CN218535182U - Turnover mechanism for processing nonmetal mineral substances - Google Patents

Abstract

The utility model provides a turnover mechanism for processing non-metallic mineral substances, which belongs to the technical field of diamond cutting, and comprises a bottom plate and a cutting mechanism which is arranged on the bottom plate in a sliding manner, wherein a fixed plate is arranged on the bottom plate corresponding to the cutting mechanism, a through hole is arranged on the fixed plate, a movable rod is arranged in the through hole, the end part of the movable rod is provided with a positioning plate, a supporting plate is arranged on the positioning plate through hinging, a clamping mechanism is arranged on the supporting plate, the other end of the supporting plate is provided with two first telescopic rods through a hinging seat, and the other end of each first telescopic rod is connected with the positioning plate through the hinging seat; the utility model discloses can place the diamond in the fixture in the backup pad, then control first electric telescopic handle and stretch out and just can make the angle of diamond adjust to slide cutting mechanism just can make the cutting knife on the cutting mechanism carry out the cutting on inclined plane to the diamond.

Description

Turnover mechanism for processing nonmetal mineral substances

Technical Field

The utility model relates to a diamond-cutting technical field, concretely relates to tilting mechanism is used in nonmetal mineral substance processing.

Background

Non-metallic minerals are minerals which have no metallic or semimetallic luster, are colorless or have various light colors, are transparent or translucent under a sheet of 0.03 mm thickness, and have poor electrical and thermal conductivity. Including the vast majority of oxysalt minerals as well as partial oxide and halide minerals. Most are rock-making minerals, and some are ore minerals constituting mineral deposits of various non-metals, light metals, rare earth metals, and the like. Some of them are mineral materials such as muscovite, kaolinite and the like; some of them are used to extract metal or nonmetal elements in their components, such as beryllium from beryllite Be3Al2[ Si6O18], and phosphorus from apatite Ca5[ PO4]3 (F, cl).

The cutting process of present diamond is on all fixing the fixture on bearing structure with the diamond usually, then control cutting blade cuts the diamond, and this kind of cutting mode is comparatively single, only can be to the diamond cutting of perpendicular or violently flat, can't carry out the cutting on inclined plane to the diamond.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a tilting mechanism for non-metallic mineral processing can place the diamond in the fixture in the backup pad, then control first electric telescopic handle and stretch out the angle that just can make the diamond and adjust to slip cutting mechanism just can make the cutting knife on the cutting mechanism carry out the cutting on inclined plane to the diamond.

In order to solve the technical problem, the utility model provides a tilting mechanism for non-metallic mineral processing, including bottom plate and the cutting mechanism of slip setting on the bottom plate, it sets up the fixed plate to correspond cutting mechanism on the bottom plate, the through-hole that sets up on the fixed plate, set up the movable rod in the through-hole, the movable rod tip sets up the locating plate, set up the backup pad through articulated on the locating plate, set up fixture in the backup pad, the backup pad other end sets up two first telescopic links through articulated seat, the other end of first telescopic link is connected with the locating plate through articulated seat.

Furthermore, a limiting ring is arranged on the supporting plate, a plurality of limiting grooves are formed in the limiting ring in an annular array mode, and limiting blocks are arranged at the end portions of the movable rods corresponding to the limiting grooves.

Further, a handle is arranged at the end part of the movable rod.

Furthermore, the side edge of the fixing plate is provided with a positioning block corresponding to the limiting ring, the positioning block is provided with a sliding groove, and the sliding groove is provided with a top plate in a sliding manner.

Further, the sliding groove is of a T-shaped structure.

Further, set up the board that resets through the bearing on the movable rod, set up a plurality of second telescopic links on the board that resets, second telescopic link tip is connected with the fixed plate, the spring is established to the cover on the second telescopic link, spring one end is connected with the fixed plate, the spring other end is connected with the board that resets.

The utility model discloses an above-mentioned technical scheme's beneficial effect as follows:

1. first telescopic link is electric telescopic handle, controls first telescopic link promptly and stretches out just can make the backup pad tip rotatory on the locating plate, and the backup pad just can change through the angle and the position that fixture drove the diamond to slip cutting mechanism just can make the cutting knife on the cutting mechanism carry out the cutting on inclined plane to the diamond.

2. Through the outside pulling of handle with the movable rod, then rotatory movable rod, the movable rod just can indirectly take the backup pad to rotate, and the backup pad just can rotate through the position that fixture took the diamond to cutting mechanism just can make the cutting knife on the cutting mechanism cut the diamond.

