CN216888891U - Steady mechanism that removes of paces formula - Google Patents

Abstract

The utility model discloses a step type stable conveying mechanism which comprises a machine table, two supports and a pressing mechanism, wherein one support is installed in a sliding mode through two rows of first sliding rail sliding blocks on the machine table, the other support is fixedly connected with the machine table, the support at the sliding end is connected with a left positioning mechanism, the support at the fixed end is connected with a right positioning mechanism, the left positioning mechanism and the right positioning mechanism are identical in structural shape, the outer side of the support at the fixed end is connected with the pressing mechanism, the end parts of the two supports are connected with blanking inclined plates, one end of each support is connected with a plate following mechanism, the two sides of the support at the sliding end are respectively connected with a screw nut mechanism, and the other end of each screw nut mechanism is connected with a first motor through a belt; the support includes the bottom plate, is the riser of vertical relation, connects the inner panel of two risers with the bottom plate, and the blanking swash plate is connected at the tip of inner panel.

Description

Steady mechanism that removes of paces formula

Technical Field

The utility model belongs to the technical field of conveying mechanisms, and particularly relates to a step type stable conveying mechanism.

Background

The plate makes the material of often using among the machining process, in the plate transportation, because the rectangular shape of plate causes the plate fork to fold easily, current handling mechanism is owing to structural defect, has following not enoughly:

1. the automation degree is not high, and the moving is easy in the conveying process;

2. the adaptability is not high, can't adapt to the plate of different length.

SUMMERY OF THE UTILITY MODEL

In view of the problems raised by the background art described above, the present invention has an object to: aims to provide a step type stable conveying mechanism.

In order to achieve the technical purpose, the technical scheme adopted by the utility model is as follows:

a step type stable conveying mechanism comprises a machine table, two supports, one support is installed in a sliding mode through two rows of first sliding rail sliding blocks on the machine table, the other support is fixedly connected with the machine table, the support at the sliding end is connected with a left positioning mechanism, the support at the fixed end is connected with a right positioning mechanism, the left positioning mechanism and the right positioning mechanism are identical in structural shape, the outer sides of the supports at the fixed end are connected with a pressing mechanism, the end portions of the two supports are connected with blanking inclined plates, one end of each support is connected with a plate following mechanism, the two sides of each support at the sliding end are respectively connected with a screw nut mechanism, and the other end of each screw nut mechanism is connected with a first motor through a belt;

the support comprises a bottom plate, vertical plates which are perpendicular to the bottom plate and an inner plate which is connected with the two vertical plates, and the blanking inclined plate is connected to the end part of the inner plate;

right side positioning mechanism includes location mainboard, along the lower briquetting of location mainboard upper surface interval certain distance distribution and two loading boards that the symmetry vertically distributes, through horizontal slide rail slider sliding connection between loading board and the inner panel, through vertical slide rail slider sliding connection, two between loading board and the location mainboard the loading board is connected with common rack, the side of rack is connected with the telescopic cylinder of third, the output and the location mainboard fixed connection of the telescopic cylinder of third, rack toothing is connected with the gear, the gear of right side positioning mechanism end is connected through the pivot with the gear of left positioning mechanism end, the leg joint has electric telescopic handle, electric telescopic handle's output and rack fixed connection.

Further inject, hold-down mechanism includes horizontal support, horizontal support is evenly connected with a plurality of first telescopic cylinder along length direction, the output of first telescopic cylinder is connected with the briquetting, and such structural design provides power through first telescopic cylinder for go up the briquetting and can push down the briquetting under the cooperation, accomplish and press from both sides tight operation.

Further inject, the middle part of board is connected with the middle part bracing piece, the tip of middle part bracing piece is connected with the blanking swash plate equally, the side of blanking swash plate is equipped with the gyro wheel that a plurality of slopes distribute, and such structural design supports the middle part of longer plate through the middle part bracing piece, and the form of avoiding both ends to support causes the plate to be recessed, and the gyro wheel through the slope distribution is convenient for the plate blanking.

