CN214394869U - High-precision cutting device for processing agate - Google Patents

Abstract

The utility model relates to an agate processing equipment technical field specifically discloses a high accuracy cutting device is used in agate processing. Including the equipment box, the inside bilateral symmetry of equipment box is equipped with the guide rail, swing joint has the slider on the guide rail, the rigid coupling has the connecting plate between the slider, the front end of connecting plate is equipped with first screw rod and spacing pipe, the installation piece has been cup jointed jointly on first screw rod and the spacing pipe, the saw bit is installed to the front end of installation piece, one side that the saw bit was kept away from to the installation piece is equipped with the second runner with saw bit coaxial coupling, installation piece top is equipped with first motor, the drive end of first motor has cup jointed first runner, the belt has been cup jointed between first runner and the second runner, the through-hole has been seted up to the inside bottom of equipment box, be equipped with the workstation in the through-hole, be equipped with the tray in the equipment box. The utility model aims to solve traditional agate cutting equipment when carrying out the agate cutting, lack the ability of accurate regulation, cause the problem that the cutting has certain error.

Description

High-precision cutting device for processing agate

Technical Field

The application relates to the technical field of agate processing equipment, and particularly discloses a high-precision cutting device for processing agate.

Background

Agate is also used as agate, horse brain, etc., is one of chalcedony minerals, is often a striped block mixed with opal and cryptocrystalline quartz, has the hardness of 6.5-7 degrees, the specific gravity of 2.65 and the color of the same level. Translucent or opaque. Trigonal system in its original form. It is usually in the form of dense block to form various structures, such as breast, grape, and tuberculosis, and is usually in the form of concentric circles. The chalcedony with different color compositions usually has various colors such as green, red, yellow, brown, white and the like. According to the pattern and the impurities, the Chinese herbal medicine can be classified into onyx, twined agate, agate with moss, agate with castle and the like. Is commonly used as a toy, an ornamental object, an ornament or a toy object. Stringed agate balls are often seen in ancient deceased.

In the processing process of agate, a cutting device is needed to cut and shape the agate and the surface of the agate needs to be subjected to buffing treatment. The existing cutting devices with various structures, including various program-controlled and numerical-controlled automatic stone machines, have complicated structures and are inconvenient, while the traditional cutting machine lacks the capability of precise adjustment and brings certain influence in the using process, so that the inventor provides a high-precision cutting device for processing agate so as to solve the problems.

Disclosure of Invention

The utility model aims to solve traditional agate cutting equipment when carrying out the agate cutting, lack the ability of accurate regulation, cause the problem that the cutting has certain error.

In order to achieve the above purpose, the basic scheme of the utility model provides a high-precision cutting device for processing agate, which comprises an equipment box, wherein guide rails are symmetrically arranged on two sides in the equipment box, slide blocks are movably connected on the guide rails, a connecting plate is fixedly connected between the slide blocks, a first screw rod and a limiting pipe are arranged at the front end of the connecting plate, an installation block is jointly sleeved on the first screw rod and the limiting pipe, a saw blade is arranged at the front end of the installation block, a second rotating wheel coaxially connected with the saw blade is arranged on one side of the installation block away from the saw blade, a first motor is arranged at the top of the installation block, a first rotating wheel is sleeved at the driving end of the first motor, a belt is sleeved between the first rotating wheel and the second rotating wheel, a through hole is arranged at the bottom end in the equipment box, a workbench is arranged in the through hole, the equipment box is internally provided with a tray, limiting grooves are symmetrically formed in the top of the tray, and the bottom of the workbench is connected into the limiting grooves in the top of the tray through limiting columns in a sliding mode.

The principle and effect of this basic scheme lie in:

1. the device realizes the accurate positioning of agate cutting through four adjusting mechanisms, wherein three adjusting mechanisms adopt manual adjustment, because the requirement on the size of the agate cutting is strict, the mechanical driving error is large, and the displacement size can be accurately controlled by adopting manual adjustment, thereby meeting the requirement on agate cutting.

2. The saw bit of cutting usefulness can carry out the front and back by a wide margin through gear and rack when adjusting and remove, cooperates the mode of manual rotation screw rod simultaneously, finely tunes around carrying out the workstation of placing agate, adjusts the transverse motion of saw bit through the same mode afterwards to the transverse motion of workstation is adjusted through above-mentioned mode once more, realizes that dual regulation makes the cutting more accurate.

Furthermore, the lower end center of the workbench is in threaded connection with a second screw, the front end of the second screw penetrates through the front end of the equipment box and is sleeved with a first crank, a rectangular through hole is formed in the front end of the equipment box, and the forming height of the rectangular through hole is equal to the diameter of the second screw. The operation stability is improved.

