is a machine tool that uses a grinding tool to grind the surface of a workpiece. Most grinding machines use a grinding wheel rotating at a high speed for grinding, and a few grinding machines use oilstone, abrasive belt and other grinding tools and free abrasive materials for processing, such as a honing machine, a superfinishing machine tool, an abrasive belt grinding machine, a polishing machine and the like, a numerical control grinding machine also comprises a numerical control plane grinding machine, a numerical control centerless grinding machine, a numerical control internal and external circular grinding machine, a numerical control vertical universal grinding machine, a numerical control coordinate grinding machine, a numerical control forming grinding machine and the like, the numerical control machine has the characteristic of increasing flexibility of machining equipment, the flexible processing is not only suitable for multi-variety and medium and small-batch production, but also suitable for large-batch production, can alternately complete the processing of two or more different parts, increases the function of automatically changing workpieces, can realize the operation of unattended night, and the numerical control machine is a product combining information technology and mechanical manufacturing technology and represents the technical level and development of modern basic machinery. Application number 202 inner chamber (210) 772564.1 discloses a six-axis linkage numerical control abrasive belt grinding machine of many abrasive band mechanism of level, including the grinding machine base, the last fixed surface of grinding machine base is connected with the safety cover, two supporting seats of the last fixed surface of grinding machine base are connected with, the common fixedly connected with lathe bed of upper surface of two supporting seats, two locating plates of interior roof fixedly connected with of safety cover. The invention adopts the combination of the servo motor and the electric push rod to play a role of enabling the fixed block and the electric push rod to move left and right, and utilizes the electric push rod to jack up the workbench to achieve the purpose of cleaning the surface of the bed body by operators. However, in the application, in the grinding and polishing process of the six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism, metal chips are easily attached to the inner wall of the protective shell, and are inconvenient to clean.

SUMMERY OF THE UTILITY MODEL

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the abstract and the title of the present application to avoid obscuring the purpose of this section, the abstract and the title of the present application, and such simplifications or omissions cannot be used to limit the scope of the present invention.

The utility model discloses a problem that exists in the six linkage numerical control abrasive band grinding machines of above-mentioned and/or current many abrasive band mechanisms of level has been provided.

Therefore, the utility model aims at providing a six linkage numerical control abrasive band grinding machines of many abrasive band mechanisms of level, through installing the motor at the protective housing top, the motor output runs through and stretches into the protective housing inside and install the threaded rod, threaded rod bottom and lathe bed top swing joint, the inside lifter plate that sets up of protective housing, the lifter plate top set up threaded hole, the threaded rod is rotatory to be run through this screw hole, it is rotatory to drive the threaded rod through the starter motor, it promotes lifter plate vertical migration to utilize the lead screw structure, lifter plate side wall contact protective housing inner wall, scrape the metal fillings of protective housing inner wall down when the lifter plate removes, the convenient metal fillings that adhere to at the protective housing inner wall after polishing are cleared up.

For solving the technical problem, according to the utility model discloses an aspect, the utility model provides a following technical scheme:

a six-axis linkage numerical control abrasive belt grinding machine of a horizontal multi-abrasive belt mechanism comprises:

the grinding and polishing device comprises a protective shell, a grinding and polishing cavity is formed in the protective shell, a motor is mounted at the top of the protective shell, and an output end of the motor penetrates into the grinding and polishing cavity and is provided with a threaded rod;

the bed body is arranged at the bottom of the grinding and polishing chamber, an inner cavity is formed in the bed body, and an operating table is arranged at the top of the bed body;

the lifting plate is positioned inside the grinding and polishing cavity, a threaded hole is formed in the top of the lifting plate, and the threaded rod penetrates through the threaded hole in a rotating mode.

As a many abrasive band mechanisms of level's six linkage numerical control abrasive band grinding machine an optimal selection scheme, wherein, grind throw the cavity top with be connected with the guide bar between the bed body top.

As an optimal selection scheme of six-axis linkage numerical control abrasive belt grinding machine of many abrasive belt mechanism of level, wherein, the guiding hole has still been seted up at the lifter plate top, the guide bar runs through the guiding hole.

As an optimal selection scheme of six-axis linkage numerical control abrasive belt grinding machine of many abrasive belt mechanism of level, wherein, the fluting has been seted up to the lifter plate lateral wall, the brush hair is installed to the fluting lateral wall.

