CN218427685U - Numerical control lathe for processing ceramic products - Google Patents

Abstract

The utility model discloses a processing ceramic's numerical control lathe, which comprises a lathe, fluted and two sets of built-in convex spout are seted up on the upper portion of lathe, the inside of recess is provided with multiunit splint, and is two sets of the equal slidable mounting in inside of built-in convex spout has the convex slide, and is two sets of fixed pipe has all been welded on the upper portion of convex slide, and is two sets of the inside of fixed pipe all is provided with first bearing, and is two sets of the inside of first bearing all is provided with the connecting axle, and is two sets of first electric telescopic handle is all installed to the one end tip of connecting axle, and is two sets of the protective housing is all installed to first electric telescopic handle's one end tip, and is two sets of the face of keeping away from of protective housing has all run through second electric telescopic handle. Has the advantages that: the utility model discloses a splint, through the splint that set up, can realize the installation work to multiunit ceramic, need not a set of group installation ceramic in proper order, improve the numerical control lathe's of processing ceramic work efficiency.

Description

Numerical control lathe for processing ceramic products

Technical Field

The utility model relates to a ceramic processing technology field particularly, relates to a numerical control lathe of processing ceramic.

Background

The ceramic product is a ware made of clay and china clay with different properties as raw materials through the process flows of proportioning, forming, drying, roasting and the like, and after the ceramic product is formed, in order to improve the appearance and the practicability of the ceramic product, a numerical control lathe is mostly used at present to finish the polishing and etching work of the ceramic product.

The prior art discloses that the publication number is: CN211891465U is a numerical control lathe for processing ceramic products, comprising a device body, a bearing plate, a chute, a slider, a support column, a rotation axis, a configuration block, a cross bar, a movable groove, a hydraulic cylinder, a telescopic rod, a rotation block, a motor shaft, a diamond grinding wheel, a bottom block, a suction cup, a support ring and a diamond drill bit.

Above-mentioned utility model, once can only install fixedly to a set of ceramic, add man-hour to multiunit ceramic when needs, frequently change ceramic, can influence the work efficiency of the numerical control lathe who is used for processing ceramic.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a numerical control lathe of processing ceramic can realize the advantage to the installation work of multiunit ceramic, and then solves the problem among the above-mentioned background art.

(II) technical scheme

In order to realize the advantages of the installation work of the multiunit ceramic products, the utility model adopts the following specific technical scheme:

a numerical control lathe for processing ceramic products comprises a lathe, wherein a groove and two groups of built-in convex sliding grooves are formed in the upper portion of the lathe, a plurality of groups of clamping plates are arranged inside the groove, convex sliding plates are slidably mounted inside the two groups of built-in convex sliding grooves, fixed pipes are welded on the upper portions of the two groups of convex sliding plates, first bearings are arranged inside the two groups of fixed pipes, connecting shafts are arranged inside the two groups of first bearings, first electric telescopic rods are mounted at one end parts of the two groups of connecting shafts, protective housings are mounted at one end parts of the two groups of first electric telescopic rods, second electric telescopic rods penetrate through far surfaces of the two groups of protective housings, mounting plates are mounted at one end parts of the two groups of second electric telescopic rods, and concave plates are welded on the lower portions of the two groups of mounting plates, the rotary plates are arranged in the two groups of concave plates through rotating shafts, the first motors are arranged at the lower parts of the two groups of rotary plates, diamond cones and diamond grinding wheels are respectively clamped at the end parts of the output ends of the two groups of first motors, rotary fan blades are arranged on the side of the lathe, an electric cabinet is arranged on the rear end surface of the lathe, a control panel is arranged in the electric cabinet, a second motor is arranged on the side of the lathe, a fixed plate is fixedly arranged at the end part of the output end of the second motor, two groups of guide rods are welded in the groove, a second bearing and two groups of guide holes are arranged on one side of each group of clamping plates, one ends of the two groups of guide rods respectively penetrate through the guide holes, a rubber plate penetrates through the inner parts of the second bearings, a third bearing is arranged on the other side of the groove, and a threaded sleeve penetrates through the inner part of the third bearing, and an adjusting bolt penetrates through the inner part of the threaded sleeve.

