CN220116548U - Probiotic powder fermentation tank with temperature control function - Google Patents

Abstract

The utility model discloses a probiotic powder fermentation tank with a temperature control function, relates to the technical field of probiotic powder fermentation tanks, and aims to solve the problems that a heat jacket of the existing probiotic powder fermentation tank is heated in a steam heating mode, a steam generator connected with the heat jacket is needed to be matched for steam heating, so that equipment cost is high, in addition, steam cannot be effectively controlled in the heat jacket, temperature adjustment can be performed only through changing and discharging of steam, and cost is further improved. A tank cover is detachably arranged above the fermentation tank body through a flange; further comprises: the heat preservation heat jacket is arranged outside the fermentation tank body, a liquid inlet is formed in the outer wall of one side of the heat preservation heat jacket, and a liquid outlet is formed below the heat preservation heat jacket; the spiral heating pipes are arranged on the outer wall of the fermentation tank body through screws and are distributed in an up-down spiral mode.

Description

Probiotic powder fermentation tank with temperature control function

Technical Field

The utility model relates to the technical field of probiotic powder fermentation tanks, in particular to a probiotic powder fermentation tank with a temperature control function.

Background

Probiotics are active microorganisms beneficial to a host by colonizing the human body and changing the flora composition of a certain part of the host, and a fermentation tank refers to a device used for fermenting the microorganisms industrially. The main body of the device is a main cylinder made of stainless steel plates; the fermenter is heated by heating the outside of the fermenter with a heating jacket.

However, the existing heat jacket of the probiotic fermentation tank is heated by adopting a steam heating mode, and the steam heating firstly needs to be matched with a steam generator connected with the steam heating mode, so that the equipment cost is high.

Disclosure of Invention

The utility model aims to provide a probiotic powder fermentation tank with a temperature control function, so as to solve the problems that the prior probiotic fermentation tank heat jacket provided in the background art is heated by adopting a steam heating mode, a steam generator connected with the steam heating mode is needed to be matched for the steam heating mode, the equipment cost is high, in addition, the steam cannot be effectively controlled in the heat jacket, and the cost is further increased only by carrying out temperature regulation by changing and discharging the steam.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a probiotic powder fermenter with temperature control function, comprising: the fermentation tank comprises a fermentation tank body, wherein a tank cover is detachably arranged above the fermentation tank body through a flange;

further comprises:

the heat preservation heat jacket is arranged outside the fermentation tank body, a liquid inlet is formed in the outer wall of one side of the heat preservation heat jacket, and a liquid outlet is formed below the heat preservation heat jacket;

the spiral heating pipes are arranged on the outer wall of the fermentation tank body through screws and are spirally distributed up and down;

the temperature detection mechanism is detachably mounted above the tank cover through a flange and comprises a controller, and the output end of the controller is electrically connected with the control end of the spiral heating pipe.

Preferably, a temperature detection cylinder is arranged below the controller, and the lower end of the temperature detection cylinder extends to the inside of the fermentation tank body.

Preferably, the temperature detection cylinder is internally provided with a plurality of temperature sensors which are vertically arranged at intervals, the detection ends of the temperature sensors extend to the outside of the temperature detection cylinder, the rear end of each temperature sensor is provided with a wire arranging plate, and the output ends of the temperature sensors are electrically connected with the input end of the controller.

Preferably, the front end of the controller is provided with a display screen, and the input end of the display screen is electrically connected with the output end of the controller.

Preferably, the intermediate position department of cover top is installed driving motor through the screw, driving motor's output is provided with the transmission shaft, be provided with first stirring leaf on the outer wall of transmission shaft, the below of first stirring leaf is provided with the support frame, the second stirring leaf is installed through screw detachably to the one end of support frame.

Preferably, a discharging pipe is arranged below the fermentation tank body through a flange.

Preferably, a feeding pipe is arranged on one side of the driving motor, and an observation manhole is arranged on the other side of the driving motor.

Compared with the prior art, the utility model has the beneficial effects that:

1. the temperature detection mechanism is used for accurately measuring the temperature of the interior through the temperature detection cylinder and the temperature sensors in the interior, compared with the temperature measurement through a single temperature sensor, the temperature measurement is more accurate, when the temperature of the interior is higher than a set interval, the spiral heating pipe is closed, the interior liquid is slowly cooled, when the temperature of the interior is lower than the set interval, the spiral heating pipe is opened again to heat, the temperature control function is provided at the position of the heat jacket of the fermentation tank, compared with steam heating, the temperature change is more convenient for a user to adjust, the overall cost is lower than that of the steam heating, and the use of the fermentation tank is more convenient.

