CN211003277U - Feed mechanism of transformer part processing - Google Patents

Abstract

The utility model particularly discloses a feeding mechanism for processing a variable-voltage component, which comprises a frame with an inclined table at the upper end and a storage platform, wherein the storage platform is fixed at the top end of the inclined table and is used for storing a large number of variable-voltage electronic elements; the third conveying device is connected to the lower end of the material storage table and is used for adjusting and conveying the variable-voltage electronic elements; the detection device is connected to the lower end of the third conveying device through the conveying channel and used for detecting parameters such as voltage and current of the electronic element; and the rotary discharging device is arranged below the detection device through the first conveying device and is used for stably adjusting and rotationally feeding the electronic elements. The utility model discloses a feed mechanism's compact structure can large batch transport electronic component to improve the orderliness and the discontinuity of carrying through the rotation type material loading, can also help electronic component heat dissipation, buffering etc. simultaneously.

Description

Feed mechanism of transformer part processing

Technical Field

The utility model relates to an electronic component processing technology field, concretely relates to feed mechanism of transformer part processing.

Background

Electronic components (electronic components), which are basic elements in electronic circuits, are usually individually packaged and have two or more leads or metal contacts. With the development of electronic technology, electronic component transformers are widely used as electrical components mounted on a circuit board, and compared with the conventional independent transformer, the electronic component transformer has the characteristics of miniaturization and high safety, and particularly, the structural arrangement of the transformer needs to be adapted to different application scenes.

However, the existing feeding mechanism for machining the transformer parts cannot orderly operate in a large scale, and has single function and low feeding efficiency.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome prior art can not operate in order in batches to the not enough of function singleness provides a feed mechanism of transformer part processing. The feeding mechanism for machining the variable-pressure parts is compact in structure and can rotate, convey and discharge materials stably, quickly and orderly in large batches.

The utility model discloses the above-mentioned problem that will solve is through following technical scheme in order to realize:

a feeding mechanism for machining a variable-voltage component comprises a rack with an inclined table at the upper end and a storage table, wherein the storage table is fixed at the top end of the inclined table and used for storing a large number of variable-voltage electronic elements; the third conveying device is connected to the lower end of the material storage table and is used for adjusting and conveying the variable-voltage electronic elements; the detection device is connected to the lower end of the third conveying device through the conveying channel and used for detecting parameters such as voltage and current of the electronic element; and the rotary discharging device is arranged below the detection device through the first conveying device and is used for stably adjusting and rotationally feeding the electronic elements.

Preferably, rotatory discharging device includes rotary part, spliced pole, column spinner, places platform, protection casing and support frame, the column spinner install in the protection casing and the platform is place to last or the lower extreme of column spinner all installs, the protection casing is installed on the slope bench, the support frame is installed on the slope bench through rotary part's bottom, rotary part's side passes the spliced pole and passes the protection casing and be connected with the column spinner. This scheme is through simple convenient rotatory discharging device's rotary part drive column rotation and is put the platform for put a rotatory electronic component of steadily carrying, and can cushion, cool off electronic component to a certain extent at rotatory conveying's in-process.

Preferably, the rotating column and the inclined table form an inclined angle of 60-75 degrees. This scheme can ensure that electronic component can rotate the transport steadily and speed and the convenience of ejection of compact are protected through the column spinner of certain suitable angle.

Preferably, the rotating component adopts a 180-degree or 360-degree rotating cylinder. The scheme can increase the discharging speed and the orderliness of the rotary discharging device through the rotary cylinder with 180 degrees or 360 degrees.

Preferably, the placing table is a placing table with a placing cavity matched with the electronic element of the transformer in the middle. This scheme is through the platform of placeeing of certain specification shape guarantee electronic component can rotate the transport steadily.

Preferably, the rotary discharging device further comprises a fourth conveying device, and the fourth conveying device is positioned at the output ends of the rotary discharging device and the first conveying device; the fourth conveying device comprises a fourth electric screw rod and a fourth sliding plate, the fourth electric screw rod is installed on the inclined table through a motor, and the fourth sliding plate is movably connected to the fourth electric screw rod and corresponds to the placing table and the first conveying device. According to the scheme, the speed and the state of the electronic element to be subjected to rotary discharging can be adjusted and conveyed through the fourth sliding plate of the fourth conveying device.

Preferably, the first conveying device comprises a first electric screw rod and a first sliding plate with a placing cavity, the first electric screw rod is mounted on the inclined table through a motor, and the first sliding plate is movably connected to the first electric screw rod and corresponds to the fourth sliding plate. According to the scheme, the electronic elements of the defective products are removed by the first conveying device, and then the electronic elements of the non-defective products are conveyed to the rotary discharging device.

