CN219395921U

CN219395921U - Accurate automatic glassware of going down of skip formula

Info

Publication number: CN219395921U
Application number: CN202320189282.9U
Authority: CN
Inventors: 汪洪君
Original assignee: Sichuan Zhongcheng Zhenxing Animal Husbandry Equipment Co ltd
Current assignee: Sichuan Zhongcheng Zhenxing Animal Husbandry Equipment Co ltd
Priority date: 2023-02-13
Filing date: 2023-02-13
Publication date: 2023-07-25
Anticipated expiration: 2033-02-13

Abstract

The utility model relates to the technical field of poultry feeding, in particular to a skip type accurate automatic blanking device, which comprises a first motor, wherein a power output shaft of the first motor is connected with a transmission assembly, a fixing assembly is connected above the transmission assembly, a hopper is connected between two longitudinal brackets in the fixing assembly, a feeding assembly for conveying feed is arranged in the hopper, and a feeding speed control assembly for adjusting feeding speed is connected above the feeding assembly; the automatic feeding device adopts the first motor, the transmission assembly, the fixing assembly, the hopper and the feeding assembly to realize the automatic feeding function, and the feeding speed control assembly enables the accurate automatic feeding device of the skip type to accurately control the feeding speed, thereby controlling the feeding amount in unit time.

Description

Accurate automatic glassware of going down of skip formula

Technical Field

The utility model relates to the technical field of poultry feeding, in particular to a skip type accurate automatic blanking device.

Background

The traditional poultry feeding is mainly carried out by manual feeding, and the feed in the feeding basin is poured into the feeding trough, so that the feeding is laborious in the poultry feeding process, the growth of the poultry is not facilitated, and the waste of the feed is caused; meanwhile, in the feeding process, the feed is fed into the blanking pipe through the storage tank and falls into the feeding tank along the blanking pipe for the poultry feed, so that the feeding amount is not easy to be accurately controlled, and the feeding amount can not be adjusted according to different growth stages of the poultry. Aiming at the problems, we provide a bucket-type accurate automatic blanking device.

Disclosure of Invention

The utility model aims to overcome the defects and shortcomings of the prior art and provides a skip type accurate automatic blanking device.

The utility model relates to a bucket-type accurate automatic blanking device which comprises a first motor, wherein a power output shaft of the first motor is connected with a transmission assembly, a fixing assembly is connected above the transmission assembly, a hopper is connected between two longitudinal brackets in the fixing assembly, a material conveying assembly for conveying feed is arranged in the hopper, and a material conveying speed control assembly for adjusting the material conveying speed is connected above the material conveying assembly.

Further, the fixing component comprises a first connecting bracket above the first motor, and two first motor fixing plates are connected below the first connecting bracket; two ends of the first connecting support are respectively connected with a transverse support, a vertical support is connected above the transverse support, and a longitudinal support is connected above the vertical support.

Further, the transmission assembly comprises a first transmission shaft, the first transmission shaft is connected with second transmission shafts on two sides of the first motor through a first transmission belt, a rolling shaft is connected to one end, opposite to the first motor, of the second transmission shaft, a spiral metal strip is fixedly installed on the rolling shaft, a first roller is connected above the spiral metal strip, a plurality of bumps are uniformly distributed on the circumference of the radial direction of the first roller, a first transmission rod is connected in the axial direction of the first roller, one end, opposite to the first roller, of the first transmission rod is connected with a third transmission shaft, the third transmission shaft is connected with a fourth transmission shaft above through a second transmission belt, one end, close to the first roller, of the fourth transmission shaft is connected with a second transmission rod, one end, opposite to the fourth transmission shaft, of the second transmission rod is connected with a fifth transmission shaft, and the second transmission rod continuously extends through a transverse bracket to be connected with a transmission roller; the fifth transmission shaft is connected with the sixth transmission shaft through a third transmission belt, the sixth transmission shaft is connected with the transmission idler wheel through a third transmission rod connected with the sixth transmission shaft, and a sliding rail is connected below the idler wheel.

