CN210765331U - Yeast probiotic culture equipment - Google Patents

Abstract

The utility model discloses a yeast probiotic culture device, which comprises a bottom plate, a moving unit, a telescopic unit, a stirring unit and a sealing box, wherein two corresponding support rods are fixed at the front end of the upper side surface of the bottom plate, an incubator is fixed at the rear end of the upper side surface of the bottom plate, an opening is arranged on the upper side surface of the incubator, the moving unit comprises a fixed plate, a first motor, a sliding block, a threaded rod and a limiting rod, the fixed plate is fixed on the upper side surfaces of the two support rods, the first motor is installed on the upper side surface of the fixed plate, a threaded hole is arranged in the middle of the sliding block, the threaded rod is in threaded connection with the inner part of the threaded hole, the upper end surface of the threaded rod is connected with an output shaft of the first motor, the lower end of the threaded rod is rotatably connected on the upper side surface of the bottom plate, culture solution in, and the temperature can be automatically regulated and controlled.

Description

Yeast probiotic culture equipment

Technical Field

The utility model relates to a benefit fungus culture apparatus technical field specifically is a yeast benefit fungus culture apparatus.

Background

The probiotics is an active microorganism which is beneficial to a host and is formed by changing flora at a certain part of the host through colonization in a human body, bacteria or fungi which are beneficial to the human body and the animal body mainly comprise saccharomycetes, probiotic bacillus, clostridium butyricum, lactobacillus, bifidobacterium, actinomycetes and the like, the saccharomycetes have good probiotic characteristics of regulating intestinal tract balance, promoting feed conversion, improving organism immunity and the like, are mostly used as feed additives for livestock and poultry breeding, more saccharomycetes are researched to be saccharomyces cerevisiae, torula delbrueckii, candida, wilkholdhamia, pichia, saccharomyces boulardii, torulopsis, saccharomyces chevalieri, rhodotorula, schizosaccharomyces pombe and saccharomyces baumannii, the existing saccharomycetes culture equipment usually directly puts the strains into a culture dish or a culture tank for fermentation culture, however, when the existing culture equipment is used for culturing yeasts, a culture dish or a culture tank is usually fixed, probiotics are easy to precipitate to the bottom of the culture dish or the culture tank, the growth of the probiotics is influenced, and the internal temperature of the existing culture equipment cannot be automatically regulated.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome current defect, provide a yeast probiotic cultured equipment, can stir the inside culture solution of culture dish, avoid the bottom that probiotic deposited the culture dish to can regulate and control the temperature automatically, can effectively solve the problem in the background art.

In order to achieve the above object, the utility model provides a following technical scheme: a yeast probiotic culture device comprises a bottom plate, a moving unit, a telescopic unit, a stirring unit and a sealing box;

a bottom plate: two corresponding support rods are fixed at the front end of the upper side surface of the bottom plate, an incubator is fixed at the rear end of the upper side surface of the bottom plate, and an opening is formed in the upper side surface of the incubator;

a mobile unit: the movable unit comprises a fixed plate, a first motor, a sliding block, a threaded rod and a limiting rod, the fixed plate is fixed on the upper side surfaces of the two support rods, the first motor is installed on the upper side surface of the fixed plate, a threaded hole is formed in the middle of the sliding block, the threaded rod is connected with the internal threads of the threaded hole, the upper end surface of the threaded rod is connected with an output shaft of the first motor, the lower end of the threaded rod is rotatably connected onto the upper side surface of the bottom plate, a through hole is formed in the edge of the sliding block, the limiting rod is connected with the through hole in a sliding mode, the upper end surface of the limiting rod is fixed on the lower side surface of the fixed plate, the lower end surface of the limiting rod is fixed;

sealing the box: the sealing box is fixed on the rear side face of the sliding block, an opening is formed in the lower side face of the sealing box, and the sealing box and the incubator correspond to each other;