Preferably, the device further comprises a defective product collecting chamber which is installed at the bottom of the first conveying device through an electromagnetic switch. The substandard product can be effectively recycled through the substandard product collection chamber in the scheme.

Preferably, the detection device comprises a side end flattening assembly, a top end flattening assembly and a detection assembly, the side end flattening assembly comprises a first fixing plate, a first flattening cylinder, a first flattening telescopic rod and a first mounting plate, and the first flattening cylinder is mounted at two symmetrical ends of the upper side of the first fixing plate and connected with the first mounting plate through the first flattening telescopic rod; the top end flattening assembly comprises a flattening electric screw rod, a flattening movable plate, a flattening support plate and a flattening support frame, the flattening electric screw rod is fixed on the flattening support frame and is positioned above the first mounting plate, the flattening movable plate is movably connected to the side end of the flattening electric screw rod, and the flattening support plate is fixed at the bottom of the flattening movable plate; the detection assembly comprises a detection display and a detection component, the detection display is installed on an inclined table, the detection component is installed on a flattening supporting plate or a first installing plate, the detection component comprises a current inductor or a voltage inductor or a power inductor, and the detection component is electrically connected with the detection display. This scheme can carry out the preliminary detection to electronic component through the side subassembly and the top subassembly and the detection subassembly that flatten.

Preferably, the detection device further comprises a second conveying device, the second conveying device comprises a telescopic cylinder, a connecting rod, a sliding guide rail and a second sliding plate, the telescopic cylinder is connected with the second sliding plate through the connecting rod, and the second sliding plate is movably connected to the sliding guide rail and close to the output end of the conveying channel. According to the scheme, the states such as the speed of the electronic element can be adjusted through the second sliding plate of the second conveying device, and preparation is made for subsequent preliminary detection.

Has the advantages that: after the structure of the utility model is adopted, because the structure is provided with the frame with the upper end being the inclined table, the power for conveying and discharging can be reduced to a certain extent according to the characteristic of the inclined table; and due to the arrangement of the storage table, the third conveying device, the detection device and the rotary discharging device, the electronic elements can be continuously conveyed through the storage table, then the third conveying device is used for adjusting and orderly conveying, and then the detection device preliminarily detects to quickly and stably convey non-defective products to the rotary discharging device for feeding, so that the feeding mechanism capable of conveying the electronic elements of the certified products in a large batch, orderly and stably in a multifunctional manner can be obtained.

Drawings

Fig. 1 is a top view main structure diagram of a feeding mechanism for machining a transformer component according to the present invention.

Fig. 2 is a side view of the main structure of a feeding mechanism for machining a transformer component according to the present invention.

Fig. 3 is a structural diagram of a rotary discharging device of a feeding mechanism for processing a transformer component according to the present invention.

Fig. 4 is a structural diagram of a detecting device of a feeding mechanism for machining a transformer component according to the present invention.

Fig. 5 is a structural diagram of a placing table of a rotary discharging device of a feeding mechanism for processing a transformer part.

Fig. 6 is a partial enlarged view of a feeding mechanism for machining a transformer component according to the present invention.

FIGS. 1 to 6: 1-a frame; 2-a tilting table; 3-a material storage table; 4-a third conveying device; 5-a detection device; 6-rotating the discharging device; 7-a second conveying device; 8-a transport channel; 9-a rotating member; 10-connecting column; 11-spin columns; 12-a placing table; 13-a protective cover; 14-a support frame; 15-a first conveying device; 16-a first electric screw rod; 17-a first sliding plate; 18-a placement cavity; 19-defective collection chamber; 20-an electromagnetic switch; 21-a side end flattening assembly; 22-a tip flattening assembly; 23-a first flattening cylinder; 24-a first flattening telescopic rod; 25-a first mounting plate; 26-a first fixing plate; 27-flattening the electric screw rod; 28-flattening the moving plate; 29-flattening the support plate; 30-flattening the support frame; 31-detection assembly (not shown); 32-detection display; 33-a detection component; 34-a telescopic cylinder; 35-a connecting rod; 36-a sliding guide rail; 37-a second sliding plate; 38-a fourth conveyor; 39-fourth electric screw; 40-fourth gliding board.

Detailed Description

The present invention will be described in further detail with reference to the following drawings and specific examples, which are not intended to limit the present invention in any manner.

Example 1:

the directional designations of "front", "rear", "left" and "right" described in this specification are determined according to the schematic drawings used in this specification.

