Production system of biological amino acid
Technical Field
The invention belongs to the technical field of amino acid production, and particularly relates to a biological amino acid production system.
Background
The amino acid is colorless crystal, the melting point is over 200 ℃, the melting point is much higher than that of common organic compounds, the alpha-amino acid has 4 different tastes of acid, sweet, bitter and fresh, and monosodium glutamate and glycine are the delicious seasonings with the largest dosage. Amino acids are generally readily soluble in water, acid solutions and alkali solutions, insoluble or slightly soluble in organic solvents such as ethanol or diethyl ether, and the solubility of amino acids in water differs greatly, e.g., tyrosine is the least soluble in water, and at 25 ℃, tyrosine only dissolves 0.045g in 100g of water, but has greater solubility in hot water towel tyrosine.
In the production of amino acid, the strain is required to ferment, so that the strain liquid is injected into the corresponding container bottle, the structure that the strain liquid can be injected into the container bottle only by one side and the two sides are inconvenient to alternately operate is insufficient in the equipment for injecting the strain liquid into the container bottle, the efficiency is required to be improved, the number of the container bottles required to be injected is large, the single one-by-one strain liquid injection is delayed, the progress is affected due to the fact that the container bottles are placed discontinuously, meanwhile, the container for containing the strain liquid is long in standing time, the deposition condition can occur, and the strain liquid is not easy to be uniformly injected into the container bottle. Therefore, a system for producing a biological amino acid is proposed in view of the above-mentioned problems.
Disclosure of Invention
The present invention has been made to solve the above problems, and an object of the present invention is to provide a system for producing a biological amino acid.
The invention realizes the aim through the following technical scheme that the production system of the biological amino acid comprises a boss, a strain leading-out mechanism, a strain sucking mechanism, a reciprocating mechanism and a bottle conveying mechanism, wherein strip-shaped grooves are formed on the adjacent surfaces of two sides of a lug structure at the top of the boss, and one end of a convex side plate of a T-shaped frame is arranged at the top of the boss;
the strain leading-out mechanism comprises a strain liquid chamber and a drainage tube, the strain liquid chamber is arranged in a boss, three stirring plates are rotatably arranged at the bottom of the strain liquid chamber, one ends of rotating connecting shafts at the bottoms of the three stirring plates are arranged at one ends of corresponding shaft rods of the second motors, a check valve is arranged at the inner side of the top of the drainage tube, and a port at the top of the drainage tube is arranged at a port at the bottom of a corresponding drainage hole;
the strain suction mechanism comprises a suction cylinder and a second air cylinder, a piston rod is slidably mounted in the suction cylinder, one end of the piston rod penetrates through the top surface of the rectangular carrier plate, a rubber ring block is sleeved at a port at the bottom of the suction cylinder, the second air cylinder is mounted in the middle of a transverse plate of a corresponding L-shaped plate, one end of a push rod of the second air cylinder is fixedly connected with one end of the piston rod through a traction plate, and the two L-shaped plates are symmetrically mounted on two sides of the top surface of the rectangular carrier plate;
the reciprocating mechanism comprises two long screws, square plates are rotatably arranged on the inner sides of two ends of the two long screws, the square plates on the same long screw are arranged on the tops of the corresponding side walls in the T-shaped frame, two square bars are connected between the two long screws in an alternate threaded manner, a first cylinder is arranged at the middle position of the bottom of each square bar, and the push rod end of the first cylinder is provided with the middle position of the edges of two sides of the top of the rectangular carrier plate;
the bottle conveying mechanism comprises a first conveying belt, the first conveying belt is arranged in the strip-shaped groove, one end of a conveying frame is arranged on the surface of a boss on the outer side of the strip-shaped groove, a second conveying belt is arranged in the conveying frame, and the second conveying belt and one side of the first conveying belt are in a mutually perpendicular position relation.
Preferably, the drainage holes are provided with three groups, and the three groups of drainage holes are parallelly and equidistantly arranged at the middle position of the top wall of the fungus liquid chamber, and the inner sides of the top ports of each group of two drainage holes are mutually communicated.
