CN215302962U

CN215302962U - Genetically engineered mouse feed conditioner

Info

Publication number: CN215302962U
Application number: CN202121450217.4U
Authority: CN
Inventors: 马剑
Original assignee: Medicience Ltd
Current assignee: Medicience Ltd
Priority date: 2021-06-29
Filing date: 2021-06-29
Publication date: 2021-12-28
Anticipated expiration: 2031-06-29

Abstract

The utility model relates to a genetic engineering mouse feed conditioner, which comprises a steam generator, two sets of shells which are parallel up and down, two hollow rotating shafts and two speed reducing motors, wherein the top of each set of shell is provided with a feed inlet, the bottom of each set of shell is provided with a discharge outlet, the discharge outlet of the upper shell is communicated with the feed inlet of the lower shell, the hollow rotating shaft is rotatably arranged in each set of shell, a first helical blade, N hollow stirring rods and a second helical blade are sequentially arranged on the hollow rotating shaft from the feed inlet to the discharge outlet, one end of the hollow rotating shaft is provided with a rotary joint, the inlet of the rotary joint is connected with the outlet of the steam generator through a pipeline, and the other end of the hollow rotating shaft is in transmission connection with a power output shaft of one speed reducing motor through a belt transmission mechanism. The utility model ensures that the temperature in the conditioner is uniformly distributed; the feed is scattered and stirred by the hollow stirring rod, so that the feed is fully contacted with the steam.

Description

Genetically engineered mouse feed conditioner

Technical Field

The utility model relates to the technical field of feed production equipment, in particular to a genetically engineered mouse feed conditioner.

Background

The feed needs to be pretreated by a conditioner before pelleting or puffing in the feed industry, so that good pelleting performance is obtained. The feed absorbs water and raises the temperature in the conditioner through steam, so that the pelletizing performance is improved, and the efficient completion of the pelletizing or puffing process and the efficient utilization of raw materials are guaranteed.

The existing conditioner has the following problems: 1. steam enters the conditioner through a steam inlet arranged on the shell, so that the temperature distribution of the conditioner is not uniform, the temperature rise of the feed is different, and the feed conditioning effect is influenced; 2. through the extrusion of helical blade, the fodder bonds together, can not fully contact with steam.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the problems in the prior art and provides a genetically engineered mouse feed conditioner.

In order to achieve the technical purpose and achieve the technical effect, the utility model is realized by the following technical scheme:

the utility model provides a genetic engineering mouse fodder quenching and tempering ware, includes steam generator, two sets of casings, two hollow rotating shafts, two gear motor that are parallel from top to bottom, every set the top of casing is equipped with a feed inlet, every set the bottom of casing is equipped with a discharge gate, the discharge gate that is located the casing of top and the feed inlet intercommunication of the casing that is located the below, every set rotate a hollow rotating shaft of installation in the casing, install a first helical blade, N root hollow puddler, a second helical blade in proper order to the discharge gate from the feed inlet in the hollow rotating shaft, rotary joint is installed to one end of hollow rotating shaft, rotary joint's entry passes through the exit linkage of pipeline with steam generator, another end of hollow rotating shaft is connected through the power output shaft transmission of taking drive mechanism and a gear motor.

The spiral direction of the first spiral blade is the same as that of the second spiral blade, and the pitch of the first spiral blade is larger than that of the second spiral blade.

The back of the advancing direction of the hollow stirring rod is provided with a row of air outlets, and the air outlets, the hollow stirring rod inner cavity, the hollow rotating shaft inner cavity and the rotary joint are communicated in sequence.

The N hollow stirring rods are spirally arranged on the hollow stirring shaft, and the spiral direction of the spirally arranged hollow stirring rods is the same as the spiral direction of the first spiral blade.

And 1\ 4-1 \3N of the hollow stirring rods are provided with material pushing plates, and the material pushing plates are arranged on the front side of the advancing direction of the hollow stirring rods.

The casing comprises a double-layer thermal refining cylinder and two end covers, wherein the two ends of the double-layer thermal refining cylinder are respectively provided with one end cover through bolts, a bearing is arranged at the center of the outer side of each end cover, the head of the hollow rotating shaft is arranged in an inner ring of the bearing in an interference mode, one side of the double-layer thermal refining cylinder is provided with an access hole, an access cover is installed in the access hole in an embedded mode, and the access cover is connected with the double-layer thermal refining cylinder through bolts.

Wherein, a feeding funnel is fixedly connected to the feeding port of the upper shell.

And a plug for preventing steam leakage is arranged at one end of the hollow rotating shaft opposite to the rotary joint.