3. The top plate that the slip set up on the locating piece can carry on spacingly to the activity pole tip to make the activity pole can not slide in the through-hole when cutting the diamond, thereby influence the cutting mechanism to the cutting of diamond.

Drawings

FIG. 1 is a schematic structural view of a turnover mechanism for processing nonmetallic minerals in the present invention;

FIG. 2 is a schematic structural view of a side view of the movable rod of the present invention;

fig. 3 is a schematic structural view of a sectional view of the positioning block of the present invention.

1. A base plate; 2. a cutting mechanism; 3. a fixing plate; 4. a through hole; 5. a movable rod; 6. positioning a plate; 7. a support plate; 8. a clamping mechanism; 9. a hinged seat; 10. a first telescopic rod; 11. a limiting ring; 12. a limiting groove; 13. a limiting block; 14. a handle; 15. positioning a block; 16. a chute; 17. a top plate; 18. a reset plate; 19. a second telescopic rod; 20. a spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to fig. 1 to 3 of the embodiments of the present invention. It is to be understood that the embodiments described are only some of the embodiments of the present invention, and not all of them. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the present invention, belong to the protection scope of the present invention.

As shown in fig. 1-3: a turnover mechanism for processing non-metallic minerals comprises a bottom plate 1 and a cutting mechanism 2 slidably arranged on the bottom plate 1, wherein a fixing plate 3 is arranged on the bottom plate 1 corresponding to the cutting mechanism 2, a through hole 4 is formed in the fixing plate 3, a movable rod 5 is arranged in the through hole 4, a positioning plate 6 is arranged at the end part of the movable rod 5, a supporting plate 7 is arranged on the positioning plate 6 through hinging, a clamping mechanism 8 is arranged on the supporting plate 7, two first telescopic rods 10 are arranged at the other end of the supporting plate 7 through a hinging seat 9, and the other ends of the first telescopic rods 10 are connected with the positioning plate 6 through the hinging seat 9; can place the diamond in fixture 8 in backup pad 7, then control first electric telescopic handle and stretch out and just can make the angle of diamond adjust to slide cutting mechanism 2 just can make the cutting knife on the cutting mechanism 2 carry out the cutting on inclined plane to the diamond.

Specifically, the turnover mechanism for processing the nonmetallic minerals is characterized in that diamonds are placed in a clamping mechanism 8 on a supporting plate 7, then a cutting mechanism 2 is slid, and cutting knives on the cutting mechanism 2 can cut the diamonds; articulated seat 9 can make the both ends of first telescopic link 10 respectively with locating plate 6 and 7 tip swivelling joints of backup pad, first telescopic link 10 is electric telescopic handle, when needs are to the cutting of diamond slope, control electric telescopic handle stretches out, the electric telescopic handle tip just can promote 7 tip of backup pad rotatory on locating plate 6, thereby backup pad 7 will take the angle of diamond to adjust through 8 of fixture, thereby slip cutting mechanism 2 just can make the cutting knife on the cutting mechanism 2 carry out the cutting on inclined plane to the diamond.

According to one embodiment of the present invention, as shown in figures 1-2,

set up spacing ring 11 on the backup pad 7, annular array sets up a plurality of spacing grooves 12 on the spacing ring 11, it sets up stopper 13 at the movable rod 5 tip to correspond spacing groove 12. A handle 14 is arranged at the end part of the movable rod 5. Can be convenient for carry out the application of force to the movable rod 5 through handle 14, outwards pull out the activity through handle 14, stopper 13 until the 5 tip of movable rod pulls out spacing groove 12, then rotate movable rod 5 through handle 14, stopper 13 until the 5 tip of movable rod rotates spacing groove 12 position, then movable rod 5 resets, stopper 13 just can insert the spacing groove 12 in the spacing ring 11 in, thereby can prevent that movable rod 5 from indirectly driving the diamond rotation when cutting mechanism 2 cuts the diamond.

In one embodiment of the present invention, as shown in figures 1-3,

the side of the fixing plate 3 is provided with a positioning block 15 corresponding to the limiting ring 11, the positioning block 15 is provided with a sliding groove 16, and the sliding groove 16 is provided with a top plate 17 in a sliding manner. When needs pull out movable rod 5 and rotatory, need upwards stir roof 17, roof 17 will slide to spout 16, and then roof 17 no longer carries on spacingly to movable rod 5 tip, just can outwards stimulate movable rod 5 through handle 14, after the angle modulation of movable rod 5 finishes, the application of force to roof 17 is cancelled, roof 17 will move down under the effect of gravity, roof 17 just can continue to carry on spacingly to movable rod 5 tip, cutting mechanism 2 is when cutting the diamond promptly, movable rod 5 can not slide in through-hole 4.