Further, the material conveying assembly comprises a transverse material conveying sleeve connected with the roller, the transverse material conveying sleeve penetrates through the side wall of the hopper to be connected with a transverse material conveying pipe in the hopper, and the discharge port end of the transverse material conveying pipe is positioned at the opposite end of the hopper to the transverse material conveying sleeve; the inner wall of the hopper is provided with a longitudinal conveying pipe, the opening end of the longitudinal conveying pipe is connected with three connecting movable rods, the inside of the longitudinal conveying pipe is provided with a second conveying rotating shaft, and six conveying plates are uniformly distributed on the circumference of the second conveying rotating shaft; the conveying device is characterized in that a conveying upper and lower conveying pipe is connected to the lower portion of the longitudinal conveying pipe, a transverse conveying pipe is connected to the lower portion of the conveying upper and lower conveying pipe, one end, close to a transverse conveying pipe sleeve, of the transverse conveying pipe is connected with a first conveying rotating shaft, the other end of the first conveying rotating shaft is connected with a conveying rod, and a plurality of spiral blades are arranged on the conveying rod.

Further, the feed speed control assembly comprises a third motor arranged on the side wall of the hopper; the other end of the connecting movable rod penetrates through the movable ring, the movable ring is connected with the horizontal control rod through the vertical control rod above, the horizontal control rod penetrates through the first limiting ring on the hopper to be connected with the U-shaped frame, the two opening ends of the U-shaped frame are connected with the second idler wheels, the second idler wheels are connected with the third idler wheels through grooves, the end, opposite to the horizontal control rod, of the third idler wheels is connected with the fourth transmission rod, the periphery of the fourth transmission rod is connected with the second limiting ring, and the periphery of the second limiting ring is connected with the fixed connection support; and one end of the fourth transmission rod, which is opposite to the third idler wheel, is connected with a second motor, and two sides of the second motor are connected with second motor connecting brackets.

After the structure is adopted, the utility model has the beneficial effects that: the utility model relates to a skip type accurate automatic blanking device, which adopts a combination installation of a first motor, a transmission assembly, a fixing assembly, a hopper and a material conveying assembly to realize the automatic blanking function, and the installation of a material conveying speed control assembly enables the skip type accurate automatic blanking device to accurately control the blanking speed, thereby controlling the feeding amount in unit time.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this application, illustrate and together with the description serve to explain the utility model, if necessary:

FIG. 1 is a top view of the present utility model;

FIG. 2 is a front view of the present utility model;

FIG. 3 is a schematic view of a material conveying assembly according to the present utility model;

FIG. 4 is a schematic view of the feed rate control assembly of the present utility model;

FIG. 5 is a schematic view of a portion of the structure of a transmission assembly according to the present utility model;

reference numerals illustrate:

a first motor 101;

a first connection bracket 201; a first motor fixing plate 202; a transverse bracket 203; a longitudinal support 204; a vertical support 205;

a first drive shaft 301; a first belt 302; a second drive shaft 303; a roller 304; a spiral metal strip 305; a first roller 306; a bump 307; a first transmission rod 308; a third drive shaft 309; a second belt 310; a fourth drive shaft 311; a second transmission lever 312; a fifth drive shaft 313; a third belt 314; a sixth drive shaft 315; a third transmission rod 316; a drive roller 317; a slide rail 318;

a lateral feed conveyor sleeve 401; a transverse feed conveyor pipe 402; a longitudinal feed conveyor pipe 403; a connecting movable bar 404; a feed bar 405; a helical blade 406; a first feed spindle 407; a second feed shaft 408; a feed plate 409; a feed up-down transfer tube 410;

a movable ring 501; a horizontal lever 502; a first stop collar 503; u-shaped rack 504; a second roller 505; a third roller 506; grooves 507; a fixed connection bracket 508; a second motor connection bracket 509; a second stop collar 510; a fourth transmission lever 511; a second motor 512; a vertical control lever 513; a third motor 514;

a hopper 601.

