CN211392822U - Material conveying device for machining of precise metal parts - Google Patents

Abstract

The utility model discloses a precision metal parts machining is with fortune material device, first conveying subassembly, second conveying subassembly and third conveying subassembly, the first conveyer belt height of first conveying subassembly is higher than the second conveyer belt height of second conveying subassembly, the second conveyer belt height of second conveying subassembly is higher than the third conveyer belt height of third conveying subassembly, the terminal baffle that is provided with a slope setting that is located second conveyer belt top of second conveying subassembly and a third spout of being connected with the second conveyer belt of second conveying subassembly for the part that will pass through the screening plate is sent to third conveying subassembly. The utility model discloses simple structure has not only realized the screening to the part, still adjusts the part that is not conform to the requirement, makes it accord with subsequent processing requirement, and need not to screen again from the head, has improved production efficiency greatly.

Description

Material conveying device for machining of precise metal parts

Technical Field

The utility model relates to a material transporting device for machining of precise metal parts, in particular to a mechanical device capable of automatically feeding and discharging materials to and from a minimally invasive surgery chuck part in the deburring machining of workpieces.

Background

The minimally invasive surgical chuck part has high requirements on the roughness of the machined surface and the quality of an edge, particularly, the machined surface does not allow any residual machined burr, but a large amount of burrs are inevitably left after machining and are required to be removed, and because a workpiece needs to be machined and inspected in a single piece, an automatic material conveying structure meeting the requirement of single-piece deburring machining needs to be designed according to a deburring machining process to improve the machining efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an accurate metalwork processing is with fortune material device, this accurate metalwork processing is with fortune material device simple structure has not only realized the screening to the part, still adjusts the part that is not conform to the requirement, makes it accord with subsequent processing requirement, and need not to follow the head and filter again, has improved production efficiency greatly.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a material conveying device for machining a precise metal part is used for minimally invasive surgery chuck parts and comprises a base plate, two convex strip portions and two wing clamping portions, wherein the two convex strip portions are arranged on the upper surface of the base plate and are arranged at two edges of the length direction of the base plate in parallel;

when the lower surface of the substrate of the component is contacted with the conveyor belt, the height of the component is H2, the height of the convex strip is H1, the total length of the component is L, the length of the wing clamping part is L1, and the width of the component is W;

the height of the part is H3 when the top surface of the wing portion of the part is in contact with the conveyor belt;

the material conveying device comprises a first conveying assembly, a second conveying assembly and a third conveying assembly, wherein the first conveying assembly is higher than the second conveying assembly in height, and the second conveying assembly is higher than the third conveying assembly in height;

the front end of the first conveying assembly is connected with the material box and is used for conveying the parts falling from the material box to the rear side, an adjusting plate is arranged in the middle of the first conveying assembly and is arranged above the first conveying belt along the movement direction of the first conveying belt, and the space above the first conveying belt is divided into two parts in the direction perpendicular to the movement direction of the first conveying belt;

a height limiting plate which is obliquely arranged is arranged on the first conveying assembly and behind the adjusting plate, two ends of the height limiting plate are respectively connected with two side plates of the first conveying assembly, the height limiting plate is arranged above the first conveying belt, the distance between the height limiting plate and the conveying belt is greater than H3 and smaller than H2, the friction coefficient of the height limiting plate is smaller than that of the conveying belt of the first conveying assembly, the first conveying belt arranged at the front end face of the height limiting plate is connected with the second conveying assembly through a first sliding groove and used for conveying parts which do not pass through the height limiting plate and are H2 to the second conveying assembly, and one end, close to the first sliding groove, of the height limiting plate inclines to one side far away from the adjusting plate;

the rear end of the first conveying assembly positioned behind the height limiting plate is connected with the second conveying assembly through a second sliding chute, the second conveying assembly is used for conveying the part with the height H3 passing through the height limiting plate to the second conveying assembly, the second sliding chute is provided with at least two sliding rails with rectangular cross sections, the height H4 of the cross section of each sliding rail is larger than the length L/2 of the part, the width W2 of the cross section of each sliding rail is larger than the width W of the part and smaller than the height H2 of the part, and the front end of the second sliding chute connected with the first conveying assembly is a semicircular sliding chute part;

the second conveying assembly conveys the parts from the second chute and the first chute backwards through a second conveying belt, a screening plate is arranged on the second conveying assembly, the screening plate is positioned behind the joint of the second chute, the first chute and the second conveying belt and is used for screening the parts from the second chute and the first chute, one end face of the screening plate is connected with one side plate of the second conveying assembly, the other end face of the screening plate is an inclined face inclined towards the other side plate of the second conveying assembly, the minimum distance W3 between the inclined face and the other side plate of the second conveying assembly is larger than L1 and smaller than 1.2L 1, and the distance H5 between the lower surface of the screening plate and the second conveying belt is larger than H1 and smaller than 1.5H 1;

the tail end of the second conveying assembly is provided with a baffle which is positioned above the second conveying belt and is obliquely arranged and a third chute connected with the second conveying belt, and the baffle is used for conveying the parts passing through the screening plate to the third conveying assembly.