Further, the two ends of the bracket are provided with inward travel switches which are distributed at the two ends of the rack, and the structural design determines the forward and backward movement distance of the rack through the travel switches.

Further inject, including the flexible cylinder of second in the same direction as board mechanism, the splint of being connected with the flexible cylinder output of second, such structural design makes splint draw close through two flexible cylinders of second are ejecting, makes the plate left and right directions of just having the material loading put in place.

The utility model has the beneficial effects that:

1. the automation degree is high, the plate is conveyed in a step type conveying mode, and displacement cannot occur in the conveying process;

2. the adaptability is high, can adapt to the plate of different length.

Drawings

The utility model is further illustrated by the non-limiting examples given in the accompanying drawings;

FIG. 1 is a schematic view of a first structure of a step-type stable conveying mechanism according to an embodiment of the present invention;

FIG. 2 is a schematic top view of a step-type stable conveying mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic side view of a step-type stable conveying mechanism according to an embodiment of the present invention;

FIG. 4 is a second schematic structural diagram of a step-type stable conveying mechanism according to an embodiment of the present invention;

FIG. 5 is an installation diagram of a plate-following mechanism in an embodiment of a step-type stable conveying mechanism of the present invention;

FIG. 6 is a schematic structural diagram of a right positioning mechanism in an embodiment of a step-type stable conveying mechanism according to the present invention;

FIG. 7 is a schematic structural diagram of a pressing mechanism in an embodiment of a step-type stable conveying mechanism according to the present invention;

FIG. 8 is a schematic structural view of a sloping blanking plate in an embodiment of a step-type stable conveying mechanism according to the present invention;

the main element symbols are as follows:

a machine table 1;

a middle support bar 2;

a first slide rail slider 3;

the support 4, the bottom plate 41, the vertical plate 42 and the inner plate 43;

the positioning device comprises a left positioning mechanism 51, a right positioning mechanism 52, a positioning main board 521, a lower pressing block 522 and a bearing plate 523;

the pressing mechanism 6, the first telescopic cylinder 61 and the upper pressing block 62;

the device comprises an electric telescopic rod 71, a rack 72, a gear 73, a third telescopic cylinder 74, a first motor 75, a lead screw nut mechanism 76, a travel switch 77 and a rotating shaft 78;

a blanking sloping plate 8 and a roller 81;

and a plate-following mechanism 92.

Detailed Description

In order that those skilled in the art can better understand the present invention, the following technical solutions are further described with reference to the accompanying drawings and examples.

As shown in fig. 1-8, the step type stable conveying mechanism of the present invention includes a machine table 1, two supports 4, one support 4 is slidably mounted through two rows of first slide rail sliders 3 on the machine table 1, the other support 4 is fixedly connected with the machine table 1, the support 4 at the sliding end is connected with a left positioning mechanism 51, the support 4 at the fixed end is connected with a right positioning mechanism 52, the left positioning mechanism 51 and the right positioning mechanism 52 have the same structural shape, the outer side of the support 4 at the fixed end is connected with a pressing mechanism 6, the end portions of the two supports 4 are connected with blanking inclined plates 8, one end of the support 4 is connected with a plate following mechanism 92, the two sides of the support 4 at the sliding end are respectively connected with a screw nut mechanism 76, and the other end of the two screw nut mechanisms 76 is connected with a first motor 75 through a belt;

the support 4 comprises a bottom plate 41, vertical plates 42 which are vertical to the bottom plate 41 and an inner plate 43 which is connected with the two vertical plates 42, and the blanking inclined plate 8 is connected to the end part of the inner plate 43;