As an optimal selection scheme of six-axis linkage numerical control abrasive belt grinding machine of many abrasive band mechanism of level, wherein, the standing groove has been seted up at bed body top, the filter-tank has been seted up to the standing groove bottom, the filter-tank with the inner chamber intercommunication, the mounting groove has still been seted up at the standing groove top.

As a six-axis linkage numerical control abrasive belt grinding machine's of many abrasive band mechanism of level preferred scheme, wherein, still include fixed frame, fixed frame is located inside the filter-tank, the filter screen is installed to fixed frame inner circle, the fixed plate is installed to fixed frame outer lane, the fixed plate is located inside the mounting groove, the interior fixed plate is installed to the filter screen inner circle, the pull rod is installed at the interior fixed plate top.

Compared with the prior art: through installing the motor at the protective housing top, the motor output runs through and stretches into inside and install the threaded rod of protective housing, threaded rod bottom and lathe bed top swing joint, the inside lifter plate that sets up of protective housing, the threaded hole is seted up at the lifter plate top, the threaded rod is rotatory to run through this screw hole, it is rotatory to drive the threaded rod through starter motor, utilize the lead screw structure to promote lifter plate vertical migration, lifter plate lateral wall contact protective housing inner wall, scrape the metal fillings of protective housing inner wall down when the lifter plate removes, the convenient metal fillings attached to the protective housing inner wall after the polish are cleared up.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and detailed embodiments, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor. Wherein:

FIG. 1 is the overall structure diagram of a six-axis linkage numerical control abrasive belt grinding machine of a horizontal multi-abrasive belt mechanism of the utility model;

FIG. 2 is a partial structure view of a six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism of the utility model;

FIG. 3 is a partial structure diagram of a six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism of the utility model;

fig. 4 is a partial structure diagram of a six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism of the utility model.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

Next, the present invention will be described in detail with reference to the schematic drawings, and in order to describe the embodiments of the present invention in detail, the sectional views showing the device structure will not be enlarged partially according to the general scale for convenience of description, and the schematic drawings are only examples, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in the actual fabrication.

In order to make the objects, technical solutions and advantages of the present invention clearer, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.

The utility model provides a six-axis linkage numerical control abrasive belt grinding machine of many abrasive band mechanisms of level, through installing the motor at the protective housing top, the motor output runs through and stretches into the protective housing inside and install the threaded rod, threaded rod bottom and lathe bed top swing joint, the inside lifter plate that sets up of protective housing, the threaded rod top set up threaded hole, this screw hole is run through in the threaded rod rotation, it is rotatory to drive the threaded rod through the starter motor, utilize lead screw structure to promote the lifter plate vertical migration, lifter plate side wall contact protective housing inner wall, scrape the metal fillings of protective housing inner wall down when the lifter plate removes, the convenient metal fillings that adhere to at the protective housing inner wall after polishing are cleared up.

Fig. 1 to 4 are schematic structural diagrams illustrating an embodiment of a six-axis linkage numerically controlled abrasive belt grinding machine of a horizontal multi-abrasive belt mechanism according to the present invention, please refer to fig. 1 to 4, and the six-axis linkage numerically controlled abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism according to the present embodiment includes a protective shell 100, a bed body 200, a lifting plate 300, and a fixing frame 400.

The grinding and polishing chamber 110 is formed in the protective shell 100, the motor 120 is installed at the top of the protective shell 100, the output end of the motor 120 penetrates into the grinding and polishing chamber 110 and is provided with the threaded rod 130, the bottom end of the threaded rod 130 is connected to the top of the bed body 200 through a bearing, and the rotation of the threaded rod 130 is not influenced while the threaded rod 130 is supported.

The bed body 200 is installed at the bottom of the grinding and polishing chamber 110, an inner chamber 210 is arranged in the bed body 200, an operation table 220 is installed at the top of the bed body 200, a placing groove 230 is arranged at the top of the bed body 200, a filter groove 240 is arranged at the bottom of the placing groove 230, the filter groove 240 is communicated with the inner chamber 210, an installation groove 250 is further arranged at the top of the placing groove 230, the four sides of the placing groove 230 are in a slope shape, and cooling liquid containing metal chips can conveniently enter the inner chamber 210.