Further, the thread sleeve is matched with the thread of the adjusting bolt.

Furthermore, the multiple groups of rubber plates are all positioned on the same horizontal line.

Furthermore, the vertical cross-sectional dimensions of the two groups of guide rods are the same as the vertical cross-sectional dimensions of the guide holes.

Furthermore, a cover hood is welded on one side of the lathe, a rotating shaft is rotatably installed on one side of the lathe, one end of the rotating shaft penetrates through the rotating fan blades, a driven gear is sleeved on the side wall of the rotating shaft, a main gear is sleeved on the side wall of the output end of the second motor, a gas collecting box is welded on one side of the cover hood, an air inlet pipe penetrates through the upper portion of the gas collecting box in a welded mode, a gas collecting hood penetrates through one side of the gas collecting box in a welded mode, and an air guide pipe is installed at one end of the gas collecting hood.

Further, the main gear and the driven gear are meshed with each other.

Furthermore, the control panel is electrically connected with the two groups of first electric telescopic rods, the two groups of second electric telescopic rods, the two groups of first motors and the second motors through electric wires.

(III) advantageous effects

Compared with the prior art, the utility model provides a processing ceramic's numerical control lathe possesses following beneficial effect:

(1) The utility model discloses a splint, during the numerical control lathe of in-service use processing ceramic, the operation workman puts the clearance between the multiunit splint respectively with the multiunit ceramic earlier, recycle thread bush and adjusting bolt screw-thread and mutually support, the operation workman holds the thread bush with the hand, clockwise rotation adjusting bolt again, adjusting bolt can promote multiunit splint and multiunit ceramic and continue the motion that moves to the right, when multiunit rubber slab and multiunit ceramic in close contact with, utilize control panel, make the second motor begin work, the output of second motor can drive the fixed plate synchronous revolution, utilize the fixed plate, adjusting bolt, the frictional force between multiunit rubber slab and the multiunit ceramic, the fixed plate drives adjusting bolt, multiunit rubber slab carries out rotary motion with the multiunit ceramic, usable control panel this moment, make two sets of first electric telescopic handle, two sets of second electric telescopic handle and two sets of first motor work, the output of two sets of first motors can drive diamond drill bit and diamond grinding wheel rotation, the extension or shorten of two sets of first electric telescopic handle and two sets of second electric telescopic handle, adjustable diamond drill bit and diamond grinding wheel bearing, for adjusting bolt, the multiunit rubber slab and the multiunit ceramic that the multiunit rotary lathe that the multiunit ceramic can pass through the multiunit installation efficiency that the multiunit installation need not improve the multiunit ceramic in proper order.

(2) The utility model discloses a rotating fan blade, according to the operation can know, rotatory diamond drill awl and diamond grinding wheel can polish and the sculpture to the ceramic, this in-process, can produce a large amount of raise dusts, the operation workman moves the one end of air duct to expected position earlier, recycle control panel, extend first electric telescopic handle, make the work of second motor simultaneously, the output of second motor can drive the master gear and carry out rotary motion, utilize master gear and driven gear intermeshing, the master gear can promote driven gear and rotate, driven gear can drive rotation axis and rotating fan blade work, when rotating fan blade is rotatory, can pass through the inside of the leading-in gas collection box of intake pipe with outside raise dusts, the inside raise dusts rethread gas collecting channel and air duct of gas collection box, arrange to expected position, through the rotating fan blade who sets up, need not to install electronic dust collecting equipment, just can accomplish dust absorption work, bring the convenience for the cleaning work of the numerical control lathe of ceramic processing.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a numerically controlled lathe for processing ceramic products according to the present invention;

fig. 2 is a perspective view of the splint according to the present invention;

fig. 3 is a schematic cross-sectional view of the protective case of the present invention;

fig. 4 is an enlarged view of a in fig. 1 according to the present invention.