Preferably, the suction barrels are provided with three groups, the three groups of suction barrels are installed on two sides of the bottom of the rectangular carrier plate at equal intervals in parallel, each group of two suction barrels are respectively located in the corresponding L-shaped plate bottom space, and the two suction barrels and the corresponding group of two drainage holes are located on the same vertical plane.
Preferably, threaded holes are formed in two ends of each square bar block, two ends of each square bar block are fixedly connected through a thin rod, two end faces of each square bar block are in sliding connection with a strip-shaped sliding groove on the same side through a sliding block, and two strip-shaped sliding grooves are formed in the inner wall of a T-shaped frame between two corresponding square plates respectively.
Preferably, two conveying frames are arranged, the two conveying frames are symmetrically arranged on the surfaces of two sides of the boss, the other end of each conveying frame is located at a position to be placed in the inoculation bacteria bottle set, and the top surface of each conveying frame, the top surface of the first conveying belt, the top surface of the second conveying belt and the adjacent surfaces of two sides of the bump structure at the top of the boss are located on the same horizontal plane.
Preferably, one end of the long screw is installed at one end of a shaft rod of the corresponding first motor, and the first motors are installed on the side face of the square plate at one end of the same long screw.
Preferably, the second motor is installed in the concave groove at the bottom of the boss, and the second motor and the first motor are electrically connected with the external control equipment and the power supply through conductive wires.
Preferably, the first air cylinder and the second air cylinder are connected with the corresponding pneumatic controller and the corresponding air pump through hoses, and the two second air cylinders are located between the two first air cylinders.
Preferably, the fungus liquid chamber is filled with fungus liquid, and is communicated with a container filled with fungus through a conduit.
Preferably, the top port of the drainage hole is communicated with the top surface of the boss, and the aperture of the top port of the drainage hole is consistent with the outer diameter of the rubber ring block.
The beneficial effects of the invention are as follows:
(1) The production system of the biological amino acid has compact structure, is favorable for transferring each group of three inoculation bottles onto the first conveyor belt and being positioned in the area range of the strain liquid to be injected, and can simultaneously transfer the inoculation bottles with the strain liquid to the bearing structure at one side to be transferred, thereby ensuring the continuity of inoculation of the strain liquid to be injected subsequently; the function of sucking, draining and injecting the strain liquid is realized, and the inoculation efficiency can be improved by the alternate operation mode of the two sucking, draining and injecting structures, so that the strain liquid can be conveniently injected into three inoculation bottles at one time.
(2) The production system of the biological amino acid is stable in operation, the first motor electrically connected with the corresponding control equipment is started to operate to drive the long screw rod to rotate correspondingly and drive the two connected square bars to move regularly and reciprocally along the long screw rod under the interaction of force, the effect of driving the connected parts to move reciprocally simultaneously is achieved, the function of providing driving power for alternate injection of the strain liquid structure is achieved, the production efficiency is improved, the second motor operated to drive the stirring plate positioned in the strain liquid chamber to rotate slowly, the strain is guaranteed to be always in a flowing state, and the deposition condition is avoided.
Drawings
In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.
FIG. 1 is a perspective view of the overall structure of the present invention;
FIG. 2 is a schematic view of the internal structure of a T-shaped frame according to the present invention;
FIG. 3 is a partial top view of the second cylinder and suction tube connection of the present invention;
FIG. 4 is a schematic diagram of the connection structure of the long screw and the square bar block of the invention;
FIG. 5 is a schematic view of the internal structure of a brush boss according to the present invention;
fig. 6 is a schematic view of the structure of the suction tube of the present invention.
In the figure: 1. boss, 2, first conveyer belt, 3, bar slot, 4, T shaped frame, 5, second conveyer belt, 6, first cylinder, 7, square board, 8, long screw rod, 9, square bar piece, 10, second cylinder, 11, L template, 12, bar spout, 13, first motor, 14, rectangular carrier plate, 15, suction cylinder, 16, rubber ring piece, 17, traction plate, 18, slider, 19, second motor, 20, fungus liquid room, 21, drainage hole, 22, check valve, 23, drainage tube, 24, stirring board, 25, piston rod.