a telescopic unit: the telescopic unit comprises a first electric telescopic rod, a connecting block, a second electric telescopic rod and an installation block, the first electric telescopic rod is installed at the edge of the upper side face of the sealing box, a telescopic arm of the first electric telescopic rod is fixed on the upper side face of the connecting block, the connecting block is located inside the sealing box, the second electric telescopic rod is installed on the right side face of the connecting block, a telescopic arm of the second electric telescopic rod is fixed on the right side face of the installation block, and the stirring unit is driven to move through the telescopic unit;

a stirring unit: the stirring unit comprises a second motor, a rotating shaft and a stirring block, the second motor is arranged on the upper side surface of the mounting block, an output shaft of the second motor is fixed on the upper end surface of the rotating shaft, the stirring blocks are uniformly distributed on the circumferential surface of the rotating shaft, and strains and culture solution in the culture dish are stirred through the stirring unit;

wherein: still include PLC controller, temperature-sensing ware, mounting panel and culture dish, the PLC controller is installed on the right flank of incubator, the temperature-sensing ware is installed on the inside wall of incubator, the inside at the incubator is fixed to the mounting panel, the middle part of side is fixed with the culture dish on the mounting panel, external power source's output is connected to the input electricity of PLC controller, the input of first motor, first electric telescopic handle, second electric telescopic handle and second motor is connected to the output electricity respectively of PLC controller, the PLC controller is connected with the two-way electricity of temperature-sensing ware.

Further, still include heating wire and air-cooler, the heating wire is installed on the lower lateral wall of incubator, the mounting hole has been seted up to the limit portion of side on the seal box, the inside of mounting hole is fixed with the air-cooler, the output of PLC controller is connected to the equal electricity of input of heating wire and air-cooler, regulates and control the temperature of incubator inside through setting up heating wire and air-cooler.

Further, the exhaust pipe and the gauze are further included, the exhaust pipe is installed on the upper side face of the sealing box and communicated with the inner cavity of the sealing box, and the gauze is fixed on the upper end face of the exhaust pipe.

Further, still include the glass board, the fixed orifices has been seted up at the middle part of seal box, the inside of fixed orifices is fixed with the glass board, observes the condition inside the culture dish through the glass board.

Further, the incubator further comprises air inlets and a limiting ring, wherein the air inlets are uniformly distributed on the upper side surface of the mounting plate, and the limiting ring is fixed outside the incubator.

Compared with the prior art, the beneficial effects of the utility model are that: the yeast probiotic culture equipment has the following advantages:

1. the PLC controller controls the second electric telescopic rod to work, the second electric telescopic rod works to drive the mounting block to move leftwards, the mounting block moves leftwards to drive the rotating shaft to move leftwards, when the second electric telescopic rod extends to the maximum distance, the rotating shaft is positioned above the culture dish, then the PLC controller controls the first electric telescopic rod to work, the first electric telescopic rod works to drive the connecting block to move downwards, the connecting block moves downwards to drive the mounting block to move downwards, the mounting block moves downwards to drive the rotating shaft to move downwards, when the first electric telescopic rod extends to the maximum distance, the rotating shaft enters the interior of the culture dish, then the PLC controller controls the second motor to rotate, the second motor rotates to drive the rotating shaft to rotate, the rotating shaft rotates to drive the stirring block to rotate, thus stirring the strains and the culture solution in the culture dish and preventing the probiotics from precipitating to the bottom of the culture dish;

2. install the temperature-sensing ware inside the incubator and continuously detect the temperature inside the incubator, if find the inside temperature of incubator low when excessively, can be with signal transmission to the PLC controller, the PLC controller receives signal back control heating wire work, and the inside temperature of heating wire work reinforcing incubator, when the inside temperature of incubator is too high, the PLC controller will control air-cooler work, and air-cooler work reduces the inside temperature of incubator, makes through above device the utility model discloses can regulate and control the temperature automatically.

Drawings

FIG. 1 is a schematic front side view of the present invention;

fig. 2 is a schematic diagram of the mobile unit structure of the present invention;

fig. 3 is a schematic view of the structure of the telescopic unit of the present invention.