In another embodiment of the present invention, as shown in figures 1-3,

the chute 16 is of a T-shaped configuration. Furthermore, the top plate 17 is also of a T-shaped structure, i.e. the top plate 17 does not fall out of the chute 16 during the downward sliding.

According to another embodiment of the present invention, as shown in figure 1,

the movable rod is provided with a reset plate 18 through a bearing, the reset plate 18 is provided with a plurality of second telescopic rods 19, the end parts of the second telescopic rods 19 are connected with the fixed plate 3, the second telescopic rods 19 are sleeved with springs 20, one ends of the springs 20 are connected with the fixed plate 3, and the other ends of the springs 20 are connected with the reset plate 18. That is, after the adjustment is performed by pulling the movable rod 5 by the handle 14, the spring 20 can push the return plate 18 to return by the handle 14, and the return plate 18 can pull the movable rod 5 to return.

The utility model discloses a theory of operation:

placing the diamond in a clamping mechanism 8 on a supporting plate 7, then sliding a cutting mechanism 2, and cutting the diamond by a cutting knife on the cutting mechanism 2; the hinged seat 9 enables two ends of the first telescopic rod 10 to be respectively connected with the positioning plate 6 and the end portion of the supporting plate 7 in a rotating mode, the first telescopic rod 10 is an electric telescopic rod, when the diamond needs to be cut in an inclined mode, the electric telescopic rod is controlled to stretch out, the end portion of the electric telescopic rod can push the end portion of the supporting plate 7 to rotate on the positioning plate 6, and therefore the supporting plate 7 can be adjusted through the angle of the diamond driven by the clamping mechanism 8, and the cutting knife on the cutting mechanism 2 can cut the inclined surface of the diamond by the aid of the sliding cutting mechanism 2; and when the cutting angle to the diamond needs to be adjusted, can stir roof 17 upwards, then outwards stimulate movable rod 5 through handle 14, then rotatory movable rod 5, movable rod 5 just can indirectly take backup pad 7 to rotate, backup pad 7 just can rotate through the position that fixture 8 took the diamond, then loosen handle 14, spring 20 just can indirectly drive movable rod 5 and reset, then the application of force to roof 17 is cancelled, roof 17 will move down under the effect of gravity, roof 17 just can continue to carry on spacingly to movable rod 5 tip, thereby slip cutting mechanism 2 just can make the cutting knife on the cutting mechanism 2 cut the diamond.

In the present invention, unless otherwise explicitly specified or limited, for example, it may be fixedly connected, detachably connected, or integrated; 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 foregoing is a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (6)

1. The utility model provides a tilting mechanism for nonmetal mineral processing which characterized in that: including bottom plate (1) and cutting mechanism (2) of slip setting on bottom plate (1), correspond cutting mechanism (2) and set up fixed plate (3) on bottom plate (1), through-hole (4) that set up on fixed plate (3), set up movable rod (5) in through-hole (4), movable rod (5) tip sets up locating plate (6), set up backup pad (7) through articulated on locating plate (6), set up fixture (8) on backup pad (7), backup pad (7) other end sets up two first telescopic links (10) through articulated seat (9), the other end of first telescopic link (10) is connected with locating plate (6) through articulated seat (9).

2. The turnover mechanism for processing nonmetallic minerals as set forth in claim 1, wherein: set up spacing ring (11) on backup pad (7), annular array sets up a plurality of spacing grooves (12) on spacing ring (11), corresponds spacing groove (12) set up stopper (13) at movable rod (5) tip.

3. The turnover mechanism for processing nonmetallic minerals as set forth in claim 2, wherein: the end part of the movable rod (5) is provided with a handle (14).

4. The turnover mechanism for processing nonmetallic minerals as set forth in claim 2, wherein: the side edge of the fixing plate (3) is provided with a positioning block (15) corresponding to the limiting ring (11), the positioning block (15) is provided with a sliding groove (16), and the sliding groove (16) is provided with a top plate (17) in a sliding manner.

5. The turnover mechanism for processing of non-metallic minerals as set forth in claim 4, wherein: the sliding groove (16) is of a T-shaped structure.

6. The turnover mechanism for processing nonmetallic minerals as set forth in claim 1, wherein: the utility model discloses a safety device, including movable rod (5), reset plate (18) is set up through the bearing on movable rod (5), reset plate (18) is last to set up a plurality of second telescopic links (19), second telescopic link (19) tip is connected with fixed plate (3), spring (20) are established to the cover on second telescopic link (19), spring (20) one end is connected with fixed plate (3), spring (20) other end is connected with reset plate (18).

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