CN110093255B - Compressed air supply mechanism of biological enzyme stirring equipment capable of discharging air through annular rotation - Google Patents

Abstract

The invention discloses a compressed air supply mechanism of biological enzyme stirring equipment for discharging air through annular rotation, which structurally comprises: the device casing, a controller, the activity is pressed the gas device, the stirring frame, after leading in compressed gas through inside input tube, turn to the regulation through inside arc piece makes inside air current downward, and the separation through the inside membrane pad of through-hole pipe makes the membrane pad downward by the pulling of the air current of below, pull the output with the inside air conditioning of cooling chamber of top, the crooked frame that carries out rotation-accelerating through the below simultaneously can make the refrigerated integrated time of inside air current reduce, thereby make the gas of output can keep at suitable temperature, pass through the joint seat of below when gaseous exports downwards simultaneously, and decurrent gas blows inside impeller and makes bevel gear atress follow the rotation, drive through hollow gear shaft afterwards, make the output frame of below rotatory, rotatory with gaseous annular horizontal output with the mode of flat.

Description

Compressed air supply mechanism of biological enzyme stirring equipment capable of discharging air through annular rotation

Technical Field

The invention relates to the field of biological enzymes, in particular to a compressed air supply mechanism of biological enzyme stirring equipment for discharging air through annular rotation.

Background

The biological enzyme is prepared by breaking cell walls of cells in a stirring manner, and the biological enzyme can be stirred more uniformly by introducing compressed air through a straight pipe by a compressor in the stirring process, but in such a manner:

1. when the stirring operation is carried out, the compressed gas is introduced through the straight pipe type through pipe, the output path of the gas is output in a straight downward mode, the internal biological enzyme is in contact with high-pressure gas at one end, and during stirring, the biological enzyme rotates in a vortex mode, so that the internal biological enzyme can hardly be in contact with the gas uniformly.

And when carrying out the during operation, the compressed air is increased when compressed the inside gaseous internal energy and makes gaseous temperature rise, and utilizes the cooling method of straight tube formula hardly fast with inside gaseous rapid cooling to when letting in the too high gas of temperature, thereby the activity of biological enzyme can receive the influence of the change of temperature and influence the output finished product.

Disclosure of Invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme: through the rotatory compressed air feed mechanism of biological enzyme agitated vessel who gives vent to anger of annular, its structure includes: device casing, controller, activity are pressed gas device and are stirred the frame, the controller is located the inboard of device casing upper end surface and is connected with the embedded block of device casing simultaneously, the inside of stirred frame embedding device casing is with bearing swing joint simultaneously with the device casing, the activity is pressed gas the inside of device locating the stirred frame and is passed through the bolt fixed connection on the flange with the stirred frame simultaneously, the inside of stirred frame is equipped with rotatory arc cutter.

As a further optimization of the invention, the movable air compressing device is provided with a cooling cabin, a matching pressing frame and a power throwing frame, the cooling cabin and the matching pressing frame are perpendicular to each other and are communicated through a pipeline, the power throwing frame is arranged on the lower side end face of the matching pressing frame and forms an integrated structure with the matching pressing frame through the pipeline, and cooling air is arranged inside the cooling cabin.

As a further optimization of the invention, the matched pressing frame is provided with a through hole pipe, a membrane pad, an input pipe, an arc-shaped block and a bending frame, the bending frame is arranged on the lower side end face of the through hole pipe and is in through connection with the through hole pipe, the membrane pad is positioned on the left side and the right side inside the through hole pipe and is adhered to the left side and the right side of the through hole pipe to form an integrated structure, the arc-shaped block is fixedly arranged on the left side inside the through hole pipe and is clamped and welded together by a plate body, the input pipe is horizontally arranged on the left side end face of the through hole pipe and is in through connection with the through hole pipe, the membrane pad is in a cross-shaped flexible membrane plate structure, and the arc-shaped block is in a block.

As a further optimization of the invention, the bending frame is provided with a bending plate, a through pipe, an arc frame and a bent pipe, the through hole is positioned in the arc frame and penetrates through the inner side end face of the arc frame, the bending plate is positioned on the front end face of the through pipe, the bending plate and the through pipe are connected together in a sealing manner, the bent pipe is positioned on the lower side end face of the arc frame and fixedly connected with the lower side end face of the arc frame through a bolt, and the bending plate is of a large and small concentric circle structure formed by bending a steel plate.