the right positioning mechanism 52 comprises a positioning main board 521, lower press blocks 522 distributed at a certain distance along the upper surface of the positioning main board 521, and two rows of symmetrical and vertically distributed bearing boards 523, the bearing boards 523 are connected with the inner board 43 through transverse slide rail sliders in a sliding manner, the bearing boards 523 are connected with the positioning main board 521 through vertical slide rail sliders in a sliding manner, the two bearing boards 523 are connected with a common rack 72, the side surface of the rack 72 is connected with a third telescopic cylinder 74, the output end of the third telescopic cylinder 74 is fixedly connected with the positioning main board 521, the rack 72 is meshed with a gear 73, the gear 73 at the end of the right positioning mechanism 52 is connected with the gear 73 at the end of the left positioning mechanism 51 through a rotating shaft 78, the support 4 is connected with an electric telescopic rod 71, and the output end of the electric telescopic rod 71 is fixedly connected with the rack 72.

In the implementation of the scheme, the plates are firstly fed, the plates are placed on the upper surfaces of the inner plates 43 of the two supports 4 after being fed, the placing positions of the plates are regulated by the plate arranging mechanism 92, then the output end of the third telescopic cylinder 74 extends out to jack the positioning main plate 521, the positioning main plate 521 slides through the vertical sliding rail slider, the lower pressing block 522 forks the plates, the plates are lifted from the upper surface of the inner plate 43, the electric telescopic rod 71 moves to drive the bearing plate 523 to move, the bearing plate 523 slides through the transverse sliding rail slider and drives the positioning main plate 521 to transversely move, the moving distance of the positioning main plate 521 is the distance between the lower pressing blocks 522, so that the plates move one step to form a step type conveying mode, the left positioning mechanism 51 at the other end moves, the power is transmitted to the gear 73 through the rotating shaft 78 to form synchronous movement, the pressing mechanism 6 presses down at each step to cooperate with the lower pressing block 522, the plates are prevented from shifting, then the third telescopic cylinder 74 is reset, the electric telescopic rod 71 is reset, the carrying process is repeated, the plates at the feeding position can be carried in a certain direction until blanking is carried out, the blanking is finished through the blanking inclined plate 8, when the plate moving to the farthest end is positioned on the blanking inclined plate 8, the lower pressing block 522 is reset, the plates slide downwards due to the inclined gradient to finish blanking, and in the process, the plate carrying is automatically carried in a step type manner, the automation degree is high, and the plates cannot shift in the carrying process;

in the aspect of improving the adaptability, one support 4 is slidably mounted through two rows of first sliding rail sliding blocks 3 on the machine table 1, the support 4 at the sliding end is connected with the left positioning mechanism 51, two sides of the support 4 at the sliding end are respectively connected with the screw nut mechanisms 76, the other ends of the two screw nut mechanisms 76 are connected with the first motor 75 through a belt, when the first motor 75 is powered on and started, the two screw nut mechanisms 76 are driven by the belt to synchronously rotate, the support 4 starts to generate translation under the driving of the screw nut mechanisms 76, so that the distance between the left positioning mechanism 51 and the right positioning mechanism 52 is adjusted, and the purpose of adapting plates with different sizes is achieved.

Preferably, hold-down mechanism 6 includes horizontal support, and horizontal support is evenly connected with a plurality of first telescopic cylinder 61 along length direction, and the output of first telescopic cylinder 61 is connected with briquetting 62, and such structural design provides power through first telescopic cylinder 61 for briquetting 522 is down pressed fit to last briquetting 62, accomplishes and presss from both sides tight operation. In fact, other configurations of the pressing device 6 can be considered as appropriate.

Preferably, the middle part of board 1 is connected with middle part bracing piece 2, and the tip of middle part bracing piece 2 is connected with blanking swash plate 8 equally, and blanking swash plate 8's side is equipped with the gyro wheel 81 that a plurality of slopes distribute, and such structural design supports the middle part of longer plate through middle part bracing piece 2, and the form of avoiding both ends to support causes the plate to be recessed, is convenient for the plate blanking through the gyro wheel 81 that the slope distributes. In fact, other configurations of the central support are specifically contemplated as the case may be.