The feeding mechanism for machining the variable-pressure component shown in fig. 1-6 comprises a frame 1 with an upper end provided with an inclined table 2, a material storage table 3, a third conveying device 4, a detection device 5 and a rotary discharging device 6, wherein the material storage table 3 is fixed at the top end of the inclined table 2, the third conveying device 4 is installed at the upper end of the inclined table 2 and connected with the material storage table 3, the detection device 5 is connected to the lower end of the third conveying device 4 through a conveying channel 8, and the rotary discharging device 6 is installed below the detection device 5 through a first conveying device 15; the rotary discharging device 6 comprises a rotary part 9, a connecting column 10, a rotary column 11, a placing table 12, a protective cover 13 and a supporting frame 14, wherein the rotary column 11 is installed in the protective cover 13, the placing table 12 is installed at the upper end and the lower end of the rotary column 11, the protective cover 13 is installed on the inclined table 2, the bottom of the rotary part 9 is installed on the inclined table 2 through the supporting frame 14, and the side end of the rotary part 9 penetrates through the protective cover 13 through the connecting column 10 to be connected with the rotary column 11; the rotating column 11 and the inclined table 2 form an inclined angle of 75 degrees; the rotating part 9 adopts a 180-degree rotating cylinder; the placing table 12 is a placing table with a placing cavity the middle part of which is matched with the electronic component of the transformer; the rotary discharging device 6 further comprises a fourth conveying device 38, and the fourth conveying device 38 is positioned at the output ends of the rotary discharging device 6 and the first conveying device 15; the fourth conveying device 38 comprises a fourth electric screw rod 39 and a fourth sliding plate 40, the fourth electric screw rod 39 is mounted on the tilting table 2 through a motor, and the fourth sliding plate 40 is movably connected to the fourth electric screw rod 39 and corresponds to the placing table 12 and the first conveying device 15; the first conveying device 15 comprises a first electric screw rod 16 and a first sliding plate 17 with a placing cavity 18, the first electric screw rod 16 is installed on the tilting table 2 through a motor, and the first sliding plate 17 is movably connected to the first electric screw rod 16 and corresponds to the fourth sliding plate 40; the detection device 5 comprises a side end flattening assembly 21, a top end flattening assembly 22 and a detection assembly 31, the side end flattening assembly 21 comprises a first fixing plate 26, a first flattening cylinder 23, a first flattening telescopic rod 24 and a first mounting plate 25, and the first flattening cylinders 23 are mounted at two symmetrical ends of the upper side of the first fixing plate 26 and connected with the first mounting plate 25 through the first flattening telescopic rod 24; the top end flattening assembly 22 comprises a flattening electric screw rod 27, a flattening moving plate 28, a flattening supporting plate 29 and a flattening supporting frame 30, the flattening electric screw rod 27 is fixed on the flattening supporting frame 30 and is positioned above the first mounting plate 25, the flattening moving plate 28 is movably connected to the side end of the flattening electric screw rod 27, and the flattening supporting plate 29 is fixed at the bottom of the flattening moving plate 28; the detection assembly 31 comprises a detection display 32 and a detection part 33, the detection display 32 is mounted on the tilting table 2, the detection part 33 is mounted on the flattening support plate 29 or the first mounting plate 25, the detection part 33 comprises a current sensor or a voltage sensor or a power supply sensor, and the detection part 33 is electrically connected with the detection display 32; the detection device 5 further comprises a second conveying device 7, the second conveying device 7 comprises a telescopic cylinder 34, a connecting rod 35, a sliding guide rail 36 and a second sliding plate 37, the telescopic cylinder 34 is connected with the second sliding plate 37 through the connecting rod 35, and the second sliding plate 37 is movably connected on the sliding guide rail 36 and close to the output end of the conveying channel 8; a defective product collection chamber 19, the defective product collection chamber 19 being installed at the bottom of the first conveyor 15 by an electromagnetic switch 20; the third conveying device 4 consists of a conveying channel and a plurality of groups of transverse conveying screw rods, and is used for conveying electronic elements in order in large batches, so that the non-interval property and the stability of conveying are guaranteed.

The working principle is as follows: firstly, a large quantity of electronic components of the barrel-packed transformer are placed on a material storage table, the electronic components are controlled to be transported and adjusted to a third conveying device under the action of a conveying assembly, a control switch and gravity, then parameters such as voltage or current and the like of each electronic component are detected through a detection device, defective products and classified products are separated, and then the electronic components are conveyed to a rotary discharging device for adjustment, cooling and rotary discharging.

The basic principle and the main features of the present invention and the advantages of the present invention have been shown and described above, and it should be understood by those skilled in the art that the present invention is not limited by the above embodiments, and the description in the above embodiments and the description is only illustrative of the principles of the present invention, and the present invention can be changed and modified in various ways without departing from the spirit and scope of the present invention, and the scope of the present invention is defined by the appended claims and their equivalents.