As a further optimization of the invention, the power throwing frame is provided with an output frame, a gear shaft, a bevel gear, a joint seat and a blade wheel, the blade wheel and the bevel gear are concentric wheels and are fixedly connected through a movable shaft rod, the gear shaft is positioned on the lower side end face of the bevel gear and is vertically and movably connected through tooth root meshing, the joint seat is positioned on the upper side end face of the blade wheel and is simultaneously communicated with the blade wheel through a through pipe, the output frame is movably arranged on the lower side end face of the bevel gear, and the blade wheel is of a special-shaped structure with a circular arc oblique circular arc blade type and a shaft rod arranged in the center.

As a further optimization of the invention, the output frame is provided with a fine pore plate, a baffle plate, a rubber block, an air pipe and a central shaft, the air pipe is arranged on the inner side end face of the central shaft and is in parallel through connection with the central shaft, the baffle plate is positioned on the front end surface of the air pipe and is in interval movable connection with the air pipe, the fine pore plate is arranged on the lower side end face of the baffle plate and is in movable connection with the baffle plate in a hinged connection manner, and the rubber block is positioned on the rear end face of the fine pore plate and is in clearance fit in a sliding connection manner of a sliding groove.

As a further optimization of the invention, the inside of the joint seat is provided with a through hole structure of a conical pillar stand.

As a further optimization of the invention, the pore plate is a movable structure with a soft block body at two ends and a pore net body in the center, and the inner side end surface of the rubber block is provided with a roller type movable clamp.

Advantageous effects

The invention is applied to a compressed air supply mechanism of a biological enzyme stirring device which discharges air through annular rotation, when stirring work is carried out, raw materials to be processed are sent into the stirring frame in advance, then after the device is sealed, after the device is started through a controller, an inner stirring cutter is dragged by a power element to carry out rotation stirring work, compressed air is simultaneously introduced through an inner input pipe, the inner airflow is downward through the steering adjustment of an inner arc block, a membrane pad is downward through the separation of an inner membrane of a through hole pipe and the traction of the lower airflow, cold air in an upper cooling cabin is dragged and output, high-pressure cold and hot air enters through a through pipe in a lower bending frame, the flowing path of the inner airflow is increased through an inner bending plate, and the inner airflow is mutually fused by the rotation collision, the accelerated rotating mixing of the incoming air stream enables the overall time for cooling of the internal air stream to be reduced, so that the output gas can be kept at a proper temperature, and meanwhile, the gas passes through the lower joint seat when being output downwards, and the downward gas blows the internal vane wheel to make the bevel gear rotate along with the force, and then the bevel gear is driven by the hollow gear shaft, the output frame at the lower part rotates, and after the air flow mixed at the upper part is input through the central shaft at the inner part, then the airflow is output through the air pipe in a turning way, the baffle inside is blown, the baffle is rotated by the rotating wheel to stretch, tighten and eject the fine pore plate inside, then the gas flow flows out along the arc-shaped baffle plate in a shape of a circle, the gas is circularly and horizontally output in a flat mode in a rotating mode, and the circular output can be matched with vortex to enable the contact between the biological enzyme and the gas to be more uniform and stable.

The invention mainly matches the pressing frame and the power throwing frame, after compressed gas is introduced through the inner input pipe, the inner airflow is downward through the steering adjustment of the inner arc block, and the membrane pad in the through hole pipe is separated by the air flow at the lower part to lead the membrane pad to be downward and lead the cold air in the cooling cabin at the upper part to be output, meanwhile, the comprehensive time of cooling the air flow inside can be reduced by accelerating, rotating and mixing the lower bent frame, so that the output gas can be kept at a proper temperature, and meanwhile, the gas passes through the lower joint seat when being output downwards, and the downward gas blows the internal vane wheel to lead the bevel gear to rotate along with the force, then the output frame below the bevel gear is driven by the hollow gear shaft to rotate, the gas is circularly and horizontally output by rotating in a flat mode, and the circular output can be matched with vortex, so that the contact between the biological enzyme and the gas is more uniform and stable.

