CN219566511U - Direct vibration runner material distributing structure with high compatibility - Google Patents

Abstract

The utility model is suitable for the field of automatic production equipment, and provides a direct vibration runner material distribution structure with high compatibility, which comprises a direct vibration assembly, wherein one end of the direct vibration assembly is connected with a vibration disc, the direct vibration assembly comprises a direct vibration runner plate driven by a direct vibrator, a material inlet area, a material storage area, a material distribution area and a material discharge area are sequentially arranged on the direct vibration runner plate, the material inlet area consists of a plurality of first runners, an inlet of each first runner is connected with a material outlet of the vibration disc, the material distribution area consists of a plurality of second runners, one end of the material storage area is communicated with an outlet of each first runner, the other end of the material storage area is communicated with an inlet of each second runner, and the material discharge area is arranged at an outlet of each second runner; carry out categorised transportation through setting up pan feeding district, storage district, partition material district and ejection of compact district to the product, through setting up the second runner of different specifications, compatible multiple different specification products, accomplish one and go out many effects, satisfy automated production's requirement, and simple structure, further reduction in production cost.

Description

Direct vibration runner material distributing structure with high compatibility

Technical Field

The utility model belongs to the field of automatic production equipment, and particularly relates to a direct vibration runner material distributing structure with high compatibility.

Background

The conventional structure of the direct vibration runner generally connects an electromagnet with 220V alternating current to vibrate the electromagnet, and the electromagnet drives the linear track to move through a spring piece, so that products are conveyed. The direct vibration runner structure in the current market can realize one outlet or two outlets only through one electromagnet and a spring piece, namely, one feeding hole can only correspond to one discharging hole, and can only carry out classified transportation on products with one specification, so that the compatibility is low; if one-out-two or one-out-more is needed, the corresponding number of electromagnets and spring pieces are needed to be added for realizing, so that the volume of the direct vibration channel feeding structure is greatly increased, and the production cost is further increased.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art and provides a direct vibration runner material distributing structure with high compatibility.

The utility model is realized in the following way: the utility model provides a high direct-vibration runner feed divider structure of compatibility, is applied to disk class product, includes the direct-vibration subassembly, the one end of direct-vibration subassembly is connected with the vibration dish, the direct-vibration subassembly includes the direct-vibration runner board of being driven by the direct-vibration ware, be equipped with pan feeding district, storage district, feed divider district and ejection of compact district on the direct-vibration runner board in proper order, the pan feeding district comprises a plurality of first runners, each the entry of first runner all with the discharge gate of vibration dish is connected, the feed divider district comprises a plurality of second runners, the one end of storage district with each the export of first runner communicates with each other, the other end with each the entry of second runner communicates with each other, the exit of every second runner is located to the ejection of compact district.

Further, a central flow dividing block is arranged on the direct vibration flow channel plate, the central flow dividing block is arranged along the center line of the storage area, and a plurality of second flow channels are uniformly distributed on two sides of the central flow dividing block.

Further, the inlets of the second flow channels are tightly attached and connected, and each second flow channel is inclined in a direction away from the central flow dividing block by taking the inlet of the second flow channel as a fixed point.

Further, the inclined second flow passage forms an angle with the central split block of between 10 ° and 12 °.

Further, two first oblique sides are arranged on one side, close to the openings of the second flow channels, of the storage area, openings of the second flow channels are arranged between the two first oblique sides, and a second oblique side corresponding to each first oblique side is arranged on one end, close to the storage area, of the central flow dividing block.

Further, an included angle between each first inclined edge and the corresponding matched second inclined edge is 120 degrees.

Further, the vertical vibration flow channel plate is further provided with a height adjusting assembly, and the height adjusting assembly is used for enabling the height of the vertical vibration flow channel plate to be matched with the height of the vibration disc.

Further, the height adjusting assembly comprises a bottom plate, a vertical first adjusting plate is arranged on the bottom plate, a second adjusting plate is detachably connected to the first adjusting plate, and a mounting plate for mounting the direct vibrator is arranged on the second adjusting plate.

According to the direct vibration runner material distribution structure with high compatibility, provided by the utility model, products are classified and transported by arranging the material inlet area, the material storage area, the material distribution area and the material outlet area, and the products with different specifications can be compatible by arranging the second runners with different specifications in the material distribution area, so that the effect of one-out-of-many products is achieved, the requirement of automatic production can be well met, the structure is simple, and the production cost is further reduced.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

The following drawings are only for purposes of illustration and explanation of the present utility model and are not intended to limit the scope of the utility model.