In the figure:

1. turning a lathe; 2. a groove; 3. a convex chute is arranged in the box; 4. a splint; 5. a convex skateboard; 6. fixing the tube; 7. a first bearing; 8. a first electric telescopic rod; 9. a protective shell; 10. a second electric telescopic rod; 11. mounting a plate; 12. a concave plate; 13. a rotating plate; 14. a first motor; 15. drilling a diamond cone; 16. a diamond grinding wheel; 17. rotating the fan blades; 18. a second motor; 19. a fixing plate; 20. a second bearing; 21. a guide hole; 22. a rubber plate; 23. a guide bar; 24. a third bearing; 25. a threaded sleeve; 26. adjusting the bolt; 27. a rotating shaft; 28. a driven gear; 29. a main gear; 30. a covering cover; 31. a gas collection box; 32. an air inlet pipe; 33. a gas-collecting hood; 34. an air duct; 35. and (7) connecting the shafts.

Detailed Description

For further explanation of the embodiments, the drawings are provided as part of the disclosure and serve primarily to illustrate the embodiments and, together with the description, to explain the principles of operation of the embodiments, and to provide further explanation of the invention and advantages thereof, it will be understood by those skilled in the art that various other embodiments and advantages of the invention are possible, and that elements in the drawings are not to scale and that like reference numerals are generally used to designate like elements.

According to the utility model discloses an embodiment provides a numerical control lathe of processing ceramic.

Referring to the drawings and the detailed description, as shown in fig. 1-4, a numerically controlled lathe for processing ceramic products according to an embodiment of the present invention includes a lathe 1, a groove 2 and two sets of built-in convex chutes 3 are formed on an upper portion of the lathe 1, a plurality of sets of clamping plates 4 are disposed inside the groove 2, convex sliding plates 5 are slidably mounted inside the two sets of built-in convex chutes 3, fixing pipes 6 are welded on upper portions of the two sets of convex sliding plates 5, first bearings 7 are disposed inside the two sets of fixing pipes 6, connecting shafts 35 are disposed inside the two sets of first bearings 7, first electric telescopic rods 8 are mounted on end portions of the two sets of connecting shafts 35, protective cases 9 are mounted on end portions of the two sets of first electric telescopic rods 8, and second electric telescopic rods 10 penetrate through surfaces of the two sets of protective cases 9, and the end parts of one end of two groups of second electric telescopic rods 10 are respectively provided with a mounting plate 11, the lower parts of the two groups of mounting plates 11 are respectively welded with a concave plate 12, the interior of the two groups of concave plates 12 is respectively provided with a rotating plate 13 through a rotating shaft, the lower parts of the two groups of rotating plates 13 are respectively provided with a first motor 14, the end parts of the output ends of the two groups of first motors 14 are respectively clamped with a diamond drill cone 15 and a diamond grinding wheel 16, the side of the lathe 1 is provided with a rotating fan blade 17, the rear end surface of the lathe 1 is provided with an electric cabinet, the interior of the electric cabinet is provided with a control panel, the side of the lathe 1 is provided with a second motor 18, the end part of the output end of the second motor 18 is fixedly provided with a fixed plate 19, the interior of the groove 2 is welded with two groups of guide rods 23, one side of the plurality of clamping plates 4 is provided with a second bearing 20 and two groups of guide rods 21, one end of the two groups of guide rods 23 respectively penetrate through the plurality of guide rods 21, the inside of multiunit second bearing 20 has all been run through and has been had rubber slab 22, and the inside opposite side of recess 2 is provided with third bearing 24, and the inside of third bearing 24 runs through threaded sleeve 25 to threaded sleeve 25's inside has been run through and has been had adjusting bolt 26, through the splint 4 that sets up, can realize the installation work to multiunit ceramic, need not a set of group installation ceramic in proper order, improves the work efficiency of the numerical control lathe of processing ceramic.

In one embodiment, the threaded sleeve 25 is threadably interfitted with the adjustment bolt 26 to facilitate adjustment of the use position of the adjustment bolt 26.

In one embodiment, the plurality of sets of rubber plates 22 are all located on the same horizontal line, so as to avoid the plurality of sets of rubber plates 22 being dislocated, which results in the plurality of sets of rubber plates 22 being unable to rotate simultaneously.