In the figure: 1 bottom plate, 2 bracing pieces, 3 incubator, 4 mobile unit, 41 fixed plates, 42 first motor, 43 sliding blocks, 44 threaded rods, 45 gag lever post, 5 flexible unit, 51 first electric telescopic handle, 52 connecting blocks, 53 second electric telescopic handle, 54 installation blocks, 6 stirring unit, 61 second motor, 62 pivot, 63 stirring block, 7 PLC controller, 8 seal box, 9 temperature-sensing ware, 10 heating wire, 11 mounting panels, 12 inlet ports, 13 culture dish, 14 blast pipe, 15 gauze, 16 glass plates, 17 spacing rings, 18 air-coolers.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a yeast probiotic culture device comprises a bottom plate 1, a moving unit 4, a telescopic unit 5, a stirring unit 6 and a sealing box 8;

bottom plate 1: two corresponding support rods 2 are fixed at the front end of the upper side surface of the bottom plate 1, an incubator 3 is fixed at the rear end of the upper side surface of the bottom plate 1, and an opening is formed in the upper side surface of the incubator 3;

the mobile unit 4: the moving unit 4 comprises a fixed plate 41, a first motor 42, a sliding block 43, a threaded rod 44 and a limiting rod 45, the fixed plate 41 is fixed on the upper side surfaces of the two support rods 2, the first motor 42 is installed on the upper side surface of the fixed plate 41, a threaded hole is formed in the middle of the sliding block 43, the threaded rod 44 is connected with the internal threads of the threaded hole, the upper end surface of the threaded rod 44 is connected with an output shaft of the first motor 42, the lower end of the threaded rod 44 is rotatably connected onto the upper side surface of the bottom plate 1, a through hole is formed in the edge of the sliding block 43, the limiting rod 45 is connected with the internal threads of the through hole in a sliding mode, the upper end surface of the limiting rod 45 is fixed on the lower side surface of the fixed plate;

and (4) sealing box 8: the sealing box 8 is fixed on the rear side surface of the sliding block 43, an opening is formed in the lower side surface of the sealing box 8, and the sealing box 8 corresponds to the incubator 3;

the telescopic unit 5: the telescopic unit 5 comprises a first electric telescopic rod 51, a connecting block 52, a second electric telescopic rod 53 and a mounting block 54, the first electric telescopic rod 51 is mounted at the edge of the upper side surface of the seal box 8, a telescopic arm of the first electric telescopic rod 51 is fixed on the upper side surface of the connecting block 52, the connecting block 52 is positioned inside the seal box 8, the second electric telescopic rod 53 is mounted on the right side surface of the connecting block 52, a telescopic arm of the second electric telescopic rod 53 is fixed on the right side surface of the mounting block 54, and the stirring unit 6 is driven to move through the telescopic unit 5;

the stirring unit 6: the stirring unit 6 comprises a second motor 61, a rotating shaft 62 and stirring blocks 63, wherein the second motor 61 is installed on the upper side surface of the installation block 54, an output shaft of the second motor 61 is fixed on the upper end surface of the rotating shaft 62, the stirring blocks 63 are uniformly distributed on the circumferential surface of the rotating shaft 62, and strains and culture solution in the culture dish 13 are stirred through the stirring unit 6;

wherein: still include PLC controller 7, temperature-sensing ware 9, mounting panel 11 and culture dish 13, PLC controller 7 is installed on the right flank of incubator 3, temperature-sensing ware 9 is installed on the inside wall of incubator 3, the inside at incubator 3 is fixed to mounting panel 11, the middle part of side is fixed with culture dish 13 on mounting panel 11, external power source's output is connected to PLC controller 7's input electricity, first motor 42 is connected to PLC controller 7's output electricity respectively, first electric telescopic handle 51, the input of second electric telescopic handle 53 and second motor 61, PLC controller 7 is connected with temperature-sensing ware 9 both-way electricity.

