CN219352717U - Quantitative feeding system for live pig breeding - Google Patents

Abstract

The utility model relates to a quantitative feeding system for live pig breeding, which comprises a feeding trough, wherein a PLC (programmable logic controller) is arranged at the upper part of the feeding trough, a bracket A is arranged at the middle part of the feeding trough, a quantitative scale is fixedly arranged on the bracket A, a quantitative trough is sleeved on the quantitative scale, the PLC is in bidirectional signal connection with the quantitative scale, and the PLC is matched with the quantitative scale, a quantitative hopper and a conveying auger for use, so that live pig feeds with different quantities can be provided according to live pig breeding requirements and live pigs with different sizes, the effect of accurate quantitative feeding of live pig breeding is achieved, meanwhile, automatic control of the quantitative feeding of live pig breeding is realized, manual feeding is not needed, the labor intensity is reduced, and the intelligent level of live pig breeding equipment is improved.

Description

Quantitative feeding system for live pig breeding

Technical Field

The utility model relates to the technical field of live pig breeding, in particular to a quantitative feeding system for live pig breeding.

Background

Pig raising is an agricultural production activity, mainly achieves the effect of eating through raising pigs, is an important industry in agriculture in China, has an important effect on guaranteeing the safety supply of meat foods, and is changed from the traditional pig raising industry to the modern pig raising industry, and the breeding mode, the regional layout, the production mode and the production capacity are all obviously changed.

The pig raising industry is an important component part of the animal raising industry in China, the continuously-growing raising scale continuously improves the requirements on the performance of raising equipment, the pig raising industry in China is currently in the primary stage of the intelligent animal raising industry, and the feeding of pigs is a very important link in raising, but in the current pig raising industry, the most common feeding mode is the manual feeding mode, and although partial feeding tanks adopt quantitative feeding, in the actual using effect, the feeding can only be realized, and the effect of quantitative control cannot be completely achieved, so that a quantitative feeding system for the pig raising is provided to solve the problems.

Disclosure of Invention

The utility model aims to provide a quantitative feeding system for pig breeding, which aims to solve the problems that the pig breeding provided in the background technology is fed manually and the conventional feeding device cannot completely play a quantitative effect.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the quantitative feeding system for live pig breeding comprises a feeding trough, wherein a PLC (programmable logic controller) is arranged at the upper part of the feeding trough, a bracket A is arranged at the middle part of the feeding trough, a feed pool is arranged at the lower part of the feeding trough, a quantitative scale is fixedly arranged on the bracket A, a quantitative trough is sleeved on the quantitative scale, and the PLC is in bidirectional signal connection with the quantitative scale;

the feeding trough is characterized in that a conveying auger is arranged outside the feeding trough, a feed inlet and a discharge pipe are arranged on the conveying auger, the discharge pipe extends into the quantitative trough, an auger shaft on the conveying auger is fixedly connected with a motor, and the motor is electrically connected with the PLC;

the bottom of the quantitative groove is movably connected with a quantitative baffle plate, an electromagnetic lock is fixedly arranged on the quantitative baffle plate, and the electromagnetic lock is electrically connected with the PLC;

the electromagnetic lock, the quantitative scale and the motor are controlled by the PLC.

Further, the quantitative groove is composed of a support B and a quantitative hopper, wherein the support B is fixed at the top of the quantitative hopper, and the upper bottom surface of the inner side of the support B is completely sleeved on the upper surface of the quantitative scale.

Further, the quantitative baffle plate is movably connected with the bottom of the quantitative groove through a hinge.

Further, the quantitative hopper is made of metal.

Further, the upper part of the feed pool is semicircular.

Further, the bracket A is a square steel bracket.

Further, a support C is arranged at the bottom of the conveying auger.

Compared with the prior art, the utility model provides a quantitative feeding system for pig breeding, which has the following beneficial effects:

1. in the device, the quantitative weighing device is arranged in the feeding trough, and the feed with the set weight is weighed by the quantitative weighing device under the control of the PLC, so that the effect of accurate quantitative feeding of pig breeding is achieved, and the device can be used for providing different amounts of pig feed according to pig breeding requirements and pigs with different sizes.

2. In the device, the quantitative weighing, the quantitative hopper and the conveying auger are controlled by the PLC, so that the quantitative feeding of the pig breeding is automatically controlled, the manual feeding is not needed, the manual labor intensity is reduced, and the intelligent level of pig breeding equipment is improved.

3. In the device, the feeding of the pig breeding feed can be controlled by the PLC, the feed amount can be effectively controlled in the feeding process, the waste of the feed is reduced, and the pig breeding cost is indirectly reduced.