According to the invention, high-pressure gas enters through the inner central shaft through the output frame, the output direction of the gas is changed by the gas pipe which is transverse below the gas pipe, then the gas flow pushes the baffle in front, the baffle rotates through the hinge wheel, meanwhile, the gas flow is output under stress through the foldable fine pore plate, then the gas flow is limited in an arc shape of the baffle, the gas flow is output in the oblique and square-shaped output direction, and the gas flow can be kept horizontal with the vortex, so that the vortex in the inner part and the square-shaped gas flow are in uniform contact in rotation during stirring.

According to the invention, through the bending frame, cold and hot air entering through the internal through pipe is limited by the loop shape of the internal bending plate, so that a pipeline through which the air flow flows is lengthened, the mixing time of the two air flows is prolonged, and meanwhile, when the loop shapes are mixed, the internal air flow can form the revolving air in a revolving mode, and the temperature reduction rate of the air is accelerated.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic three-dimensional structure of a main body of a compressed air supply mechanism of a bio-enzyme stirring device for discharging air through annular rotation according to the present invention.

FIG. 2 is a schematic view of the cross-sectional mechanism of the cleaning and grinding device of the compressed air supply mechanism of the bio-enzyme stirring equipment for discharging air through annular rotation according to the present invention.

FIG. 3 is a schematic structural diagram of a matching pressing frame of a compressed air supply mechanism of the bio-enzyme stirring device for discharging air through annular rotation according to the present invention.

FIG. 4 is a schematic front view of the curved rack of the compressed air supply mechanism of the bio-enzyme stirring device for discharging air through annular rotation according to the present invention.

FIG. 5 is a schematic structural view of a power throwing-out frame of a compressed air supply mechanism of the bio-enzyme stirring device for annular rotation air outlet according to the present invention.

FIG. 6 is a schematic top view of the output frame of the compressed air supply mechanism of the bio-enzyme stirring apparatus for discharging air through circular rotation according to the present invention.

In the figure: the device comprises a device shell-1, a controller-2, a movable air compressing device-3, a stirring frame-4, a cooling cabin-31, a matching pressing frame-32, a power throwing frame-33, a through hole pipe-321, a membrane pad-322, an input pipe-323, an arc block-324, a bending frame-325, a bending plate-3251, a through pipe-3252, an arc frame-3253, an elbow pipe-3254, an output frame-331, a gear shaft-332, a bevel gear-333, a joint seat-334, a vane wheel-335, a fine pore plate-3311, a baffle-3312, a rubber block-3313, an air pipe-3314 and a central shaft-3315.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easy to understand, the following description and the accompanying drawings further illustrate the preferred embodiments of the invention.

Examples

Referring to fig. 1, the present invention provides a compressed air supply mechanism of a bio-enzyme stirring apparatus for discharging air through circular rotation, which comprises: device casing 1, controller 2, activity are pressed gas device 3 and are stirred the frame 4, controller 2 is located the inboard of 1 upper end surface of device casing and is connected with the embedded block of device casing 1 simultaneously, 4 embedding device casings 1's of stirred frame inside simultaneously with device casing 1 with bearing swing joint, the activity is pressed gas device 3 and is located the inside of stirred frame 4 and simultaneously through the bolt fixed connection on the flange with stirred frame 4, the inside of stirred frame 4 is equipped with rotatory arc cutter, and the power that provides through power component drives inside rotatable arc cutter and carries out the mechanical cutting of circular arc formula.

Referring to fig. 2, the present invention provides a compressed air supply mechanism of a bio-enzyme stirring apparatus for discharging air through circular rotation, which comprises: the activity is compressed air device 3 and is equipped with cooling cabin 31, cooperation pressure frame 32 and power and throws away frame 33, cooling cabin 31 and cooperation pressure frame 32 mutually perpendicular and with pipeline through connection, power throws away the frame 33 and locates the downside terminal surface that cooperation pressure frame 32 and with cooperation pressure frame 32 and constitute the integral structure through the pipeline, the inside of cooling cabin 31 is equipped with cooling gas, carries out the cold and hot circulation in turn of inside gas through the inside air conditioning of cooling cabin 31 and is used for the cooling work.