The utility model has the beneficial effects that: 1. arranging a hollow rotating shaft, connecting the hollow rotating shaft with a pipeline for conveying steam by using a rotating joint, mounting a hollow stirring rod with an air outlet on the rotating joint, and feeding the steam into a conditioner through the hollow rotating shaft and the hollow stirring rod to ensure that the temperature in the conditioner is uniformly distributed; 2. install first helical blade in proper order from the feed inlet to the discharge gate in the hollow rotating shaft, hollow stirring rod, second helical blade, utilize first helical blade to follow the fodder that the feed inlet got into to the regional propelling movement of hollow stirring rod, utilize hollow stirring rod to break up and stir the fodder, let fodder and steam fully contact, utilize the second spiral with the regional fodder of hollow stirring shaft to the discharge gate propelling movement, because first helical blade's pitch is greater than second helical blade's pitch, make the speed of second helical blade propelling movement fodder be greater than the speed of first helical blade propelling movement fodder, then can reduce the extrusion force that the regional fodder of hollow stirring shaft received, be favorable to hollow stirring shaft to break up the fodder and stir.

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 embodiment(s) of the utility model and together with the description serve to explain the utility model without limiting the utility model. In the drawings:

FIG. 1 is a schematic view of a conditioner according to the present invention;

FIG. 2 is a schematic structural view of a housing, a hollow rotating shaft and an access cover according to the present invention;

FIG. 3 is a schematic structural view of a hollow shaft according to the present invention.

The reference numbers in the figures illustrate: the device comprises a steam generator 1, a shell 2, a hollow rotating shaft 3, a speed reducing motor 4, a feed inlet 5, a discharge outlet 6, a first helical blade 7, a hollow stirring rod 8, a second helical blade 9, a rotary joint 10, a pipeline 11, a valve 12, a belt transmission mechanism 13, a driving belt pulley 14, a driven belt pulley 15, a transmission belt 16, an air outlet 17, a material pushing plate 18, a double-layer tempering cylinder 19, an end cover 20, a bearing 21, an access opening 22, an access cover 23, a feeding hopper 24 and a plug 25.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

As shown in fig. 1 to 3, the embodiment provides a genetically engineered mouse feed conditioner, which includes a steam generator 1, two sets of shells 2 parallel to each other, two hollow rotating shafts 3, and two speed reducing motors 4, wherein a feed inlet 5 is formed at the top of each set of shells 2, a feed hopper 24 is fixedly connected to the feed inlet 5 of the upper set of shells 2, a discharge outlet 6 is formed at the bottom of each set of shells 2, the discharge outlet 6 of the upper set of shells 2 is communicated with the feed inlet 5 of the lower set of shells 2, a hollow rotating shaft 3 is rotatably installed in each set of shells 2, a first helical blade 7, 40 hollow stirring rods 8, and a second helical blade 9 are sequentially installed on the hollow rotating shaft 3 from the feed inlet 5 to the discharge outlet 6, a rotary joint 10 is installed at one end of the hollow rotating shaft 3, an inlet of the rotary joint 10 is connected to an outlet of the steam generator 1 through a pipeline 11, a valve 12 is arranged on the pipeline 11 to control the steam flow transmitted to the shell 2, the other end of the hollow rotating shaft 3 is in transmission connection with a power output shaft of the speed reducing motor 4 through a belt transmission mechanism 13, and a plug 25 for preventing steam leakage is arranged at one end of the hollow rotating shaft 3 opposite to the rotary joint 10.

Arranging a hollow rotating shaft, connecting the hollow rotating shaft with a pipeline for conveying steam by using a rotating joint, mounting a hollow stirring rod with an air outlet on the rotating joint, and feeding the steam into a conditioner through the hollow rotating shaft and the hollow stirring rod to ensure that the temperature in the conditioner is uniformly distributed; 2. install first helical blade, hollow puddler, second helical blade in proper order from the feed inlet to the discharge gate in the hollow rotating shaft, utilize first helical blade to be from the fodder of feed inlet entering to the regional propelling movement of hollow puddler, utilize hollow puddler to break up and stir the fodder, let fodder and vapour fully contact, utilize the second spiral to carry out the regional fodder of hollow stirring shaft to the discharge gate propelling movement.

The belt transmission mechanism 13 comprises a driving belt pulley 14 arranged on a power output shaft of the speed reducing motor 4, a driven belt pulley 15 arranged on the hollow rotating shaft 3 and a transmission belt 16, wherein the transmission belt 16 is tensioned by the driving belt pulley 14 and the driven belt pulley 15.