Drawings

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

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

FIG. 3 is a schematic structural diagram of a bracket A and a quantitative scale in the utility model;

FIG. 4 is a schematic diagram of the structure of the quantitative baffle and the electromagnetic lock according to the present utility model;

fig. 5 is a schematic structural view of a bracket B according to the present utility model.

In the figure: 1. the feeding device comprises a motor, 2, a feed inlet, 3, a conveying auger, 4, a discharge pipe, 5, an auger shaft, 6, a bracket C,7, a feeding trough, 8, a PLC controller, 9, a quantitative scale, 10, a bracket A,11, a quantitative trough, 11-1, a bracket B,11-2, a quantitative hopper, 12, a feed pool, 13, an electromagnetic lock, 14 hinges, 15 and a quantitative baffle.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. 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.

Examples:

referring to fig. 1-5, a quantitative feeding system for pig breeding in the embodiment comprises a feeding trough 7, wherein a PLC controller 8 is arranged at the upper part of the feeding trough 7, a bracket a10 is arranged at the middle part of the feeding trough, a feed pool 12 is arranged at the lower part of the feeding trough, a quantitative scale 9 is fixedly arranged on the bracket a10, a quantitative trough 11 is sleeved on the quantitative scale 9, and the PLC controller 8 is in bidirectional signal connection with the quantitative scale 9;

a conveying auger 3 is arranged outside the feeding trough 7, a feed inlet 2 and a discharge pipe 4 are arranged on the conveying auger 3, the discharge pipe 4 extends into the quantitative trough 11, an auger shaft 5 on the conveying auger 3 is fixedly connected with a motor 1, and the motor 1 is electrically connected with a PLC controller 8;

the bottom of the quantitative groove 11 is movably connected with a quantitative baffle 15, an electromagnetic lock 13 is fixedly arranged on the quantitative baffle 15, and the electromagnetic lock 13 is electrically connected with the PLC 8;

the electromagnetic lock 13, the quantitative scale 9 and the motor 1 are controlled by the PLC controller 8.

The quantitative tank 11 is composed of a bracket B11-1 and a quantitative hopper 11-2, wherein the bracket B11-1 is fixed at the top of the quantitative hopper 11-2, and the upper bottom surface of the inner side of the bracket B11-1 is completely sleeved on the upper surface of the quantitative scale 9.

The quantitative baffle 15 is movably connected to the bottom of the quantitative tank 11 by a hinge 14.

The quantitative hopper 11-2 is made of metal.

The upper portion of the feed tank 12 is semicircular.

The bracket a10 is a square steel bracket.

The bottom of the conveying auger 3 is provided with a bracket C6.

The working principle of the embodiment is as follows:

when the embodiment is used, firstly, the motor 1, the PC 8 (Mitsubishi FX3U-128 MR-ES-A) and the electromagnetic lock 13 (sucking disc type direct current HY-3016) are connected with an external power supply, so that the electromagnetic lock can be normally electrified for use, the quantitative scale 9 is cleared, whether the electromagnetic lock 13 (sucking disc type direct current HY-3016) is in an electrified closed state is checked, whether the quantitative baffle 15 on the quantitative hopper 11-2 is also in the closed state is checked, and meanwhile, the weight value of feed to be fed is set on the PC 8 (Mitsubishi FX3U-128 MR-ES-A) and can be set according to the specific value of the live pig to be fed; starting se:Sup>A motor 1, pouring feed into se:Sup>A conveying auger 3 from se:Sup>A feed inlet 2, conveying the feed to se:Sup>A discharge pipe 4 by an auger shaft 5 in the conveying auger 3 under the rotation of the motor 1, gradually increasing the weight of the feed in the quantitative hopper 11-2 when the feed falls into the quantitative hopper 11-2 from the discharge pipe 4, controlling the motor 1 to move downwards by the PC controller 8 (three-diamond FX 3U-MR-ES-A) under the action of feed gravity and simultaneously driving se:Sup>A bracket B11-1 to move downwards, completely sleeving the upper bottom surface on the inner side of the bracket B11-1 on the upper surface of se:Sup>A quantitative scale 9, applying downward pressure on the quantitative scale 9 by the bracket B11-1, enabling the quantitative scale 9 to accurately weigh the feed in the quantitative hopper 11-2, feeding the feed into the quantitative scale 9 by se:Sup>A feedback signal to the PC controller 8 (three-FX 3U-MR-ES-A) when the feed in the quantitative hopper 11-2 reaches se:Sup>A set weighing value, controlling the three-diamond FX 3U-MR-ES-A to stop rotating the motor 1, stopping the rotation of the motor 3U-MR-ES-A by the PC controller 8 (three-FX 3U-MR-128) when the feed in the quantitative hopper 11-2 falls into se:Sup>A direct current 30113, stopping the rotation of the feed hopper (13) and stopping the electromagnetic chuck 13) when the electromagnetic chuck is opened, and the electromagnetic chuck is opened for se:Sup>A direct current 30113, and the electromagnetic chuck is opened for se:Sup>A user to take out of the feed 13, the PC 8 (Mitsubishi FX3U-128 MR-ES-A) can control the electromagnetic lock 13 (sucking disc type direct current HY-3016) to be electrified, and simultaneously, the quantitative baffle 15 is manually closed, so that the electromagnetic lock 13 (sucking disc type direct current HY-3016) is adsorbed at the bottom of the quantitative hopper 11-2, the bottom of the quantitative hopper 11-2 is in se:Sup>A closed state, the PC 8 (Mitsubishi FX3U-128 MR-ES-A) re-controls the motor 1 to start, and the conveying auger 3 continuously conveys feed into the quantitative hopper 11-2 so as to finish quantitative feeding next time;