The further improved scheme in the technical scheme is as follows:

1. in the above scheme, the first conveyor belt, the second conveyor belt and the third conveyor belt are all driven by motors.

2. In the scheme, a part processing device is arranged behind the third conveyor belt.

3. In the above scheme, the inclined plane of the screening plate is an arc-shaped inclined plane.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses accurate metalwork processing is with fortune material device, its burring singleton automated processing who is applicable to the high added value part, especially be fit for singleton processing and examine the work piece of requirement entirely, device simple structure is compact, can realize the screening adjustment and the conveying of work piece position appearance, helps minimal access surgery chuck part to realize batchization, flexibility, automated manufacturing, changes the unloading mode of traditional dependence manual work, improves operating efficiency and quality.

2. The utility model discloses accurate metalworking is with fortune material device, it is located the first conveying subassembly rear end at limit for height board rear is connected with second conveying subassembly through a second spout for highly being H3 part through the limit for height board delivers to second conveying subassembly, the second spout has two at least cross-sections and is the slide of rectangle, the cross-sectional height H4 of slide is greater than the length L2 of part, cross-sectional width W2 are greater than the width W of part and are less than the high H2 of part, the front end that the second spout is connected with first conveying subassembly is semi-circular spout portion, through the setting of second spout, has not only realized the screening to the part, still adjusts the part that is not conform to the requirement, makes it accord with subsequent processing requirement, and need not to filter from the head again, has improved production efficiency greatly.

Drawings

FIG. 1 is a schematic diagram of the structure of the components on which the present invention is based;

FIG. 2 is a schematic diagram of the position and posture state of the part based on the present invention;

FIG. 3 is a schematic structural view of the conveying device for machining the precision metal part;

fig. 4 is a schematic structural view of a first conveying assembly in the conveying device for metal part processing of the present invention;

FIG. 5 is a schematic structural view of a semicircular chute part in the conveying device for metal part processing of the present invention;

fig. 6 is a schematic structural view of a second conveying assembly in the conveying device for metal part processing of the present invention;

fig. 7 is a side view of a second conveying assembly of the material conveying device for processing according to the present invention.

In the above drawings: 1. a first transfer assembly; 2. a second transfer assembly; 3. a third transfer assembly; 4. a second chute; 401. a semicircular chute part; 5. a first chute; 7. a third chute; 10. a part; 101. a substrate; 102. a raised strip portion; 103. a clip part; 11. a first conveyor belt; 12. an adjustment plate; 13. a height limiting plate; 21. a second conveyor belt; 22. screening the plate; 23. a baffle plate; 31. a third conveyor belt.

Detailed Description

Example 1: a material conveying device for machining a precise metal piece is used for a minimally invasive surgical chuck part 10, as shown in fig. 1, the part 10 comprises a base plate 101, two convex strip parts 102 and two wing clamping parts 103, wherein the two convex strip parts 102 are arranged on the upper surface of the base plate 101, the two convex strip parts 102 are arranged on two edges of the base plate 101 in the length direction in parallel, and the two wing clamping parts 103 are positioned at one end of the base plate 101 and are respectively connected with the two convex strip parts 102;

as shown in fig. 2, there are four possible positions of the part, when the lower surface of the base plate 101 of the part 10 contacts the conveyor belt, the height of the part 10 is H2, the height of the ridge 102 is H1, the total length of the part 10 is L, the length of the clip wing 103 is L1, and the width of the part 10 is W;

the height of the part 10 is H3 when the top surface of the clip wing 103 of the part 10 is in contact with the conveyor belt;

the material conveying device comprises a first conveying assembly 1, a second conveying assembly 2 and a third conveying assembly 3, wherein the height of a first conveyor belt 11 of the first conveying assembly 1 is higher than that of a second conveyor belt 21 of the second conveying assembly 2, and the height of the second conveyor belt 21 of the second conveying assembly 2 is higher than that of a third conveyor belt 31 of the third conveying assembly 3;