Further, a third screw rod is arranged on one side of the bottom end of the tray, the front end of the third screw rod penetrates through one side of the equipment box and is sleeved with a second crank, and a limiting plate is connected to the other side of the bottom end of the tray in a sliding mode. The operation stability is improved.

Furthermore, one end of the first screw penetrates through one side of the equipment box and is sleeved with the third crank, and a rectangular through hole is also formed in the side face of the equipment box. The operation of the user is convenient.

Furthermore, the top pin of the equipment box is connected with a transparent cover, the equipment box is formed by splicing bulletproof glass, and the thickness of the equipment box is equal to that of the equipment box. In order to prevent agate fragments from flying out to hurt workers in the cutting process, the transparent cover is arranged in the device and is formed by splicing bulletproof glass, the safety of the transparent cover is guaranteed, and the transparent cover covers the main body to improve the safety performance in all the adjusting and cutting processes.

Further, a protective cover is installed at the bottom of the sliding block, the guide rail is wrapped in the protective cover, a second motor is installed in the protective cover, and a gear is sleeved on the driving end of the second motor. The second motor is protected to work stably.

Furthermore, the bottom end of the guide rail is provided with a rack, and the rack is meshed with the gear. The transmission efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram illustrating a high-precision cutting device for agate processing according to an embodiment of the present application;

fig. 2 is a schematic structural diagram illustrating a displacement mechanism in a high-precision cutting device for agate processing according to an embodiment of the present application;

fig. 3 shows a schematic structural diagram of an adjusting mechanism in a high-precision cutting device for agate processing according to an embodiment of the present application.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description of the embodiments, structures, features and effects according to the present invention will be made with reference to the accompanying drawings and preferred embodiments.

Reference numerals in the drawings of the specification include: the device comprises a transparent cover 1, a first rotating wheel 2, a sliding block 3, a second rotating wheel 4, a guide rail 5, an equipment box 6, a first crank 7, a workbench 8, a second crank 9, a limiting pipe 10, a third crank 11, a first screw 12, a connecting plate 13, a saw blade 14, an installation block 15, a first motor 16 and a rack 17. The protective cover 18, the second motor 19, the gear 20, the second screw 21, the third screw 22, the tray 23 and the limiting groove 24.

Referring to fig. 1 to 3, in the embodiment of the present invention, a high precision cutting device for processing agate comprises an equipment box 6, wherein two sides of the inside of the equipment box 6 are symmetrically provided with guide rails 5, the guide rails 5 are movably connected with sliders 3, a connecting plate 13 is welded between the sliders 3, the front end of the connecting plate 13 is provided with a first screw 12 and a limiting pipe 10, the first screw 12 and the limiting pipe 10 are jointly sleeved with an installation block 15, the front end of the installation block 15 is provided with a saw blade 14, the rear end of the saw blade 14 penetrates through the front end of the installation block 15 and is sleeved with a second runner 4, the top of the installation block 15 is provided with a first motor 16, the driving end of the first motor 16 is sleeved with a first runner 2, a belt is sleeved between the first runner 2 and the second runner 4, the inside bottom end of the equipment box 6 is provided with a through hole, a workbench 8 is arranged in the through hole, a tray 23 is arranged in the equipment box 6, and the top of tray 23 has seted up spacing groove 24 symmetrically, and the bottom of workstation 8 is passed through spacing post sliding connection and is in the spacing groove 24 at tray 23 top.

In fig. 3, the center of the lower end of the worktable 8 is connected with a second screw 21 in a threaded manner, the front end of the second screw 21 penetrates through the front end of the equipment box 6 and is sleeved with a first crank 7, the front end of the equipment box 6 is provided with a rectangular through hole, the opening height of the rectangular through hole is equal to the diameter of the second screw 21, the first crank 7 drives the second screw 21 to rotate to adjust the worktable 8 back and forth, and the rectangular through hole has the effect that when the worktable 8 is adjusted transversely, the second screw 21 is not blocked.

In fig. 3, a third screw 22 is arranged on one side of the bottom end of the tray 23, the front end of the third screw 22 penetrates through one side of the equipment box 6 and is sleeved with a second crank 9, a limiting plate is slidably connected to the other side of the bottom end of the tray 23, the third screw 22 is driven to rotate through the second crank 9 to transversely adjust the workbench 8, and the limiting plate restrains the displacement of the tray 23.