the live pig breeding is se:Sup>A long-term process, is commonly influenced by se:Sup>A plurality of factors such as environment, feed, breeding mode and the like, the risk of pig diseases in the live pig breeding is maximum, the death rate of pigs is higher, the death rate of pigs is directly related to the death of the breeding farm, however, most of the causes of pig diseases are closely related to the breeding environment, feed feeding and seasonal variation, the PC (Mitsubishi FX3U-128 MR-ES-A) is matched with the quantitative scale 9, the quantitative hopper 11-2 and the quantitative baffle 15, the live pig breeding can be accurately and quantitatively fed according to the temperature variation, day-and-night temperature difference and the feed type of the live pig breeding farm, the weight of the feed required to be fed is set on the PC (Mitsubishi FX3U-128 MR-ES-A), the specific numerical value can be set according to the size of the live pigs fed, meanwhile, the direct contact of the breeding workers on the live pig feed is avoided in the feed feeding process, and the death rate of the live pig diseases can be indirectly reduced.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a live pig is bred ration and throws edible system, includes feeding trough (7), its characterized in that: the feeding trough is characterized in that a PLC (programmable logic controller) is arranged at the upper part of the feeding trough (7), a bracket A (10) is arranged at the middle part of the feeding trough, a feed pool (12) is arranged at the lower part of the feeding trough, a quantitative scale (9) is fixedly arranged on the bracket A (10), a quantitative trough (11) is sleeved on the quantitative scale (9), and the PLC (8) is in bidirectional signal connection with the quantitative scale (9);

the feeding trough (7) is externally provided with a conveying auger (3), the conveying auger (3) is provided with a feed inlet (2) and a discharge pipe (4), the discharge pipe (4) extends into the quantitative trough (11), an auger shaft (5) of the conveying auger (3) is fixedly connected with a motor (1), and the motor (1) is electrically connected with the PLC (8);

the bottom of the quantitative groove (11) is movably connected with a quantitative baffle (15), an electromagnetic lock (13) is fixedly arranged on the quantitative baffle (15), and the electromagnetic lock (13) is electrically connected with the PLC (8);

the electromagnetic lock (13), the quantitative scale (9) and the motor (1) are controlled by the PLC (8).

2. The quantitative feeding system for live pig breeding according to claim 1, wherein: the quantitative tank (11) consists of a bracket B (11-1) and a quantitative hopper (11-2), wherein the bracket B (11-1) is fixed at the top of the quantitative hopper (11-2), and the upper bottom surface of the inner side of the bracket B (11-1) is completely sleeved on the upper surface of the quantitative scale (9).

3. The quantitative feeding system for live pig breeding according to claim 1, wherein: the quantitative baffle plate (15) is movably connected with the bottom of the quantitative groove (11) through a hinge (14).

4. The quantitative feeding system for live pig breeding according to claim 2, wherein: the quantitative hopper (11-2) is made of metal.

5. The quantitative feeding system for live pig breeding according to claim 1, wherein: the upper part of the feed pool (12) is semicircular.

6. The quantitative feeding system for live pig breeding according to claim 1, wherein: the support A (10) is a square steel support.

7. The quantitative feeding system for live pig breeding according to claim 1, wherein: a bracket C (6) is arranged at the bottom of the conveying auger (3).