Description of the embodiments

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

As shown in fig. 1-5, the skip type precise automatic blanking device in this embodiment includes a first motor 101, a power output shaft of the first motor 101 is connected with a transmission assembly, a fixed assembly is connected above the transmission assembly, a hopper 601 is connected between two longitudinal brackets 204 in the fixed assembly, a feeding assembly for conveying feed is arranged in the hopper 601, and a feeding speed control assembly for adjusting feeding speed is connected above the feeding assembly.

Further, the fixing assembly comprises a first connecting bracket 201 above the first motor 101, and two first motor fixing plates 202 are connected below the first connecting bracket 201; two ends of the first connecting support 201 are respectively connected with a transverse support 203, a vertical support 205 is connected above the transverse support 203, and a longitudinal support 204 is connected above the vertical support 205.

Further, the transmission assembly includes a first transmission shaft 301, the first transmission shaft 301 is connected with a second transmission shaft 303 on two sides of the first motor 101 through a first transmission belt 302, one end, opposite to the first motor 101, of the second transmission shaft 303 is connected with a roller 304, a spiral metal strip 305 is fixedly installed on the roller 304, a first roller 306 is connected above the spiral metal strip 305, a plurality of bumps 307 are uniformly distributed on the circumference of the radial direction of the first roller 306, a first transmission rod 308 is connected in the axial direction of the first roller 306, one end, opposite to the first roller 306, of the first transmission rod 308 is connected with a third transmission shaft 309, the third transmission shaft 309 is connected with a fourth transmission shaft 311 above through a second transmission belt 310, one end, close to the first roller 306, of the fourth transmission shaft 311 is connected with a second transmission rod 312, one end, opposite to the fourth transmission shaft 311, of the second transmission rod 312 is connected with a fifth transmission shaft 313, and continuously extends through the transverse bracket 203 to be connected with a transmission roller 317; the fifth transmission shaft 313 is connected with a sixth transmission shaft 315 through a third transmission belt 314, the sixth transmission shaft 315 is connected with a transmission roller 317 through a third transmission rod 316 connected with the sixth transmission shaft, and a sliding rail 318 is connected below the roller 317.

Further, the material conveying assembly comprises a transverse material conveying sleeve 401 connected with the roller 304, the transverse material conveying sleeve 401 penetrates through the side wall of the hopper 601 to be connected with a transverse material conveying pipe 402 inside the hopper 601, and the material outlet end of the transverse material conveying pipe 402 is positioned at the end, opposite to the transverse material conveying sleeve 401, of the hopper 601; the inner wall of the hopper 601 is provided with a longitudinal conveying pipe 403, the opening end of the longitudinal conveying pipe 403 is connected with three connecting movable rods 404, the inside of the longitudinal conveying pipe 403 is provided with a second conveying rotating shaft 408, and six conveying plates 409 are uniformly distributed on the circumference of the second conveying rotating shaft 408; the lower part of the longitudinal conveying pipe 403 is connected with a conveying up-down conveying pipe 410, the lower part of the conveying up-down conveying pipe 410 is connected with a transverse conveying pipe 402, one end, close to the transverse conveying pipe sleeve 401, of the transverse conveying pipe 402 is connected with a first conveying rotating shaft 407, the other end of the first conveying rotating shaft 407 is connected with a conveying rod 405, and a plurality of spiral blades 406 are arranged on the conveying rod 405.