2. The temperature detection cylinder is used for installing a plurality of temperature sensors, the temperature sensors which are arranged at intervals up and down can detect the temperature of different depths in the tank, compared with the traditional single temperature sensor, the temperature detection cylinder is higher in temperature measurement accuracy, can reflect the temperature change of different tank depths, temperature data obtained by the temperature sensors are fed back to the controller, the controller carries out opening and closing operation on the spiral heating pipe according to whether the temperature is in a set interval, and the controller feeds back the data to the display screen for a user to know, so that the user can control the temperature more accurately and conveniently.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the internal structure of the fermenter according to the present utility model;

FIG. 3 is a schematic view of a partial structure of a temperature detecting cylinder according to the present utility model;

FIG. 4 is a schematic view of a part of the structure of a spiral heating pipe according to the present utility model;

in the figure: 1. a fermenter body; 101. a discharge pipe; 2. a can lid; 201. observing the manhole; 202. a feed pipe; 3. a heat preservation heat jacket; 301. a liquid inlet; 302. a liquid outlet; 4. a driving motor; 401. a transmission shaft; 402. a first stirring blade; 403. a support frame; 404. a second stirring blade; 5. a temperature detection mechanism; 501. a controller; 502. a display screen; 503. a temperature detection cylinder; 504. a temperature sensor; 505. a wire arrangement plate; 6. and (5) a spiral heating pipe.

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.

Referring to fig. 1-4, an embodiment of the present utility model is provided: a probiotic powder fermenter with temperature control function, comprising: the fermentation tank comprises a fermentation tank body 1, wherein a tank cover 2 is detachably arranged above the fermentation tank body 1 through a flange;

further comprises:

a heat-insulating heat jacket 3 installed outside the fermenter body 1, a liquid inlet 301 being provided on an outer wall of one side of the heat-insulating heat jacket 3, a liquid outlet 302 being provided below the heat-insulating heat jacket 3;

the spiral heating pipes 6 are arranged on the outer wall of the fermentation tank body 1 through screws and are spirally distributed up and down;

the temperature detection mechanism 5 is detachably arranged above the tank cover 2 through a flange, the temperature detection mechanism 5 comprises a controller 501, and the output end of the controller 501 is electrically connected with the control end of the spiral heating pipe 6;

the temperature detection mechanism 5, the heat preservation heat jacket 3 and the spiral heating pipe 6 are arranged to achieve the effect of enabling the fermentation tank heat jacket to have temperature control capability, specifically, the heat preservation heat jacket 3 is filled with liquid in advance through the liquid inlet 301, then the liquid inlet 301 is sealed, the spiral heating pipe 6 is opened, the spiral heating pipe 6 is used for heating internal liquid in a heating mode, in the heating process, the temperature at the heat jacket is transferred to the inside of the fermentation tank body 1, internal probiotics are enabled to be at a proper temperature, the temperature detection mechanism 5 is used for accurately measuring the temperature of the inside through the temperature detection barrel 503 and the plurality of temperature sensors 504 in the heat jacket, compared with the temperature measurement of the single temperature sensor 504, the temperature measurement is more accurate, when the internal temperature is higher than a set interval, the spiral heating pipe 6 is closed, the internal liquid is slowly cooled, when the internal temperature is lower than the set interval, the spiral heating pipe 6 is opened again, the temperature control function is achieved at the heat jacket of the fermentation tank, compared with steam heating, the temperature change is more convenient for a user, the whole cost is lower than that of the steam heating type, and the use is more convenient for the user.

Referring to fig. 2 and 3, a temperature detecting cylinder 503 is disposed below the controller 501, and the lower end of the temperature detecting cylinder 503 extends into the fermentation tank body 1, the temperature detecting cylinder 503 is used for installing a plurality of temperature sensors 504, and the temperature sensors 504 arranged at intervals up and down can detect temperatures at different depths in the tank, and compared with the conventional single temperature sensor 504, the temperature detecting cylinder has higher temperature detecting accuracy and can reflect temperature changes of different tank depths.

Referring to fig. 2 and 3, a plurality of temperature sensors 504 are installed in the temperature detecting cylinder 503 at intervals, the detecting ends of the temperature sensors 504 extend to the outside of the temperature detecting cylinder 503, a flat cable 505 is installed at the rear end of the temperature sensors 504, the output ends of the temperature sensors 504 are electrically connected with the input end of the controller 501, temperature data obtained by the temperature sensors 504 are fed back to the controller 501, and the controller 501 performs an opening and closing operation on the spiral heating tube 6 according to whether the temperature is in a set interval.

Referring to fig. 1 and 2, a display screen 502 is installed at the front end of the controller 501, and an input end of the display screen 502 is electrically connected to an output end of the controller 501, and the controller 501 feeds data back to the display screen 502 for the user to know.

Referring to fig. 1 and 2, a driving motor 4 is installed at a middle position above a tank cover 2 through a screw, a transmission shaft 401 is arranged at an output end of the driving motor 4, a first stirring blade 402 is arranged on an outer wall of the transmission shaft 401, a supporting frame 403 is arranged below the first stirring blade 402, a second stirring blade 404 is detachably installed at one end of the supporting frame 403 through the screw, the driving motor 4 is used for driving the transmission shaft 401 to rotate, the first stirring blade 402 rotates along with the rotation of the driving motor, probiotics at the upper part of the tank body are stirred, and the second stirring blade 404 stirs probiotics at the bottom of the tank body and improves the internal stirring effect through different stirring blades.