Fig. 1 is a schematic view of the structure provided by the present utility model.

Fig. 2 is a schematic structural view of the direct vibration flow channel plate according to the present utility model.

FIG. 3 is a schematic view of the locations of the feed zone, the storage zone, the dividing zone, and the discharge in the present utility model.

FIG. 4 is a schematic illustration of the dimensions of a direct-vibration flow channel according to the present utility model.

Fig. 5 is a schematic view of the structure of the height adjusting assembly according to the present utility model.

Reference numerals illustrate: 1. a vibration plate; 2. a direct vibrator; 3. a direct vibration runner plate; 31. a feeding area; 311. a first flow passage; 32. a storage area; 321. a first oblique side; 33. a material dividing area; 331. a second flow passage; 34. a discharge zone; 35. a central shunt block; 351. a second oblique side; 4. a height adjustment assembly; 41. a bottom plate; 42. a first adjustment plate; 43. a second adjusting plate; 44. and (3) mounting a plate.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1-5, the utility model discloses a direct vibration runner material distributing structure with high compatibility, which is particularly applied to wafer products. The flow channel dividing structure directly shakes the subassembly including directly shaking, the one end that directly shakes the subassembly is connected with vibration dish 1, directly shake the subassembly and include by the direct flow channel board 3 that shakes of the 2 drives of direct vibrator, further, directly shake and still be equipped with high adjusting part 4 on the flow channel board 3, be used for making the height of flow channel board 3 that directly shakes with the high looks adaptation of vibration dish 1. Specifically, the height adjusting assembly 4 includes the bottom plate 41, be equipped with vertical first regulating plate 42 on the bottom plate 41, be connected with the second regulating plate 43 on the first regulating plate 42 in a detachable way, be equipped with on the second regulating plate 43 and be used for installing the mounting panel 44 of direct vibrator 2, dismantle first regulating plate 42 with behind the second regulating plate 43, will the position of direct vibration runner board 3 with behind the position of vibration dish 1 corresponds the parallel and level, again this position connection first regulating plate 42 with second regulating plate 43 can fix the direct vibration runner board 3 with the relative position between the vibration dish 1, ensure the smooth transportation of product, just the direct vibration runner board 3 can adapt to the vibration dish 1 of different specifications, the adaptability is high.

The direct vibration flow channel plate 3 is sequentially provided with a feeding area 31, a storage area 32, a dividing area 33 and a discharging area 34, and the vibration disc 1 is specifically connected with the feeding area 31 in a matched mode. The product is initially located in the vibration disc 1, the product enters the feeding area 31 through the vibration disc 1, the product enters the storage area 32 through the feeding area 31, products of various specifications are filled in the storage area 32 at this time, various products can enter the material dividing area 33 for classification, and when the products are matched with the corresponding type areas, the products can smoothly enter the discharging area 34, so that the material dividing effect is achieved.

Specifically, the feeding area 31 is composed of a plurality of first flow channels 311, at least one first flow channel 311 is provided, an inlet of each first flow channel 311 is connected with a discharge hole of the vibration disc 1, one end of the storage area 32 is communicated with an outlet of each first flow channel 311, each product enters the first flow channel 311 under the action of the vibration disc 1 and then enters the storage area 32 through the first flow channels 311, after the product enters the storage area 32, under the action of the direct vibrator 2, the stacked products can be separated, the products are ensured to be independently moved one by one, overlapping transportation of the products is avoided, and the products can be smoothly moved to the distribution area 33. The material dividing area 33 is composed of a plurality of second flow channels 331, the other end of the material storing area 32 is communicated with the inlet of each second flow channel 331, and the product after the primary treatment in the material storing area 32 enters the second flow channels 331. Specifically, a product with one specification corresponds to the second flow channel 331 with one specification, and by setting the second flow channels 331 with different specifications, the product with different specifications can be compatible. Preferably, the direct vibration runner plate 3 is provided with a central split block 35, the central split block 35 is specifically disposed in the material dividing area 33, the central split block 35 is disposed along a central line of the material storing area 32, and a plurality of second runners 331 are uniformly distributed on two sides of the central split block 35. Specifically, one side of the storage area 32 near the openings of the second flow channels 331 is provided with two first oblique sides 321, the openings of the second flow channels 331 are provided between the two first oblique sides 321, one end of the central flow dividing block 35 near the storage area 32 is provided with a second oblique side 351 corresponding to each first oblique side 321, that is, the storage area 32 forms two funnel-like shapes under the cooperation of the first oblique sides 321 and the second oblique sides 351, so that products in the storage area 32 can smoothly enter the second flow channels 331, and the phenomenon that the products are jammed in the storage area 32 is avoided. Further, the included angle between each first inclined edge 321 and the corresponding second inclined edge 351 is 120 °, as shown in fig. 4, so that the product can be ensured to enter the second flow channel 331 after stacking and separating, and the product is prevented from directly passing through the storage area 32 into the second flow channel 331 under the condition of stacking each other.