Further, the feed rate control assembly includes a third motor 514 mounted to a side wall of the hopper 601; the other end of the connecting movable rod 404 passes through the movable ring 501, the movable ring 501 is connected with the horizontal control rod 502 through the vertical control rod 513 above, the horizontal control rod 502 passes through the first limit ring 503 on the hopper 601 and is connected with the U-shaped frame 504, the two opening ends of the U-shaped frame 504 are connected with the second roller 505, the second roller 505 is connected with the third roller 506 through the groove 507, the opposite end of the third roller 506 to the horizontal control rod 502 is connected with the fourth transmission rod 511, the periphery of the fourth transmission rod 511 is connected with the second limit ring 510, and the periphery of the second limit ring 510 is connected with the fixed connection bracket 508; the opposite end of the fourth transmission rod 511 and the third roller 506 is connected with a second motor 512, and two sides of the second motor 512 are connected with a second motor connecting bracket 509.

The working principle of the utility model is specifically described as follows:

in the design, when the skip type precise automatic feeder works, a first motor 101 is started to drive a first transmission shaft 301 to rotate, the first transmission shaft 301 drives a second transmission shaft 303 to rotate through a first transmission belt 302, the second transmission shaft 303 drives a roller 304 connected with the first transmission shaft 301 to rotate, the roller 304 drives a first roller 306 and a convex block 307 to rotate through a spiral metal strip 305, the first roller 306 drives a first transmission rod 308 coaxial with the first roller 306 to rotate after rotating, the first transmission rod 308 drives a third transmission shaft 309 connected with the first roller 308 to rotate, the third transmission shaft 309 drives a fourth transmission shaft 311 to rotate through a second transmission belt 310, the fourth transmission shaft 311 drives a transmission roller 317 and a fifth transmission shaft 313 to rotate through a second transmission rod 312 connected with the fourth transmission shaft 311, the fifth transmission shaft 313 drives a sixth transmission shaft 315 to rotate through a third transmission belt 314, and the sixth transmission shaft 315 drives a roller 317 connected with the sixth transmission shaft through the first roller 306 to rotate; the rollers 317 on the slide rails 318 at two ends of the hopper 601 drive the transverse support 203 to move after rotating, the transverse support 203 drives the longitudinal support 204 and the vertical support 205 at the top to move, and the longitudinal support 204 drives the hopper 601 to move after moving, so that the skip type accurate automatic feeder can feed different food tanks.

In the design, a third motor 514 drives a second material conveying rotating shaft 408 and a material conveying plate 409 to rotate, and the upper feed is conveyed into a transverse material conveying pipe 402 through a material conveying up-down conveying pipe 410; after the roller 304 rotates, the first material conveying rotating shaft 407 connected with the roller is driven to rotate, after the first material conveying rotating shaft 407 rotates, the material conveying rod 405 coaxial with the roller is driven to rotate, and the material conveying rod 405 drives the helical blade 406 to rotate, so that feed is conveyed.

In this design, during the work of the material conveying speed control assembly, the second motor 512 drives the fourth transmission rod 511 to rotate, the fourth transmission rod 511 drives the third roller 506 connected with the fourth transmission rod to rotate, after the third roller 506 rotates, the second roller 505 matched with the groove 507 moves in the groove 507, the second roller 505 drives the horizontal control rod 502 to move back and forth along the axial direction of the first limiting ring 503 through the U-shaped frame 504, the horizontal control rod 502 drives the movable ring 501 to move back and forth through the vertical control rod 513 below the horizontal control rod 502, and the horizontal control rod is used for controlling the feed amount flowing into the longitudinal material conveying pipe 403, thereby controlling the material conveying speed and the feeding amount in unit time.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims

1. The utility model provides a accurate automatic glassware down of skip formula which characterized in that: the automatic feeding device comprises a first motor (101), wherein a power output shaft of the first motor (101) is connected with a transmission assembly, a fixing assembly is connected above the transmission assembly, a hopper (601) is connected between two longitudinal supports (204) in the fixing assembly, a feeding assembly for conveying feed is arranged in the hopper (601), and a feeding speed control assembly for adjusting feeding speed is connected above the feeding assembly.