In fig. 1, one end of the first screw 12 penetrates through one side of the equipment box 6 and is sleeved with the third crank 11, and a rectangular through hole is also formed in the side surface of the equipment box 6, the third crank 11 drives the first screw 12 to rotate so as to enable the mounting block 15 to move transversely, and meanwhile, the mounting block 15 is constrained by the limiting pipe 10, and the rectangular through hole has the effect that when the mounting block 15 is adjusted forwards and backwards, the first screw 12 is not blocked.

In fig. 1, the top pin of the equipment box 6 is connected with the transparent cover 1, the equipment box 6 is formed by splicing bulletproof glass, the thickness of the equipment box 6 is equal to that of the equipment box 6, and the transparent cover 1 is used for preventing the broken slag from splashing and detecting the cutting condition.

In fig. 2, a protective cover 18 is installed at the bottom of the sliding block 3, the guide rail 5 is wrapped in the protective cover 18, a second motor 19 is installed in the protective cover 18, a gear 20 is sleeved at the driving end of the second motor 19 (the model is Y-160L-6), and the second motor 19 drives the gear 20 to rotate.

In fig. 2, a rack 17 is disposed at the bottom end of the guide rail 5, and the rack 17 is engaged with the gear 20, and when the gear 20 rotates, the rack 17 rotates to further drive the slider 3 to displace.

The utility model discloses a theory of operation is: the agate raw stone is placed on a workbench 8, a second motor 19 drives a gear 20 to rotate, when the gear 20 rotates, the gear rotates on a rack 17 to further drive a sliding block 3 to displace so as to realize front and back displacement of a saw blade 14, then a third crank 11 drives a first screw 12 to rotate so as to enable an installation block 15 to transversely displace, the saw blade 14 is controlled to transversely be positioned at a cutting point, then the second crank 9 drives a third screw 22 to rotate so as to finely adjust the workbench 8, then a first crank 7 drives a second screw 21 to rotate so as to adjust the workbench 8 front and back, at the moment, a first motor 16 (the model is the same as that in the above, Y-160L-6) drives a first rotating wheel 2 to rotate, and the first rotating wheel 2 drives a second rotating wheel 4 to rotate through a belt so as to further drive the saw blade 14 to cut.

Although the present invention has been described with reference to the preferred embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (7)

1. The utility model provides a high accuracy cutting device is used in agate processing which characterized in that: including the equipment box, the inside bilateral symmetry of equipment box is equipped with the guide rail, swing joint has the slider on the guide rail, the rigid coupling has the connecting plate between the slider, the front end of connecting plate is equipped with first screw rod and spacing pipe, the installation piece has cup jointed jointly on first screw rod and the spacing pipe, the saw bit is installed to the front end of installation piece, one side that the saw bit was kept away from to the installation piece is equipped with the second runner with saw bit coaxial coupling, installation piece top is equipped with first motor, the drive end of first motor has cup jointed first runner, the belt has been cup jointed between first runner and the second runner, the through-hole has been seted up to the inside bottom of equipment box, be equipped with the workstation in the through-hole, be equipped with the tray in the equipment box, spacing groove has been seted up to the top symmetry of tray, the bottom of workstation is through the spacing inslot at tray top through spacing post sliding connection.

2. The high-precision cutting device for agate processing according to claim 1, wherein a second screw rod is connected to the center of the lower end of the workbench in a threaded manner, the front end of the second screw rod penetrates through the front end of the equipment box and is sleeved with a first crank, a rectangular through hole is formed in the front end of the equipment box, and the opening height of the rectangular through hole is equal to the diameter of the second screw rod.

3. The high-precision cutting device for agate processing according to claim 1, wherein a third screw is arranged on one side of the bottom end of the tray, the front end of the third screw penetrates through one side of the equipment box and is sleeved with a second crank, and a limiting plate is connected to the other side of the bottom end of the tray in a sliding manner.

4. The high-precision cutting device for agate processing according to claim 1, wherein one end of the first screw rod penetrates through one side of the equipment box and is sleeved with a third crank, and the side surface of the equipment box is also provided with a rectangular through hole.

5. The high-precision cutting device for agate processing according to claim 1, wherein a transparent cover is connected to a top pin of the equipment box, the equipment box is formed by splicing bulletproof glass, and the thickness of the equipment box is equal to that of the equipment box.

6. The high-precision cutting device for agate processing according to claim 1, wherein a protective cover is mounted at the bottom of the sliding block, the guide rail is wrapped in the protective cover, a second motor is mounted in the protective cover, and a gear is sleeved at the driving end of the second motor.

7. The high-precision cutting device for agate processing according to claim 6, wherein the bottom end of the guide rail is provided with a rack, and the rack is meshed with the gear.

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