Preferably, both ends of the bracket 4 are provided with inward travel switches 77, and the travel switches 77 are distributed at both ends of the rack 72, so that the forward and backward movement distance of the rack 72 is determined by the travel switches 77. In fact, other configurations for determining the position of movement of the rack 72 are contemplated as appropriate.

Preferably, in the same direction as board mechanism 92 includes the flexible cylinder of second, with the splint that the flexible cylinder output is connected of second, such structural design makes splint draw close through two flexible cylinders of second are ejecting, makes the plate left and right directions of just having material loading put in place. In fact, other configurations of the plate mechanism 92 are specifically contemplated as the case may be.

The foregoing embodiments are merely illustrative of the principles of the present invention and its efficacy, and are not to be construed as limiting the utility model. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (5)

1. The utility model provides a mechanism is carried in step stability which characterized in that: comprises a machine table (1), two brackets (4), one bracket (4) is slidably mounted through two rows of first sliding rail sliding blocks (3) on the machine table (1), the other bracket (4) is fixedly connected with the machine table (1), the bracket (4) at the sliding end is connected with a left positioning mechanism (51), the bracket (4) at the fixed end is connected with a right positioning mechanism (52), the left positioning mechanism (51) and the right positioning mechanism (52) have the same structural shape, the outer side of the bracket (4) at the fixed end is connected with a pressing mechanism (6), the end parts of the two brackets (4) are connected with blanking inclined plates (8), one end of the support (4) is connected with a plate following mechanism (92), two sides of the support (4) at the sliding end are respectively connected with a screw nut mechanism (76), and the other ends of the two screw nut mechanisms (76) are connected with a first motor (75) through a belt;

the support (4) comprises a bottom plate (41), vertical plates (42) which are perpendicular to the bottom plate (41), and an inner plate (43) which is connected with the two vertical plates (42), and the blanking inclined plate (8) is connected to the end part of the inner plate (43);

the right positioning mechanism (52) comprises a positioning main board (521), lower pressing blocks (522) distributed at a certain distance along the upper surface of the positioning main board (521) and two rows of symmetrical and vertically distributed bearing boards (523), the bearing boards (523) are connected with an inner board (43) in a sliding mode through transverse sliding rail sliders, the bearing boards (523) are connected with the positioning main board (521) in a sliding mode through vertical sliding rail sliders, the two bearing boards (523) are connected with a common rack (72), a third telescopic cylinder (74) is connected to the side face of the rack (72), the output end of the third telescopic cylinder (74) is fixedly connected with the positioning main board (521), the rack (72) is connected with a gear (73) in a meshing mode, the gear (73) at the end of the right positioning mechanism (52) is connected with the gear (73) at the end of the left positioning mechanism (51) through a rotating shaft (78), the support (4) is connected with an electric telescopic rod (71), and the output end of the electric telescopic rod (71) is fixedly connected with the rack (72).

2. The step stable conveying mechanism according to claim 1, characterized in that: hold-down mechanism (6) are including horizontal support, horizontal support is evenly connected with a plurality of first telescopic cylinder (61) along length direction, the output of first telescopic cylinder (61) is connected with briquetting (62).

3. The step stable conveying mechanism according to claim 2, characterized in that: the middle part of board (1) is connected with middle part bracing piece (2), the tip of middle part bracing piece (2) is connected with blanking swash plate (8) equally, the side of blanking swash plate (8) is equipped with gyro wheel (81) that a plurality of slopes distribute.

4. The step stable conveying mechanism according to claim 3, characterized in that: both ends of support (4) are equipped with inward travel switch (77), travel switch (77) distribute at the both ends of rack (72).

5. The step stable conveying mechanism according to claim 4, characterized in that: the plate following mechanism (92) comprises a second telescopic cylinder and a clamping plate connected with the output end of the second telescopic cylinder.

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