2. The skip type precise automatic blanking device according to claim 1, wherein: the fixing assembly comprises a first connecting bracket (201) above the first motor (101), and two first motor fixing plates (202) are connected below the first connecting bracket (201); two ends of the first connecting support (201) are respectively connected with a transverse support (203), a vertical support (205) is connected above the transverse support (203), and a longitudinal support (204) is connected above the vertical support (205).

3. The skip type precise automatic blanking device according to claim 1, wherein: the transmission assembly comprises a first transmission shaft (301), the first transmission shaft (301) is connected with a second transmission shaft (303) on two sides of a first motor (101) through a first transmission belt (302), a roller (304) is connected to the opposite end of the second transmission shaft (303) to the first motor (101), a spiral metal strip (305) is fixedly installed on the roller (304), a first roller (306) is connected above the spiral metal strip (305), a plurality of bumps (307) are uniformly distributed on the circumference of the radial direction of the first roller (306), a first transmission rod (308) is connected in the axial direction of the first roller (306), a third transmission shaft (309) is connected to one end of the first transmission rod (308) opposite to the first roller (306), the third transmission shaft (309) is connected with a fourth transmission shaft (311) above through a second transmission belt (310), one end, close to the first roller (306), of the second transmission rod (312) is connected with a fifth transmission shaft (313) opposite to one end of the fourth transmission shaft (311), and the second transmission rod (312) continuously extends through a transverse transmission bracket (317); the fifth transmission shaft (313) is connected with the sixth transmission shaft (315) through a third transmission belt (314), the sixth transmission shaft (315) is connected with a transmission roller (317) through a third transmission rod (316) connected with the sixth transmission shaft, and a sliding rail (318) is connected below the roller (317).

4. The skip type precise automatic blanking device according to claim 1, wherein: the material conveying assembly comprises a transverse material conveying sleeve (401) connected with a roller (304), the transverse material conveying sleeve (401) penetrates through the side wall of the hopper (601) to be connected with a transverse material conveying pipe (402) in the hopper (601), and the discharge port end of the transverse material conveying pipe (402) is positioned at the opposite end of the hopper (601) to the transverse material conveying sleeve (401); the inner wall of the hopper (601) is provided with a longitudinal conveying pipe (403), the opening end of the longitudinal conveying pipe (403) is connected with three connecting movable rods (404), the inside of the longitudinal conveying pipe (403) is provided with a second conveying rotating shaft (408), and six conveying plates (409) are uniformly distributed on the circumference of the second conveying rotating shaft (408); the conveying device is characterized in that a conveying up-and-down conveying pipe (410) is connected below the longitudinal conveying pipe (403), a transverse conveying pipe (402) is connected below the conveying up-and-down conveying pipe (410), one end, close to the transverse conveying pipe sleeve (401), of the transverse conveying pipe (402) is connected with a first conveying rotating shaft (407), the other end of the first conveying rotating shaft (407) is connected with a conveying rod (405), and a plurality of spiral blades (406) are arranged on the conveying rod (405).

5. The skip type precise automatic blanking device according to claim 4, wherein: the feeding speed control assembly comprises a third motor (514) arranged on the side wall of the hopper (601); the other end of the connecting movable rod (404) penetrates through the movable ring (501), the movable ring (501) is connected with the horizontal control rod (502) through the vertical control rod (513) above, the horizontal control rod (502) penetrates through the first limiting ring (503) on the hopper (601) to be connected with the U-shaped frame (504), two opening ends of the U-shaped frame (504) are connected with the second roller (505), the second roller (505) is connected with the third roller (506) through the groove (507), one end, opposite to the horizontal control rod (502), of the third roller (506) is connected with the fourth transmission rod (511), the periphery of the fourth transmission rod (511) is connected with the second limiting ring (510), and the periphery of the second limiting ring (510) is connected with the fixed connection bracket (508); and one end, opposite to the third roller (506), of the fourth transmission rod (511) is connected with a second motor (512), and two sides of the second motor (512) are connected with second motor connecting brackets (509).