Detailed Description
In order to make the objects, features and advantages of the present invention more comprehensible, the technical solutions in the embodiments of the present invention are described in detail below with reference to the accompanying drawings, and it is apparent that the embodiments described below are only some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.
Referring to fig. 1-6, a biological amino acid production system comprises a boss 1, a strain extraction mechanism, a strain suction mechanism, a reciprocating mechanism and a bottle conveying mechanism, wherein strip-shaped grooves 3 are formed in two adjacent surfaces of a bump structure at the top of the boss 1, and one end of a convex side plate of a T-shaped frame 4 is arranged at the top of the boss 1; the strain leading-out mechanism comprises a strain liquid chamber 20 and a drainage tube 23, wherein the strain liquid chamber 20 is arranged in a boss 1, three stirring plates 24 are rotatably arranged at the inner bottom of the strain liquid chamber 20, one ends of the bottom rotary connecting shafts of the three stirring plates 24 are arranged at one ends of the corresponding shaft rods of the second motors 19, a check valve 22 is arranged at the inner side of the top of the drainage tube 23, and the top port of the drainage tube 23 is arranged at the bottom port of the corresponding drainage hole 21; the strain suction mechanism comprises a suction cylinder 15 and a second air cylinder 10, a piston rod 25 is slidably installed in the suction cylinder 15, one end of the piston rod 25 penetrates through the top surface of the rectangular carrier plate 14, a rubber ring block 16 is sleeved at a bottom port of the suction cylinder 15, the second air cylinder 10 is installed in the middle of a transverse plate of a corresponding L-shaped plate 11, one end of a push rod of the second air cylinder 10 is fixedly connected with one end of the piston rod 25 through a pulling plate 17, and the two L-shaped plates 11 are symmetrically installed on two sides of the top surface of the rectangular carrier plate 14;
the reciprocating mechanism comprises two long screws 8, wherein the two long screws 8 are provided, square plates 7 are rotatably arranged on the inner sides of two ends of the two long screws 8, the square plates 7 positioned on the same long screw 8 are arranged on the tops of the corresponding side walls in the T-shaped frame 4, two square bars 9 are connected between the two long screws 8 in an alternate threaded manner, a first cylinder 6 is arranged in the middle position of the bottom of each square bar 9, and the push rod end of the first cylinder 6 is provided with the middle positions of the edges of two sides of the top of the rectangular carrier plate 14;
the bottle conveying mechanism comprises a first conveying belt 2, the first conveying belt 2 is arranged in a strip-shaped groove 3, one end of a conveying frame is arranged on the surface of a boss 1 outside the strip-shaped groove 3, a second conveying belt 5 is arranged in the conveying frame, and the second conveying belt 5 and one side of the first conveying belt 2 are in a mutually perpendicular position relation.
The drainage holes 21 are provided with three groups, and the three groups of drainage holes 21 are parallelly and equidistantly arranged at the middle position of the top wall of the bacterial liquid chamber 20, and the inner sides of the top ports of each group of two drainage holes 21 are mutually communicated, so that bacterial liquid in the bacterial liquid chamber 20 is conveniently drained to the corresponding positions for suction of the suction cylinders 15 under the suction action of the corresponding structures; the suction drums 15 are provided with three groups, the three groups of suction drums 15 are parallelly and equidistantly arranged on two sides of the bottom of the rectangular carrier plate 14, each group of two suction drums 15 are respectively positioned in the bottom space of the corresponding L-shaped plate 11, the two suction drums 15 and the corresponding group of two drainage holes 21 are positioned on the same vertical plane, and the bottom ports of the corresponding suction drums 15 can be slidably inserted into the corresponding drainage holes 21 to perform suction operation; screw holes are formed in the two ends of each square bar 9, the two ends of each square bar 9 are fixedly connected through thin rods, the end faces of the two ends of each square bar 9 are in sliding connection with the strip-shaped sliding grooves 12 on the same side through sliding blocks 18, and the two strip-shaped sliding grooves 12 are formed in the inner wall of the T-shaped frame 4 between the corresponding two square plates 7 respectively, so that stable movement of the square bars 9 is guaranteed; the two conveying frames are symmetrically arranged on the surfaces of two sides of the boss 1, the other end of the conveying frame is positioned at a centralized place where the inoculated fungus bottles are to be placed, the top surface of the conveying frame, the top surface of the first conveying belt 2, the top surface of the second conveying