Referring to fig. 1 and 2, a discharge pipe 101 is installed below the fermenter body 1 through a flange, and the discharge pipe 101 is used for discharging internal probiotics.

Referring to fig. 1 and 2, a feeding pipe 202 is installed on one side of a driving motor 4, an observation manhole 201 is installed on the other side of the driving motor 4, the feeding pipe 202 is used for feeding, and the observation manhole 201 is convenient for a user to observe the internal condition.

Working principle: the temperature detection mechanism 5, the heat preservation heat jacket 3 and the spiral heating pipe 6 are arranged to achieve the effect of enabling the heat jacket of the fermentation tank to have temperature control capability, specifically, the heat preservation heat jacket 3 is filled with liquid in advance through the liquid inlet 301, then the liquid inlet 301 is sealed, the spiral heating pipe 6 is started, the spiral heating pipe 6 heats the internal liquid, in the heating process, the temperature at the heat jacket is transferred to the inside of the fermentation tank body 1, the internal probiotics are subjected to accurate temperature measurement through the temperature detection barrel 503 and the plurality of temperature sensors 504 in the internal probiotics, compared with the temperature measurement through the single temperature sensor 504, the temperature measurement is more accurate, when the internal temperature is higher than a set interval, the spiral heating pipe 6 is closed, the internal liquid is slowly cooled, when the internal temperature is lower than the set interval soon, the spiral heating pipe 6 is started again to heat, so that the heat jacket of the fermentation tank has a temperature control function, compared with steam heating, the temperature change is more convenient for a user to adjust, the whole cost is lower than that of steam heating, the use is more convenient for the user, the temperature detection cylinder 503 is used for installing a plurality of temperature sensors 504, the temperature sensors 504 which are arranged up and down at intervals can detect the temperature at different depths in the tank, compared with the traditional single temperature sensor 504, the temperature measurement accuracy is higher, the temperature change of different tank depths can be reflected, the temperature data obtained by the temperature sensor 504 is fed back to the controller 501, the controller 501 carries out the opening and closing operation on the spiral heating pipe 6 according to whether the temperature is in a set interval, the controller 501 feeds the data back to the display screen 502 for the user to know, the temperature control is more accurate and convenient for the user, the driving motor 4 is used for driving the transmission shaft 401 to rotate, the first stirring blade 402 rotates along with the rotation and is used for stirring probiotics at the upper part of the tank body, the second stirring blade 404 is used for stirring probiotics at the bottom of the tank body, and the stirring effect inside is improved through different stirring blades.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. The probiotics powder fermentation tank with the temperature control function comprises a fermentation tank body (1), wherein a tank cover (2) is detachably arranged above the fermentation tank body (1) through a flange;

the method is characterized in that: further comprises:

a heat-insulating heat jacket (3) which is arranged outside the fermentation tank body (1), wherein a liquid inlet (301) is arranged on the outer wall of one side of the heat-insulating heat jacket (3), and a liquid outlet (302) is arranged below the heat-insulating heat jacket (3);

the spiral heating pipes (6) are arranged on the outer wall of the fermentation tank body (1) through screws and are spirally distributed up and down;

the temperature detection mechanism (5) is detachably mounted above the tank cover (2) through a flange, the temperature detection mechanism (5) comprises a controller (501), and the output end of the controller (501) is electrically connected with the control end of the spiral heating pipe (6).

2. The probiotic powder fermenter with temperature control function according to claim 1, wherein: a temperature detection cylinder (503) is arranged below the controller (501), and the lower end of the temperature detection cylinder (503) extends to the inside of the fermentation tank body (1).

3. The probiotic powder fermenter with temperature control function according to claim 2, wherein: the inside of temperature detection section of thick bamboo (503) is installed a plurality of temperature sensor (504) of upper and lower interval arrangement, and the detection end of temperature sensor (504) extends to the outside of temperature detection section of thick bamboo (503), winding displacement board (505) is installed to the rear end of temperature sensor (504), and the output of temperature sensor (504) and the input electric connection of controller (501).

4. A probiotic powder fermenter with temperature control according to claim 3, wherein: the front end of the controller (501) is provided with a display screen (502), and the input end of the display screen (502) is electrically connected with the output end of the controller (501).

5. The probiotic powder fermenter with temperature control function according to claim 1, wherein: the novel stirring tank is characterized in that a driving motor (4) is arranged at the middle position above the tank cover (2) through a screw, a transmission shaft (401) is arranged at the output end of the driving motor (4), a first stirring blade (402) is arranged on the outer wall of the transmission shaft (401), a supporting frame (403) is arranged below the first stirring blade (402), and a second stirring blade (404) is detachably arranged at one end of the supporting frame (403) through the screw.

6. The probiotic powder fermenter with temperature control function according to claim 1, wherein: the lower part of the fermentation tank body (1) is provided with a discharging pipe (101) through a flange.

7. The probiotic powder fermenter with temperature control function according to claim 5, wherein: one side of the driving motor (4) is provided with a feeding pipe (202), and the other side of the driving motor (4) is provided with an observation manhole (201).