In one embodiment, the vertical cross-sectional dimensions of the two groups of guide rods 23 are the same as those of the multiple groups of guide holes 21, so that the multiple groups of clamping plates 4 can be stably and transversely moved for use.

In one embodiment, a cover 30 is welded on one side of the lathe 1, a rotating shaft 27 is rotatably installed on one side of the lathe 1, one end of the rotating shaft 27 penetrates through the rotating fan blade 17, a driven gear 28 is sleeved on the side wall of the rotating shaft 27, a main gear 29 is sleeved on the side wall of the output end of the second motor 18, a gas collecting box 31 is welded on one side of the cover 30, an air inlet pipe 32 penetrates through the upper portion of the gas collecting box 31 in a welding mode, a gas collecting hood 33 penetrates through one side of the gas collecting box 31 in a welding mode, an air guide pipe 34 is installed at one end portion of the gas collecting hood 33, and through the arranged rotating fan blade 17, dust collection can be completed without installing an electric dust collection device, so that convenience is brought to cleaning work of a numerical control lathe for processing ceramic products.

In one embodiment, the master gear 29 intermeshes with the slave gear 28 to facilitate urging rotation of the slave gear 28.

In one embodiment, the control panel is electrically connected to the two sets of first electric telescopic rods 8, the two sets of second electric telescopic rods 10, the two sets of first motors 14 and the second motors 18 through electric wires, and the control panel can be implemented through simple programming by a person skilled in the art.

The working principle is as follows:

when the numerically controlled lathe for processing ceramic products is actually used, an operator firstly places a plurality of groups of ceramic products in gaps among a plurality of groups of clamping plates 4 respectively, then uses the threads of the thread bushing 25 to be matched with the threads of the adjusting bolt 26, the operator holds the thread bushing 25 by hand, then clockwise rotates the adjusting bolt 26, the adjusting bolt 26 can push the plurality of groups of clamping plates 4 and the plurality of groups of ceramic products to move to the right continuously, when a plurality of groups of rubber plates 22 are in close contact with the plurality of groups of ceramic products, the second motor 18 starts to work by using the control panel, the output end of the second motor 18 can drive the fixing plate 19 to synchronously rotate, the fixing plate 19, the adjusting bolt 26 and the friction force between the plurality of groups of rubber plates 22 and the plurality of groups of ceramic products are used, the adjusting bolt 26 is driven by the fixing plate 19, the plurality of groups of rubber plates 22 and the plurality of groups of ceramic products can rotate by using the control panel, the two groups of first electric telescopic rods 8, the two groups of second electric telescopic rods 10 and the two groups of first motors 14 are enabled to work, the output ends of the two groups of first motors 14 can drive the diamond drill cones 15 and the diamond grinding wheels 16 to rotate, the two groups of first electric telescopic rods 8 and the two groups of second electric telescopic rods 10 extend or shorten, the using positions of the diamond drill cones 15 and the diamond grinding wheels 16 can be adjusted, the multiple groups of second bearings 20 and third bearings 24 provide possibility for rotation of the adjusting bolts 26, the multiple groups of rubber plates 22 and the multiple groups of ceramic products, through the arranged clamping plates 4, the installation work of the multiple groups of ceramic products can be realized, the ceramic products do not need to be installed in sequence in one group, the working efficiency of a numerical control lathe for processing the ceramic products is improved, meanwhile, according to the operation, the rotating diamond drill cones 15 and the diamond grinding wheels 16 can polish and etch the ceramic products, a large amount of dust can be generated in the process, an operator firstly moves one end of the air duct 34 to a desired position, then utilizes the control panel to extend the first electric telescopic rod 8, and simultaneously enables the second motor 18 to work, the output end of the second motor 18 can drive the main gear 29 to rotate, the main gear 29 and the driven gear 28 are meshed with each other, the main gear 29 can drive the driven gear 28 to rotate, the driven gear 28 can drive the rotating shaft 27 and the rotating fan blades 17 to work, when the rotating fan blades 17 rotate, external dust can be guided into the gas collecting box 31 through the air inlet pipe 32, the dust in the gas collecting box 31 can be discharged to the desired position through the gas collecting hood 33 and the air duct 34, and the dust collection work can be completed through the arranged rotating fan blades 17 without installing electric dust collection equipment, so that the cleaning work of a numerical control lathe for processing ceramic products is facilitated.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The utility model provides a numerical control lathe of processing ceramic ware, its characterized in that, including lathe (1), recess (2) and two sets of built-in convex spout (3) have been seted up on the upper portion of lathe (1), the inside of recess (2) is provided with multiunit splint (4), and is two sets of equal slidable mounting in the inside of built-in convex spout (3) has convex slide (5), and is two sets of fixed pipe (6) have all been welded on the upper portion of convex slide (5), and is two sets of the inside of fixed pipe (6) all is provided with first bearing (7), and is two sets of the inside of first bearing (7) all is provided with connecting axle (35), and is two sets of first electric telescopic handle (8) is all installed to the one end tip of connecting axle (35), and is two sets of rotor plate (11) are all installed to the one end tip of first electric telescopic handle (8), and two sets of the face of keeping away of protective housing (9) all runs through second electric telescopic handle (10), and is two sets of the one end tip of second electric telescopic handle (10) all install rotor plate (11), the lower part of mounting plate (11) all have welded with concave board (12), and two sets of motor taper plate (13) have all installed through the lower part joint (13) and the motor output terminal of the diamond taper plate (13) and the lower part of the motor (13) and the joint (14) have first motor (14) respectively the motor (14) the lower part joint of the motor (14) the motor Diamond grinding wheel (16), rotatory flabellum (17) are installed to the side of lathe (1), the electric cabinet is installed to the rear end face of lathe (1), and the internally mounted of electric cabinet has a control panel, second motor (18) are installed to the side of lathe (1), and the output tip fixed mounting of second motor (18) has fixed plate (19), the inside welding of recess (2) has two sets of guide arms (23), the multiunit one side of splint (4) all is provided with second bearing (20) and two sets of guide hole (21), and is two sets of the multiunit is run through respectively to the one end of guide arm (23) guide hole (21), multiunit the inside of second bearing (20) all runs through there is rubber slab (22), the inside opposite side of recess (2) is provided with third bearing (24), and the inside of third bearing (24) runs through has threaded bush (25) to the inside of threaded bush (25) runs through has adjusting bolt (26).