The spiral direction of the first helical blade 7 is the same as the spiral direction of the second helical blade 9, and the pitch of the first helical blade 7 is greater than that of the second helical blade 9. Because the pitch of first helical blade is greater than the pitch of second helical blade for the speed of second helical blade propelling movement fodder is greater than the speed of first helical blade propelling movement fodder, then can reduce the extrusion force that the regional fodder of hollow mixing shaft received, is favorable to hollow mixing shaft to break up the fodder and stir.

The back of the advancing direction of the hollow stirring rod 8 is provided with a row of air outlets 17 to avoid the air outlets from being blocked by feed, and the air outlets 17, the inner cavity of the hollow stirring rod 8, the inner cavity of the hollow rotating shaft 3 and the rotary joint 10 are communicated in sequence.

The 40 hollow stirring rods 8 are spirally arranged on the hollow stirring shaft 3, and the spiral direction of the spirally arranged hollow stirring rods 8 is the same as the spiral direction of the first spiral blade 7. Guarantee that first helical blade, hollow puddler, second helical blade on the same hollow puddler are the same to the propelling movement direction of fodder.

The 10 hollow stirring rods 8 are provided with the material pushing plates 18, so that the power for pushing the feed in the hollow stirring rod area to the direction of the second spiral blade is increased, the feed is prevented from accumulating in the hollow stirring rod area, and the material pushing plates 18 are arranged on the front face of the advancing direction of the hollow stirring rods 8.

The shell 2 comprises a double-layer thermal refining cylinder 19 and two end covers 20, the two ends of the double-layer thermal refining cylinder 19 are respectively provided with one end cover 20 through bolts, a bearing 21 is arranged at the center of the outer side of each end cover 20, the head of the hollow rotating shaft 3 is arranged in an inner ring of the bearing 21 in an interference mode, one side of the double-layer thermal refining cylinder 19 is provided with an access opening 22, an access cover 23 is embedded in the access opening 22, and the access cover 23 is connected with the double-layer thermal refining cylinder 19 through bolts so as to be convenient for overhauling the inside of the double-layer thermal refining cylinder.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed.

Claims

1. A genetic engineering mouse feed conditioner is characterized in that: including steam generator, two sets of parallel's casing, two hollow rotating shaft, two gear motor about, every set the top of casing is equipped with a feed inlet, every set the bottom of casing is equipped with a discharge gate, the discharge gate that is located the casing of top and the feed inlet intercommunication of the casing that is located the below, every set rotate a hollow rotating shaft of installation in the casing, install a first helical blade, N hollow puddler, a second helical blade in proper order to the discharge gate from the feed inlet in the hollow rotating shaft, rotary joint is installed to one end of hollow rotating shaft, pipeline and steam generator's exit linkage is passed through in rotary joint's entry, another end of hollow rotating shaft is connected through the power output shaft transmission of taking drive mechanism and a gear motor.

2. The genetically engineered mouse feed conditioner of claim 1, wherein: the spiral direction of the first spiral blade is the same as that of the second spiral blade, and the pitch of the first spiral blade is larger than that of the second spiral blade.

3. The genetically engineered mouse feed conditioner of claim 1, wherein: the back of the advancing direction of the hollow stirring rod is provided with a row of air outlets, and the air outlets, the hollow stirring rod inner cavity, the hollow rotating shaft inner cavity and the rotary joint are communicated in sequence.

4. The genetically engineered mouse feed conditioner of claim 1, wherein: the N hollow stirring rods are spirally arranged on the hollow stirring shaft, and the spiral direction of the spirally arranged hollow stirring rods is the same as the spiral direction of the first spiral blade.

5. The genetically engineered mouse feed conditioner of claim 1, wherein: and 1\ 4-1 \3N of the hollow stirring rods are provided with material pushing plates, and the material pushing plates are arranged on the front side of the advancing direction of the hollow stirring rods.

6. The genetically engineered mouse feed conditioner of claim 1, wherein: the casing includes double-deck tempering section of thick bamboo, two end covers, an end cover is installed through the bolt respectively at double-deck tempering section of thick bamboo both ends, the bearing is installed at the outside center of end cover, the head interference of hollow rotating shaft is installed in the inner circle of bearing, one side of double-deck tempering section of thick bamboo is equipped with the access hole, inlay in the access hole and install the access cover, the access cover is connected with double-deck tempering section of thick bamboo with the bolt.

7. The genetically engineered mouse feed conditioner of claim 1, wherein: a feeding funnel is fixedly connected to the feeding hole of the upper shell.

8. The genetically engineered mouse feed conditioner of claim 1, wherein: and a plug for preventing steam from leaking is arranged at one end of the hollow rotating shaft opposite to the rotary joint.