In addition, the inlets of the second flow channels 331 are all closely attached and connected, each second flow channel 331 is inclined away from the direction of the central flow dividing block 35 by taking the inlet of the second flow channel 331 as a fixed point, so that each product is ensured to smoothly enter the corresponding second flow channel 331 in the storage area 32, and the problem that the classification and transportation of the subsequent products are influenced due to the fact that the products are blocked in the position between the two second flow channels 331 is not in front is avoided. Meanwhile, in order to avoid the jamming phenomenon when the product is transited from the storage area 32 to the distribution area 33, the inclined second flow passage 331 and the central distribution block 35 have an included angle between 10 ° and 12 °, as shown in fig. 4.

The discharging area 34 is horizontally disposed at the outlet of each second flow passage 331, and the final product is discharged from the discharging area 34 after passing through the second flow passages 331, so that the sorting and transportation of the product can be completed. The feeding area 31, the storage area 32, the dividing area 33 and the discharging area 34 are matched with each other, so that a plurality of products with different specifications can be compatible, and the requirement of automatic production can be well met.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, or alternatives falling within the spirit and principles of the utility model.

Claims (8)

1. High direct vibration runner divides material structure of compatibility, its characterized in that: be applied to disk class product, including direct vibration subassembly, direct vibration subassembly's one end is connected with vibration dish (1), direct vibration subassembly includes direct vibration runner board (3) by direct vibrator (2) driven, be equipped with pan feeding district (31), storage district (32), branch material district (33) and ejection of compact district (34) on direct vibration runner board (3) in proper order, pan feeding district (31) are constituteed by a plurality of first runners (311), every the entry of first runner (311) all with the discharge gate of vibration dish (1) is connected, divide material district (33) to constitute by a plurality of second runners (331), the one end of storage district (32) and each the export of first runner (311) communicates with each other end and each the entry of second runner (331) communicates with each other, the exit of second runner (331) is located in ejection of compact district (34).

2. The high-compatibility direct vibration runner material distributing structure according to claim 1, wherein: the vertical vibration flow channel plate (3) is provided with a central flow distribution block (35), the central flow distribution block (35) is arranged along the central line of the storage area (32), and a plurality of second flow channels (331) are uniformly distributed on two sides of the central flow distribution block (35).

3. The high-compatibility direct vibration runner material distributing structure according to claim 2, wherein: the inlets of the second flow channels (331) are tightly attached and connected, and each second flow channel (331) is inclined in a direction away from the central flow dividing block (35) by taking the inlet of the second flow channel as a fixed point.

4. A high-compatibility direct vibration runner material distributing structure according to claim 3, wherein: the inclined second flow channel (331) forms an angle with the central split block (35) of between 10 ° and 12 °.

5. The high-compatibility direct vibration runner material distributing structure according to claim 2, wherein: two first bevel edges (321) are arranged on one side, close to the openings of the second flow channels (331), of the storage area (32), the openings of the second flow channels (331) are arranged between the two first bevel edges (321), and a second bevel edge (351) corresponding to each first bevel edge (321) is arranged on one end, close to the storage area (32), of the central flow dividing block (35).

6. The high-compatibility direct vibration runner material distributing structure according to claim 5, wherein: the included angle between each first inclined edge (321) and the corresponding matched second inclined edge (351) is 120 degrees.

7. The high-compatibility direct vibration runner material distributing structure according to claim 1, wherein: the vertical vibration flow channel plate (3) is further provided with a height adjusting component (4) which is used for enabling the height of the vertical vibration flow channel plate (3) to be matched with the height of the vibration disc (1).

8. The high-compatibility direct vibration runner material distributing structure according to claim 7, wherein: the height adjusting assembly (4) comprises a bottom plate (41), a vertical first adjusting plate (42) is arranged on the bottom plate (41), a second adjusting plate (43) is detachably connected to the first adjusting plate (42), and a mounting plate (44) for mounting the vibrator (2) is arranged on the second adjusting plate (43).