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CN-224227036-U - Fermentation material self-circulation temperature control disturbance mechanism

CN224227036UCN 224227036 UCN224227036 UCN 224227036UCN-224227036-U

Abstract

The utility model discloses a self-circulation temperature control disturbance mechanism for fermentation materials, which comprises a mounting plate, wherein the upper center of the mounting plate is connected with a hollow shaft through a bearing, the outer side of the hollow shaft is connected with a connecting rod, a cavity is arranged in the connecting rod, the cavity is communicated with the hollow shaft, a spiral strip is connected to the connecting rod, a conveying pipe is connected below the spiral strip, a micropore nozzle is arranged on the conveying pipe, and heat conducting oil is arranged in the hollow shaft.

Inventors

  • ZHU GUOBAO
  • ZHANG XIN
  • ZHANG HAO
  • YANG YANHAI
  • LU BAOJIE
  • HUANG LIANG
  • LI ZUOMING
  • An Yanhao
  • HAN XIAOYU
  • YIN WEN
  • TA NA
  • ZHENG WENKAI
  • LI HUA

Assignees

  • 宁夏博瑞科技有限公司
  • 宁夏农垦牛羊肉食品有限公司
  • 宁夏一加禾牧业有限公司

Dates

Publication Date
20260512
Application Date
20250516

Claims (9)

  1. 1. The utility model provides a fermentation material self-loopa control by temperature change disturbance mechanism, a serial communication port, including mounting panel (1), center department is connected with cavity axle (2) through the bearing on mounting panel (1), cavity axle (2) outside is connected with connecting rod (3), inside cavity (4) that are equipped with of connecting rod (3), cavity (4) are linked together with cavity axle (2), be connected with spiral strip (5) on connecting rod (3), spiral strip (5) below is connected with conveyer pipe (6), be equipped with micropore nozzle (7) on conveyer pipe (6), inside conduction oil that is equipped with of cavity axle (2).
  2. 2. The fermentation material self-circulation temperature control disturbance mechanism according to claim 1, wherein a heating rod (9) is arranged inside the hollow shaft (2), the top end of the heating rod (9) is connected with a connecting cover (10), the connecting cover (10) is connected with the hollow shaft (2) through bolts, a temperature sensor (11) is arranged inside the hollow shaft (2), the temperature sensor (11) is connected with a controller (12) through a wire, and the controller (12) is connected with the heating rod (9) through a wire.
  3. 3. The self-circulation temperature-control disturbance mechanism for fermentation materials according to claim 1, wherein one end of the conveying pipe (6) penetrates through the hollow shaft (2) and the connecting cover (10) to be connected with the connecting pipe (13), one end of the connecting pipe (13) is connected with the filter (14), and one side of the filter (14) is connected with the air compressor (16) through the air inlet pipe (15).
  4. 4. A fermentation material self-circulation temperature-control disturbance mechanism according to claim 3, wherein the connecting pipe (13) is provided with a pressure regulating valve (17).
  5. 5. The fermentation material self-circulation temperature control disturbance mechanism according to claim 1, wherein a driven gear (18) is connected to the hollow shaft (2), one side of the driven gear (18) is meshed with a driving gear (19), the driving gear (19) is connected with an output shaft of a driving motor (20), and the driving motor (20) is connected with a fixing frame (21).
  6. 6. A fermentation material self-circulation temperature control disturbance mechanism according to claim 5, wherein the fixing frame (21) is connected with the mounting plate (1).
  7. 7. The fermentation material self-circulation temperature control disturbance mechanism according to claim 1, wherein a tank body (22) is connected below the mounting plate (1) through bolts, and the hollow shaft (2) is arranged inside the tank body (22).
  8. 8. A fermentation material self-circulation temperature-control perturbation mechanism according to claim 3 is characterized in that the filter (14) and the air compressor (16) are arranged on one side of the mounting plate (1).
  9. 9. The self-circulation temperature-control disturbance mechanism for fermentation materials according to claim 1, wherein the mounting plate (1) is provided with a feed inlet (8).