Referring to fig. 3, the present invention provides a compressed air supply mechanism of a bio-enzyme stirring apparatus for discharging air through circular rotation, which comprises: the matching pressing frame 32 is provided with a through hole pipe 321, a membrane pad 322, an input pipe 323, an arc block 324 and a bending frame 325, the bending frame 325 is arranged on the lower side end face of the through hole pipe 321 and is in through connection with the through hole pipe 321, the membrane pad 322 is positioned on the left side and the right side inside the through hole pipe 321 and is attached to the left side and the right side to form an integrated structure, the arc block 324 is fixedly arranged on the left side inside the through hole pipe 321 and is clamped and welded together by a plate body, the input pipe 323 is horizontally arranged on the left side end face of the through hole pipe 321 and is in through connection with the through hole pipe 321, the membrane pad 322 is in a cross-shaped flexible membrane structure, the membrane influenced by the air flow can rotate and move through the flexible membrane structure, the arc block 324 is in a block structure with a small arc angle at the upper end, and the tendency of the air flow following the small arc angle is realized according to the coanda effect, for changing the direction of the flow output of the gas stream.

Referring to fig. 4, the present invention provides a compressed air supply mechanism of a bio-enzyme stirring apparatus for discharging air through circular rotation, which comprises: the bending frame 325 is provided with a bending plate 3251, a through pipe 3252, an arc frame 3253 and a bent pipe 3254, the through hole 3252 is located inside the arc frame 3253 and penetrates through the inner side end face of the arc frame 3253, the bending plate 3251 is located on the front end face of the through pipe 3252 and is in fit connection with the front end face of the through pipe 3252, the bent pipe 3254 is located on the lower side end face of the arc frame 3253 and penetrates through the lower side end face of the arc frame 3253 to be fixedly connected through a bolt, the bending plate 3251 is of a large and small concentric circle structure formed by bending a steel plate, the length of an inner fluid walkway can be increased through the concentric circle structure formed by bending, and cooling work of equipment.

Referring to fig. 5, the present invention provides a compressed air supply mechanism of a bio-enzyme stirring apparatus for discharging air through circular rotation, which comprises: the power throwing frame 33 is provided with an output frame 331, a gear shaft 332, a bevel gear 333, a joint seat 334 and a vane wheel 335, the vane wheel 335 and the bevel gear 333 are concentric wheels and are fixedly connected through a movable shaft rod, the gear shaft 332 is positioned on the lower side end surface of the bevel gear 333 and is vertically and movably connected through tooth root meshing, the joint seat 334 is positioned on the upper side end surface of the vane wheel 335 and is communicated with the vane wheel 335 through a through pipe, the output frame 331 is movably installed on the lower side end surface of the bevel gear 333, the vane wheel 335 is in a special-shaped structure of a circular arc inclined arc vane type, the center of the circular arc inclined arc vane type is provided with the shaft rod, the circular arc inclined vane can rotate when being impacted by airflow, and the inside of the joint seat 334 is provided with a.

Referring to fig. 6, the present invention provides a compressed air supply mechanism of a bio-enzyme stirring apparatus for discharging air through circular rotation, which comprises: the output frame 331 is provided with a fine hole plate 3311, a baffle plate 3312, a rubber block 3313, an air pipe 3314 and a central shaft 3315, the air pipe 3314 is arranged on the inner side end surface of the central shaft 3315 and is connected with the central shaft 3315 in a parallel and through manner, the baffle plate 3312 is arranged on the front end surface of the air pipe 3314 and is movably connected with the air pipe 3314 at intervals, the fine hole plate 3311 is arranged on the lower side end surface of the baffle plate 3312 and is movably connected with the baffle plate 3312 in a hinged manner, the rubber block 3313 is arranged on the rear end surface of the fine hole plate 3311, the fine hole plate 3311 is in clearance fit in a sliding connection manner of a sliding chute, the fine hole plate 3311 is a movable structure with a fine hole body having a mesh hole at the center, the inner mesh structure can be tightened for expanding the outlet of the air flow by stretching and folding, and the inner side end surface of the rubber block 331.