2. The numerically controlled lathe for machining ceramic products according to claim 1, characterized in that said threaded sleeve (25) is threaded to cooperate with an adjusting bolt (26).

3. The numerically controlled lathe for machining ceramic products according to claim 1, wherein said sets of rubber plates (22) are all located on the same horizontal line.

4. The numerically controlled lathe for machining ceramic products according to claim 1, wherein the two sets of guide rods (23) have the same vertical cross-sectional dimensions as the plurality of sets of guide holes (21).

5. The numerically controlled lathe for machining ceramic products according to claim 1, wherein a cover hood (30) is welded on one side of the lathe (1), a rotating shaft (27) is rotatably installed on one side of the lathe (1), one end of the rotating shaft (27) penetrates through the rotating fan blades (17), a driven gear (28) is sleeved on the side wall of the rotating shaft (27), a main gear (29) is sleeved on the side wall of the output end of the second motor (18), a gas collecting box (31) is welded on one side of the cover hood (30), an air inlet pipe (32) is welded on the upper portion of the gas collecting box (31), a gas collecting hood (33) is welded on one side of the gas collecting box (31), and an air guide pipe (34) is installed at one end of the gas collecting hood (33).

6. The numerically controlled lathe for machining ceramic products according to claim 5, wherein the main gear (29) is meshed with the driven gear (28).

7. The numerically controlled lathe for machining ceramic products according to claim 1, wherein said control panel is electrically connected to two sets of said first electric telescopic rods (8), two sets of said second electric telescopic rods (10), two sets of said first electric motors (14) and two sets of said second electric motors (18) through electric wires.

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