Claims (10)

1. A feeding mechanism for processing a variable-pressure part is characterized by comprising a frame (1) with an inclined table (2) at the upper end and a feeding mechanism,

the storage table (3) is fixed at the top end of the inclined table (2) and is used for storing a large number of variable-voltage electronic elements;

the third conveying device (4), the third conveying device (4) is connected to the lower end of the material storage table (3), and is used for adjusting and conveying the variable-voltage electronic elements;

the detection device (5) is connected to the lower end of the third conveying device (4) through a conveying channel (8) and is used for detecting voltage and current parameters of the electronic element;

the rotary discharging device (6) is installed below the detection device (5) through the first conveying device (15) and used for stably adjusting and rotationally feeding the electronic elements.

2. The feeding mechanism for processing the variable pressure components as claimed in claim 1, wherein the rotary discharging device (6) comprises a rotary component (9), a connecting column (10), a rotary column (11), a placing table (12), a protective cover (13) and a supporting frame (14), the rotary column (11) is installed in the protective cover (13), the placing table (12) is installed at the upper end or the lower end of the rotary column (11), the protective cover (13) is installed on the inclined table (2), the bottom of the rotary component (9) is installed on the inclined table (2) through the supporting frame (14), and the side end of the rotary component (9) penetrates through the protective cover (13) through the connecting column (10) to be connected with the rotary column (11).

3. The feeding mechanism for machining of variable-pressure parts according to claim 2, characterized in that the rotary column (11) and the inclined table (2) are inclined at an angle of 60-75 degrees.

4. The feeding mechanism for machining of the variable pressure parts as claimed in claim 2, characterized in that the rotating part (9) is a 180-degree or 360-degree rotating cylinder.

5. The feeding mechanism for machining the transformer component as claimed in claim 2, wherein the placing table (12) is a placing table provided with a placing cavity in the middle part, and the placing cavity is matched with an electronic component of the transformer.

6. A feeding mechanism for the machining of variable-pressure components according to claim 2, characterized in that said rotary outfeed device (6) further comprises a fourth conveyor device (38), said fourth conveyor device (38) being located at the output end of the rotary outfeed device (6) and of the first conveyor device (15); the fourth conveying device (38) comprises a fourth electric screw rod (39) and a fourth sliding plate (40), the fourth electric screw rod (39) is installed on the inclined table (2) through a motor, and the fourth sliding plate (40) is movably connected to the fourth electric screw rod (39) and corresponds to the placing table (12) and the first conveying device (15).

7. The feeding mechanism for machining of variable-pressure parts according to claim 1, characterized in that the first conveying device (15) comprises a first electric screw (16) and a first sliding plate (17) with a placing cavity (18), the first electric screw (16) is mounted on the tilting table (2) through a motor, and the first sliding plate (17) is movably connected to the first electric screw (16) and corresponds to the fourth sliding plate (40).

8. The feeding mechanism for the processing of the variable pressure parts according to claim 7, further comprising a reject collection chamber (19), wherein the reject collection chamber (19) is installed at the bottom of the first conveying device (15) by an electromagnetic switch (20).

9. The feeding mechanism for machining the variable-pressure parts is characterized in that the detection device (5) comprises a side end flattening assembly (21), a top end flattening assembly (22) and a detection assembly (31), the side end flattening assembly (21) comprises a first fixing plate (26), a first flattening air cylinder (23), a first flattening telescopic rod (24) and a first mounting plate (25), and the first flattening air cylinders (23) are mounted at two symmetrical ends of the upper side of the first fixing plate (26) and are connected with the first mounting plate (25) through the first flattening telescopic rod (24); the top end flattening assembly (22) comprises a flattening electric screw rod (27), a flattening moving plate (28), a flattening supporting plate (29) and a flattening supporting frame (30), the flattening electric screw rod (27) is fixed on the flattening supporting frame (30) and located above the first mounting plate (25), the flattening moving plate (28) is movably connected to the side end of the flattening electric screw rod (27), and the flattening supporting plate (29) is fixed at the bottom of the flattening moving plate (28); detection element (31) are including detecting display (32) and detection part (33), it installs on slope platform (2) to detect display (32), detection part (33) are installed on flattening backup pad (29) or first mounting panel (25), detection part (33) are including current inductor or voltage inductor or power inductor, detection part (33) and detection display (32) electric connection.

10. The feeding mechanism for machining of variable-pressure parts according to claim 9, characterized in that the detection device (5) further comprises a second conveying device (7), the second conveying device (7) comprises a telescopic cylinder (34), a connecting rod (35), a sliding guide (36) and a second sliding plate (37), the telescopic cylinder (34) is connected with the second sliding plate (37) through the connecting rod (35), and the second sliding plate (37) is movably connected with the sliding guide (36) and close to the output end of the conveying channel (8).

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