the front end of the first conveying assembly 1 is connected with the material box and is used for conveying the parts falling from the material box to the rear, an adjusting plate 12 is arranged in the middle of the first conveying assembly 1, the adjusting plate 12 is arranged above the first conveying belt 11 along the movement direction of the first conveying belt 11, and the space above the first conveying belt 11 is divided into two parts in the direction perpendicular to the movement direction of the first conveying belt 11;

a height limiting plate 13 which is obliquely arranged is arranged on the first conveying assembly 1 and behind the adjusting plate 12, two ends of the height limiting plate 13 are respectively connected with two side plates of the first conveying assembly 1, the height limiting plate 13 is arranged above the first conveying belt 11, the distance between the height limiting plate 13 and the conveying belt is larger than H3 and smaller than H2, the friction coefficient of the height limiting plate 13 is smaller than that of the conveying belt of the first conveying assembly 1, the first conveying belt 11 arranged on the front end surface of the height limiting plate 13 is connected with the second conveying assembly 2 through a first sliding groove 5 and used for conveying parts 10 which do not pass through the height limiting plate 13 and are H2 to the second conveying assembly 2, and one end, close to the first sliding groove 5, of the height limiting plate 13 inclines to one side far away from the adjusting plate 12;

the rear end of the first conveying assembly 1 positioned behind the height limiting plate 13 is connected with the second conveying assembly 2 through a second chute 4, the second chute 4 is used for conveying the parts 10 with the height H3 passing through the height limiting plate 13 to the second conveying assembly 2, the second chute 4 is provided with at least two chutes with rectangular sections, the section height H4 of each chute is larger than the length L/2 of each part 10, the section width W2 of each chute is larger than the width W of each part 10 and is smaller than the height H2 of each part 10, and the front end of the second chute 4 connected with the first conveying assembly 1 is a semicircular chute part 401;

the second conveying assembly 2 conveys the parts 10 from the second chute 4 and the first chute 5 to the rear through the second conveyor belt 21, a screening plate 22 is arranged on the second conveying assembly 2, the screening plate 22 is positioned behind the joint of the second chute 4 and the first chute 5 with the second conveyor belt 21 and is used for screening the parts 10 from the second chute 4 and the first chute 5, one end surface of the screening plate 22 is connected with one side plate of the second conveying assembly 2, the other end surface of the screening plate 22 is an inclined surface inclined towards the other side plate of the second conveying assembly 2, the minimum distance W3 between the inclined surface and the other side plate of the second conveying assembly 2 is greater than L1 and less than 1.2L 1, and the distance H5 between the lower surface of the screening plate 22 and the second conveyor belt 21 is greater than H1 and less than 1.5H 1;

the second conveyor assembly 2 is provided at its end with an obliquely arranged baffle 23 above the second conveyor belt 21 and a third chute 7 connected to the second conveyor belt 21 for feeding the parts 10 passing the screening plate 22 to the third conveyor assembly 3.

The inclined plane of the screening plate 22 is an arc inclined plane; the first conveyor belt 11, the second conveyor belt 21, and the third conveyor belt 31 are all driven by a motor.

Example 2: a material conveying device for machining a precise metal piece is used for a minimally invasive surgery chuck part 10, wherein the part 10 comprises a base plate 101, two convex strip parts 102 and two clamping wing parts 103, wherein the two convex strip parts 102 are arranged on the upper surface of the base plate 101, the two convex strip parts 102 are arranged on two edges of the length direction of the base plate 101 in parallel, and the two clamping wing parts 103 are positioned at one end of the base plate 101 and are respectively connected with the two convex strip parts 102;

when the lower surface of the substrate 101 of the component 10 contacts with the conveyor belt, the height of the component 10 is H2, the height of the raised strip 102 is H1, the total length of the component 10 is L, the length of the wing clamping part 103 is L1, and the width of the component 10 is W;

the height of the part 10 is H3 when the top surface of the clip wing 103 of the part 10 is in contact with the conveyor belt;

the material conveying device comprises a first conveying assembly 1, a second conveying assembly 2 and a third conveying assembly 3, wherein the height of a first conveyor belt 11 of the first conveying assembly 1 is higher than that of a second conveyor belt 21 of the second conveying assembly 2, and the height of the second conveyor belt 21 of the second conveying assembly 2 is higher than that of a third conveyor belt 31 of the third conveying assembly 3;

the front end of the first conveying assembly 1 is connected with the material box and is used for conveying the parts falling from the material box to the rear, an adjusting plate 12 is arranged in the middle of the first conveying assembly 1, the adjusting plate 12 is arranged above the first conveying belt 11 along the movement direction of the first conveying belt 11, and the space above the first conveying belt 11 is divided into two parts in the direction perpendicular to the movement direction of the first conveying belt 11;