Description

Fermentation material self-circulation temperature control disturbance mechanism Technical Field The utility model relates to the technical field of fermentation, in particular to a self-circulation temperature control disturbance mechanism for fermentation materials. Background Fermentation engineering plays a key role in various fields of food, medicine, environmental protection, agriculture and the like as an important branch of biotechnology. In the fermentation process, temperature control, material mixing uniformity and Dissolved Oxygen (DO) content are key factors influencing microorganism growth rate and product conversion efficiency, and particularly when a high-viscosity fermentation system is processed, the traditional stirring device often has the problems of uneven heat transfer, low mixing efficiency, insufficient dissolved oxygen and the like, so that the fermentation effect and the product quality are seriously restricted. The existing fermentation equipment is used for carrying out material mixing and temperature control operation in a mode of combining mechanical stirring with external heating, but the system is generally difficult to realize accurate control of the internal temperature of the material, and particularly local supercooling phenomenon easily occurs in a high-viscosity system, so that the activity of thalli is reduced or even deactivated. In addition, the traditional aeration mode is mostly dependent on the bottom gas distribution plate for gas supply, and uneven gas distribution is easy to cause overlarge dissolved oxygen gradient, so that good growth environment of aerobic microorganisms is limited. For the problems in the related art, no effective solution has been proposed at present. Disclosure of utility model Aiming at the problems in the related art, the utility model provides a self-circulation temperature control disturbance mechanism for fermentation materials, so as to overcome the technical problems in the prior related art. For this purpose, the utility model adopts the following specific technical scheme: The utility model provides a fermentation material self-loopa control by temperature change disturbance mechanism, includes the mounting panel, and center department is connected with the cavity axle through the bearing on the mounting panel, and the cavity axle outside is connected with the connecting rod, and the inside cavity that is equipped with of connecting rod is linked together with the cavity axle, is connected with the spiral strip on the connecting rod, and the spiral strip below is connected with the conveyer pipe, is equipped with micropore nozzle on the conveyer pipe, and the inside conduction oil that is equipped with of cavity axle. Further, the inside heating rod that is equipped with of cavity axle, the heating rod top is connected with the junction cap, and the junction cap is connected with the cavity axle through the bolt, and the inside temperature sensor that is equipped with of cavity axle, temperature sensor are connected with the controller through the wire, and the controller is connected through the wire with the heating rod. Further, one end of the conveying pipe penetrates through the hollow shaft and the connecting cover to be connected with the connecting pipe, one end of the connecting pipe is connected with the filter, and one side of the filter is connected with the air compressor through the air inlet pipe. Further, a pressure regulating valve is arranged on the connecting pipe. Further, a driven gear is connected to the hollow shaft, one side of the driven gear is meshed with a driving gear, the driving gear is connected with an output shaft of a driving motor, and the driving motor is connected with a fixing frame. Further, the mount is connected with the mounting panel. Further, a tank body is connected below the mounting plate through bolts, and the hollow shaft is arranged inside the tank body. Further, the filter and the air compressor are arranged on one side of the mounting plate. Further, a feeding port is arranged on the mounting plate. The beneficial effects of the utility model are as follows: (1) The device is characterized in that heat conduction oil is introduced into the hollow shaft and the hollow cavity, the heating rod is arranged to heat the heat conduction oil, and a closed-loop temperature control system is formed by matching the temperature sensor and the controller, so that the temperature of the hollow shaft and the connecting component thereof can be monitored and regulated in real time. In the rotation process of the hollow shaft and the connecting rod, the surface of the hollow shaft is fully contacted with materials, heat is uniformly transferred to the inner part of the whole tank body, local overheating or cold area generation is effectively avoided, the stability of the fermentation process is improved, and by arranging the spiral strips, the material can be guided to flow along the spiral di