Wherein: still include heating wire 10 and air-cooler 18, heating wire 10 installs on the lower lateral wall of incubator 3, and the mounting hole has been seted up to the limit portion of side on the seal box 8, and the inside of mounting hole is fixed with air-cooler 18, and PLC controller 7's output is all connected to the input of heating wire 10 and air-cooler 18 electricity, regulates and control the inside temperature of incubator 3 through setting up heating wire 10 and air-cooler 18.

Wherein: the exhaust pipe 14 is arranged on the upper side face of the sealing box 8, the exhaust pipe 14 is communicated with the inner cavity of the sealing box 8, and the gauze 15 is fixed on the upper end face of the exhaust pipe 14.

Wherein: still include glass board 16, the fixed orifices has been seted up at the middle part of seal box 8, and the inside of fixed orifices is fixed with glass board 16, observes the inside condition of culture dish 13 through glass board 16.

Wherein: the incubator also comprises air inlet holes 12 and a limiting ring 17, wherein the air inlet holes 12 which are uniformly distributed are formed in the upper side surface of the mounting plate 11, and the limiting ring 17 is fixed outside the incubator 3.

When in use: strains and culture solution are sequentially placed inside a culture dish 13, then a PLC (programmable logic controller) 7 is used for controlling a first motor 42 to rotate, the first motor 42 rotates to drive a sliding block 43 to move downwards, the sliding block 43 moves downwards to drive a seal box 8 to move downwards, after the lower side surface of the seal box 8 is contacted with a limiting ring 17, the PLC 7 is used for controlling the first motor 42 to stop rotating, when the strains and the solution inside the culture dish 13 need to be stirred, a PLC 7 is used for controlling a second electric telescopic rod 53 to work, the second electric telescopic rod 53 works to drive an installation block 54 to move leftwards, the installation block 54 moves leftwards to drive a rotating shaft 62 to move leftwards, after the second electric telescopic rod 53 stretches to the maximum distance, the rotating shaft 62 is positioned above the culture dish 13, then the PLC 7 is used for controlling a first electric telescopic rod 51 to work, the first electric telescopic rod 51 works to drive a connecting block 52 to move downwards, the connecting block 52 moves downwards to drive the mounting block 54 to move downwards, the mounting block 54 moves downwards to drive the rotating shaft 62 to move downwards, when the first electric telescopic rod 51 extends to the maximum distance, the rotating shaft 62 enters the culture dish 13, then the second motor 61 is controlled to rotate through the PLC controller 7, the second motor 61 rotates to drive the rotating shaft 62 to rotate, the rotating shaft 62 rotates to drive the stirring block 63 to rotate, so that strains and culture solution in the culture dish 13 are stirred, meanwhile, the temperature sensor 9 arranged in the culture box 3 continuously detects the temperature in the culture box 3, if the temperature in the culture box 3 is too low, a signal is sent to the PLC controller 7, the PLC controller 7 controls the electric heating wire 10 to work after receiving the signal, the electric heating wire 10 works to enhance the temperature in the culture box 3, when the temperature in the culture box 3 is too high, the PLC controller 7 controls the air cooler 18 to work, the inside temperature of 18 work reduction incubators of air-cooler 3 makes through above device the utility model discloses can effectually stir the inside culture solution of culture dish, avoid the bottom that the probiotic deposited the culture dish to can regulate and control the temperature automatically.

It should be noted that the specific model of the PLC controller 7 disclosed in this embodiment is siemens S7-200, the air cooler 18 is an AD100-U evaporative air cooler manufactured by american companies, and the PLC controller 7 controls the first motor 42, the first electric telescopic rod 51, the second electric telescopic rod 52, the second motor 61, the heating wire 10 and the air cooler 18 to operate by a method commonly used in the prior art.