a height limiting plate 13 which is obliquely arranged is arranged on the first conveying assembly 1 and behind the adjusting plate 12, two ends of the height limiting plate 13 are respectively connected with two side plates of the first conveying assembly 1, the height limiting plate 13 is arranged above the first conveying belt 11, the distance between the height limiting plate 13 and the conveying belt is larger than H3 and smaller than H2, the friction coefficient of the height limiting plate 13 is smaller than that of the conveying belt of the first conveying assembly 1, the first conveying belt 11 arranged on the front end surface of the height limiting plate 13 is connected with the second conveying assembly 2 through a first sliding groove 5 and used for conveying parts 10 which do not pass through the height limiting plate 13 and are H2 to the second conveying assembly 2, and one end, close to the first sliding groove 5, of the height limiting plate 13 inclines to one side far away from the adjusting plate 12;

the rear end of the first conveying assembly 1 positioned behind the height limiting plate 13 is connected with the second conveying assembly 2 through a second chute 4, the second chute 4 is used for conveying the parts 10 with the height H3 passing through the height limiting plate 13 to the second conveying assembly 2, the second chute 4 is provided with at least two chutes with rectangular sections, the section height H4 of each chute is larger than the length L/2 of each part 10, the section width W2 of each chute is larger than the width W of each part 10 and is smaller than the height H2 of each part 10, and the front end of the second chute 4 connected with the first conveying assembly 1 is a semicircular chute part 401;

the second conveying assembly 2 conveys the parts 10 from the second chute 4 and the first chute 5 to the rear through the second conveyor belt 21, a screening plate 22 is arranged on the second conveying assembly 2, the screening plate 22 is positioned behind the joint of the second chute 4 and the first chute 5 with the second conveyor belt 21 and is used for screening the parts 10 from the second chute 4 and the first chute 5, one end surface of the screening plate 22 is connected with one side plate of the second conveying assembly 2, the other end surface of the screening plate 22 is an inclined surface inclined towards the other side plate of the second conveying assembly 2, the minimum distance W3 between the inclined surface and the other side plate of the second conveying assembly 2 is greater than L1 and less than 1.2L 1, and the distance H5 between the lower surface of the screening plate 22 and the second conveyor belt 21 is greater than H1 and less than 1.5H 1;

the second conveyor assembly 2 is provided at its end with an obliquely arranged baffle 23 above the second conveyor belt 21 and a third chute 7 connected to the second conveyor belt 21 for feeding the parts 10 passing the screening plate 22 to the third conveyor assembly 3.

The inclined plane of the screening plate 22 is an arc inclined plane; a processing device for the parts 10 is provided behind the third conveyor belt 31.

When the part conveying device is used, parts in the material box fall onto the first conveying belt, when the parts pass through the adjusting plate, the adjusting plate gives a perturbation to the parts, the postures of the parts are adjusted to be one of 4 poses, the parts in the 4 poses move backwards to the height limiting plate along with the first conveying belt, the parts in the two poses with the height H3 pass through the height limiting plate, the parts in the two poses with the height H2 slide down to the second conveying belt through the first sliding chute, the parts in the two poses with the height H2 move backwards to the screening plate along with the second conveying belt, the parts in one pose with the front clamping wing part pass through the screening plate and slide down to the third conveying assembly through the third sliding chute, and therefore the parts in the only pose required by subsequent processing are obtained;

further, the parts which do not pass through the height limiting plate and are in two postures of H2 pass through the second chute, are adjusted to be in two postures of H3 and are also conveyed to the second conveyor belt for subsequent screening.

When the material conveying device for machining the precise metal part is adopted, the material conveying device is suitable for automatic deburring single-part machining of parts with high added values, particularly suitable for single-part machining and full inspection of workpieces with requirements, simple and compact in structure, capable of realizing screening adjustment and transmission of workpiece poses, beneficial to realizing batch, flexible and automatic manufacturing of minimally invasive surgery chuck parts, capable of changing the traditional loading and unloading mode depending on manual operation and capable of improving the operation efficiency and quality;

in addition, through the setting of second spout, not only realized the screening to the part, still adjusted the part that does not conform to the requirement, made it accord with subsequent processing requirement, and need not to follow the head and filter again, improved production efficiency greatly.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (4)