The lifting plate 300 is located inside the grinding and polishing chamber 110, a threaded hole 310 is formed in the top of the lifting plate 300, the threaded rod 130 penetrates through the threaded hole 310 in a rotating mode, the guide rod 140 is connected between the top of the grinding and polishing chamber 110 and the top of the bed body 200, a guide hole 320 is further formed in the top of the lifting plate 300, the guide rod 140 penetrates through the guide hole 320, when the lifting plate 300 moves, the guide hole 320 slides on the rod body of the guide rod 140, stability of the lifting plate 300 in sliding is improved, meanwhile, the guide rod 140 limits the rotating direction of the lifting plate 300, the lifting plate 300 is prevented from rotating along with the threaded rod 130, a notch 330 is formed in the side wall of the lifting plate 300, bristles 340 are installed on the side wall of the notch 330, the other end of each bristle 340 is attached to the side wall of the grinding and polishing chamber 110, when the motor 120 drives the threaded rod 130 to rotate, the lifting plate 130 to push the lifting plate 300 to move vertically, the lifting plate 300 drives the bristles 340 to move vertically, the bristles 340 rub the side wall of the grinding and polishing chamber 110, and polish metal scraps attached to the side wall of the grinding and polishing chamber 110.

The fixed frame 400 is located inside the filter tank 240, the filter screen 410 is installed on the inner ring of the fixed frame 400, the fixing plate 420 is installed on the outer ring of the fixed frame 400, the fixing plate 420 is located inside the mounting groove 250, the inner fixing plate 430 is installed on the inner ring of the filter screen 410, the pull rod 440 is installed at the top of the inner fixing plate 430, the filter screen 410 is used for filtering metal chips mixed in cooling liquid, the filtered metal chips are accumulated inside the placing groove 230, the bottom of the fixing plate 420 is in contact with the bottom of the mounting groove 250, the fixed frame 400 is fixed inside the filter tank 240 by utilizing gravity, and the fixed frame 400 is conveniently taken out from the inside of the filter tank 240 for cleaning through the pulling pull rod 440.

With reference to fig. 1 to 4, in the six-axis linkage numerically controlled abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism according to the embodiment, after grinding and polishing are completed, the motor 120 is started to drive the threaded rod 130 to rotate, the lifting plate 300 is pushed by the lead screw structure to move vertically, the bristles 340 rub against the side wall of the grinding and polishing chamber 110, metal chips attached to the side wall of the grinding and polishing chamber 110 are swept down, the coolant mixed with the metal chips flows into the filter tank 240 through the placing tank 230, and the filter screen 410 filters the metal chips in the coolant.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the non-exhaustive description of these combinations in this specification is merely for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (6)

1. A six-axis linkage numerical control abrasive belt grinding machine of a horizontal multi-abrasive belt mechanism is characterized by comprising:

the grinding and polishing device comprises a protective shell (100), wherein a grinding and polishing chamber (110) is formed in the protective shell (100), a motor (120) is installed at the top of the protective shell (100), and an output end of the motor (120) penetrates into the grinding and polishing chamber (110) and is provided with a threaded rod (130);

the bed body (200), the bed body (200) is installed at the bottom of the grinding and polishing chamber (110), an inner cavity (210) is formed in the bed body (200), and an operation table (220) is installed at the top of the bed body (200);

the lifting plate (300) is located inside the grinding and polishing chamber (110), a threaded hole (310) is formed in the top of the lifting plate (300), and the threaded rod (130) penetrates through the threaded hole (310) in a rotating mode.

2. The six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism of claim 1, characterized in that a guide rod (140) is connected between the top of the grinding and polishing chamber (110) and the top of the bed body (200).

3. The six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism of claim 2, characterized in that a guide hole (320) is further formed in the top of the lifting plate (300), and the guide rod (140) penetrates through the guide hole (320).

4. The six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism according to claim 3, characterized in that a slot (330) is formed in the side wall of the lifting plate (300), and bristles (340) are mounted on the side wall of the slot (330).

5. The six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive-belt mechanism according to claim 4, characterized in that a placing groove (230) is formed in the top of the bed body (200), a filter tank (240) is formed in the bottom of the placing groove (230), the filter tank (240) is communicated with the inner cavity (210), and a mounting groove (250) is further formed in the top of the placing groove (230).

6. The six-axis linkage numerical control abrasive belt grinding machine of the horizontal multi-abrasive belt mechanism according to claim 5, characterized by further comprising a fixing frame (400), wherein the fixing frame (400) is located inside the filter tank (240), a filter screen (410) is installed on the inner ring of the fixing frame (400), a fixing plate (420) is installed on the outer ring of the fixing frame (400), the fixing plate (420) is located inside the installation groove (250), an inner fixing plate (430) is installed on the inner ring of the filter screen (410), and a pull rod (440) is installed at the top of the inner fixing plate (430).

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