belt 5 and the adjacent surfaces of two sides of the bump structure at the top of the boss 1 are positioned on the same horizontal plane, so that the inoculated bottles placed on the second conveying belt 5 can be conveniently moved onto the first conveying belt 2; one end of the long screw rod 8 is arranged at one end of a shaft rod of the corresponding first motor 13, and the first motor 13 is arranged on the side surface of the square plate 7 at one end of the same long screw rod 8, so that the long screw rod 8 is driven to correspondingly rotate under the control of corresponding control equipment through the started first motor 13; the second motor 19 is arranged in a concave groove at the bottom of the boss 1, and the second motor 19 and the first motor 13 are electrically connected with external control equipment and a power supply through conductive wires, so that the operation of the corresponding motors is controlled; the first air cylinders 6 and the second air cylinders 10 are connected with corresponding pneumatic controllers and air pumps through hoses, and the two second air cylinders 10 are positioned between the two first air cylinders 6, so that the coordination control of the running states of the first air cylinders 6 and the second air cylinders 10 is facilitated; the bacterial liquid chamber 20 is filled with bacterial liquid, and the bacterial liquid chamber 20 is communicated with a container which is filled with bacterial through a conduit, so as to achieve the effects of filling and injecting bacterial liquid used for producing amino acid; the top port of the drainage hole 21 is communicated with the top surface of the boss 1, and the aperture of the top port of the drainage hole 21 is consistent with the outer diameter of the rubber ring block 16, so that the suction tube 15 can be conveniently inserted into the top port of the drainage hole 21 through the sliding of the rubber ring block 16.
When the invention is used, as the whole body starts to operate after being debugged for many times by professional installers, firstly, each three inoculation bottles of operators are placed on the second conveyor belt 5 at equal intervals and intermittently operate under the action of the second conveyor belt 5 controlled by corresponding control equipment, thereby being beneficial to transferring each group of three inoculation bottles onto the first conveyor belt 2 and being positioned in the area range of the strain liquid to be injected, and simultaneously being capable of transferring the inoculation bottles filled with the strain liquid to a bearing structure on one side to be transferred, and ensuring the continuity of inoculation of the subsequent strain liquid to be injected;
when the top ports of the three inoculation bottles are positioned at the bottom of one corresponding side of the T-shaped frame 4, the bottom ports of the three suction drums 15 positioned at the same side push the rectangular carrier plate 14 to move downwards and slide to be inserted into the top ports of the drainage holes 21 corresponding to the same side up and down under the action of the first started cylinder 6 to form a closed suction space, then the three piston rods 25 at the same side connected by the traction plate 17 are driven to move upwards by the second started cylinder 10 in a contracted state and the strain liquid in the strain liquid chambers 20 which are communicated is sucked into the suction drums 15 according to the principle of an injector, and simultaneously the three suction drums 15 at the other side are alternately filled with the strain liquid in the mode and extend into the corresponding three inoculation bottle ports on the first conveyor belt 2 at the same side under the action of the second started cylinder 10, so that the function of sucking, discharging and filling the strain liquid is realized, and the inoculation efficiency can be improved by the alternate operation mode of the two sucking and discharging structures, so that the strain liquid is conveniently injected into the three inoculation bottles at one time;
in the process of alternately injecting the strain liquid, the first motor 13 electrically connected with the corresponding control equipment is started to operate to drive the long screw rod 8 to rotate correspondingly and drive the two connected square bar blocks 9 to move reciprocally and regularly along the long screw rod 8 under the interaction of force, so that the effect of driving the connected parts to move reciprocally and simultaneously is achieved, the function of providing driving power for alternately injecting the strain liquid structure is realized, the production efficiency is improved, and meanwhile, the second motor 19 operates to drive the stirring plate 24 plate positioned in the strain liquid chamber 20 to rotate slowly, so that the strain is always in a flowing state, and the situation of deposition is avoided.
It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention 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 invention 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.
The above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.