1. The utility model provides a precision metal parts machining is with fortune material device which characterized in that: the minimally invasive surgical chuck part (10) comprises a base plate (101), two convex strip parts (102) and two clamping wing parts (103), wherein the two convex strip parts (102) are arranged on the upper surface of the base plate (101), the two convex strip parts (102) are arranged at two edges of the length direction of the base plate (101) in parallel, and the two clamping wing parts (103) are positioned at one end of the base plate (101) and are respectively connected with the two convex strip parts (102);

when the lower surface of the substrate (101) of the component (10) is contacted with the conveyor belt, the height of the component (10) is H2, the height of the convex strip part (102) is H1, the total length of the component (10) is L, the length of the wing clamping part (103) is L1, and the width of the component (10) is W;

the height of the part (10) is H3 when the top surface of the wing portion (103) of the part (10) contacts the conveyor belt;

the conveying device comprises a first conveying assembly (1), a second conveying assembly (2) and a third conveying assembly (3), wherein the height of a first conveyor belt (11) of the first conveying assembly (1) is higher than that of a second conveyor belt (21) of the second conveying assembly (2), and the height of the second conveyor belt (21) of the second conveying assembly (2) is higher than that of a third conveyor belt (31) of the third conveying assembly (3);

the front end of the first conveying assembly (1) is connected with the material box and used for conveying the parts falling from the material box to the rear, an adjusting plate (12) is arranged in the middle of the first conveying assembly (1), the adjusting plate (12) is arranged above the first conveying belt (11) along the movement direction of the first conveying belt (11), and the space above the first conveying belt (11) is divided into two parts in the direction perpendicular to the movement direction of the first conveying belt (11);

a height limiting plate (13) which is obliquely arranged is arranged on the first conveying assembly (1) and behind the adjusting plate (12), two ends of the height limiting plate (13) are respectively connected with two side plates of the first conveying assembly (1), the height limiting plate (13) is arranged above the first conveying belt (11), the distance between the height limiting plate (13) and the conveyor belt is larger than H3 and smaller than H2, the friction coefficient of the height limiting plate (13) is smaller than that of the conveyor belt of the first conveying assembly (1), the first conveyor belt (11) positioned at the front end surface of the height limiting plate (13) is connected with the second conveying assembly (2) through a first chute (5), for feeding parts (10) of height H2 that have not passed through the height-limiting plate (13) to the second transfer assembly (2), one end of the height limiting plate (13) close to the first sliding chute (5) inclines to one side far away from the adjusting plate (12);

the rear end of a first conveying assembly (1) positioned behind the height limiting plate (13) is connected with a second conveying assembly (2) through a second sliding chute (4) and is used for conveying the parts (10) with the height of H3 passing through the height limiting plate (13) to the second conveying assembly (2), the second sliding chute (4) is provided with at least two sliding ways with rectangular sections, the section height H4 of each sliding way is larger than the length L/2 of each part (10), the section width W2 of each sliding way is larger than the width W of each part (10) and is smaller than the height H2 of each part (10), and the front end of the second sliding chute (4) connected with the first conveying assembly (1) is a semicircular sliding chute (401);

the second conveying component (2) conveys the parts (10) from the second chute (4) and the first chute (5) to the rear through a second conveying belt (21), the second conveying component (2) is provided with a screening plate (22), the screening plate (22) is positioned behind the joint of the second chute (4), the first chute (5) and the second conveying belt (21), for screening the parts (10) coming from the second chute (4) and the first chute (5), one end face of the screening plate (22) is connected with one side plate of the second conveying assembly (2), the other end face of the screening plate (22) is an inclined surface inclined towards the other side plate of the second conveying assembly (2), and the minimum distance W3 between the inclined surface and the other side plate of the second conveying assembly (2) is more than L1 and less than 1.2L 1, the distance H5 between the lower surface of the screen plate (22) and the second conveyor belt (21) is greater than H1 and less than 1.5 × H1;

the tail end of the second conveying assembly (2) is provided with a baffle (23) which is positioned above the second conveying belt (21) and is arranged in an inclined mode and a third sliding chute (7) connected with the second conveying belt (21), and the baffle is used for conveying the parts (10) passing through the screening plate (22) to the third conveying assembly (3).

2. The precision metal part machining material handling device of claim 1, wherein: the first conveyor belt (11), the second conveyor belt (21) and the third conveyor belt (31) are all driven by a motor.

3. The precision metal part machining material handling device of claim 1, wherein: and a processing device of the part (10) is arranged behind the third conveyor belt (31).

4. The precision metal part machining material handling device of claim 1, wherein: the inclined plane of the screening plate (22) is an arc inclined plane.

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