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

Claims (5)

1. The utility model provides a yeast probiotic cultivates equipment which characterized in that: comprises a bottom plate (1), a moving unit (4), a telescopic unit (5), a stirring unit (6) and a sealing box (8);

base plate (1): two corresponding support rods (2) are fixed at the front end of the upper side face of the bottom plate (1), an incubator (3) is fixed at the rear end of the upper side face of the bottom plate (1), and an opening is formed in the upper side face of the incubator (3);

mobile unit (4): the moving unit (4) comprises a fixed plate (41), a first motor (42), a sliding block (43), a threaded rod (44) and a limiting rod (45), the fixed plate (41) is fixed on the upper side surfaces of the two support rods (2), a first motor (42) is installed on the upper side surface of the fixed plate (41), a threaded hole is arranged in the middle of the sliding block (43), a threaded rod (44) is connected with the inner thread of the threaded hole, the upper end surface of the threaded rod (44) is connected with an output shaft of a first motor (42), the lower end of the threaded rod (44) is rotatably connected to the upper side surface of the bottom plate (1), the edge of the sliding block (43) is provided with a through hole, the inside of the through hole is connected with a limiting rod (45) in a sliding way, the upper end surface of the limiting rod (45) is fixed on the lower side surface of the fixing plate (41), the lower end face of the limiting rod (45) is fixed on the upper side face of the bottom plate (1);

seal box (8): the sealing box (8) is fixed on the rear side face of the sliding block (43), an opening is formed in the lower side face of the sealing box (8), and the sealing box (8) corresponds to the incubator (3);

expansion unit (5): the telescopic unit (5) comprises a first electric telescopic rod (51), a connecting block (52), a second electric telescopic rod (53) and a mounting block (54), the first electric telescopic rod (51) is mounted at the edge of the upper side surface of the seal box (8), a telescopic arm of the first electric telescopic rod (51) is fixed on the upper side surface of the connecting block (52), the connecting block (52) is positioned in the seal box (8), the second electric telescopic rod (53) is mounted on the right side surface of the connecting block (52), and a telescopic arm of the second electric telescopic rod (53) is fixed on the right side surface of the mounting block (54);

stirring unit (6): the stirring unit (6) comprises a second motor (61), a rotating shaft (62) and stirring blocks (63), the second motor (61) is installed on the upper side face of the installation block (54), an output shaft of the second motor (61) is fixed on the upper end face of the rotating shaft (62), and the stirring blocks (63) are uniformly distributed on the circumferential face of the rotating shaft (62);

wherein: still include PLC controller (7), temperature-sensing ware (9), mounting panel (11) and culture dish (13), install on the right flank of incubator (3) PLC controller (7), install on the inside wall of incubator (3) temperature-sensing ware (9), the inside at incubator (3) is fixed in mounting panel (11), the middle part of side is fixed with culture dish (13) on mounting panel (11), the output of external power source is connected to the input electricity of PLC controller (7), the input of first motor (42), first electric telescopic handle (51), second electric telescopic handle (53) and second motor (61) is connected to the output electricity respectively of PLC controller (7), PLC controller (7) are connected with temperature-sensing ware (9) two-way electricity.

2. The yeast probiotic culture apparatus of claim 1, wherein: still include heating wire (10) and air-cooler (18), install on the lower lateral wall of incubator (3) heating wire (10), the mounting hole has been seted up to the limit portion of side on seal box (8), the inside of mounting hole is fixed with air-cooler (18), the output of PLC controller (7) is all connected to the input electricity of heating wire (10) and air-cooler (18).

3. The yeast probiotic culture apparatus of claim 1, wherein: still include blast pipe (14) and gauze (15), blast pipe (14) are installed on the last side of seal box (8), blast pipe (14) communicate with each other with the inner chamber of seal box (8), be fixed with gauze (15) on the up end of blast pipe (14).

4. The yeast probiotic culture apparatus of claim 1, wherein: the glass sealing box is characterized by further comprising a glass plate (16), a fixing hole is formed in the middle of the sealing box (8), and the glass plate (16) is fixed inside the fixing hole.

5. The yeast probiotic culture apparatus of claim 1, wherein: the incubator is characterized by further comprising air inlets (12) and a limiting ring (17), wherein the air inlets (12) are uniformly distributed on the upper side face of the mounting plate (11), and the limiting ring (17) is fixed outside the incubator (3).

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