When stirring, raw materials to be processed are fed into the stirring frame 4 in advance, then the device is sealed, after the device is started through the controller 2, the internal stirring cutter is dragged by the power element to perform rotary stirring, and after compressed gas is introduced through the internal input pipe 323 at the same time, the internal airflow is downward through the steering adjustment of the internal arc-shaped block 324, and the membrane 322 inside the through hole pipe 321 is dragged by the airflow below through the separation of the membrane 322 inside the through hole pipe 321, so that the membrane pad 322 is downward, cold air inside the cooling cabin 31 above is dragged and output, meanwhile, after high-pressure cold and hot air enters through the through pipe 3252 in the bending frame 325 below, the path through which the internal airflow flows is increased through the internal bending plate 3251, and the internal airflows inside are mutually fused by rotary collision, so that the comprehensive time for cooling the internal airflow can be reduced by accelerating, rotating and mixing the inflowing airflow, so that the output gas can be maintained at a proper temperature while the gas passes through the lower engaging seat 334 when being output downwards, and the downward gas blows the inner vane wheel 335 so that the bevel gear 333 is forced to follow the rotation, then the lower output frame 331 is rotated by the driving of the hollow gear shaft 332, and after the upper mixed gas flow is input through the inner central shaft 3315, the gas flow is turned to be output through the gas pipe 3314, the inner baffle 3312 is blown, the baffle 3312 makes the inner fine pore plate 3311 stretched, stretched and ejected tightly, and then the gas flow flows out along the curved baffle 3312 in a circle shape, and the gas is output in a circular horizontal manner by the rotation of the rotating wheel, so that the circular output can be matched with the vortex flow to make the contact of the bio-enzyme and the gas more uniform and stable.

The invention solves the problems that when stirring is carried out, compressed gas is introduced through a straight pipe type through pipe, an output path of the gas is output in a straight downward mode, internal biological enzymes contact high-pressure gas at one end, when stirring, the biological enzymes rotate in a vortex mode, the internal biological enzymes can hardly contact the gas uniformly, when working, the internal energy of the internal gas is increased when the compressed air is compressed, so that the temperature of the gas is increased, the internal gas is hardly cooled rapidly by using a straight pipe type cooling mode, so that when gas with overhigh temperature is introduced, the activity of the biological enzymes is influenced by the change of the temperature to influence the output of a finished product, in the invention, the internal gas flow is downward mainly through matching of a pressing frame and a power throwing frame, after the compressed gas is introduced through an internal input pipe, through the steering adjustment of an internal arc-shaped block, the membrane pad is downwards dragged by the airflow below through the separation of the membrane pad inside the through hole pipe, the cool air inside the cooling cabin above is dragged and output, meanwhile, the comprehensive time for cooling the airflow inside can be reduced by accelerating, rotating and mixing the bent frame below, so that the output gas can be kept at a proper temperature, meanwhile, the gas passes through the joint seat below when being downwards output, the downward gas blows the internal impeller to enable the bevel gear to be forced to rotate along with the bevel gear, then the output frame below rotates through the driving of the hollow gear shaft, the gas is circularly and horizontally output in a flat mode through rotating, the circular output and vortex matching enables the contact of the biological enzyme and the gas to be more uniform and stable, after the high-pressure gas enters through the internal central shaft, the output direction of the gas is changed through the air pipe which is transverse below, then the baffle in the place ahead is moved in the air current top, the baffle is rotatory through the hinge wheel, simultaneously through the output of pore board atress that can fold, then the air current is spacing with the arc of baffle, export the air current with the output direction of slant shape of returning, can keep the level with the vortex, thereby make the vortex of inside when the stirring carry out rotatory even contact with the air current of shape of returning, cold and hot gas with the inside siphunculus entering, the shape of returning of the crooked board of inside is spacing down, make the pipeline of the flowing through of air current lengthen, increase the mixing time of two air currents, when the shape of returning mixes simultaneously, can make the air current of inside form the gas of gyration with the mode of gyration, accelerate the temperature rate of decline of gas.

While there have been shown and described what are at present considered the fundamental principles of the invention, the essential features and advantages thereof, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but rather, is capable of numerous changes and modifications in various forms without departing from the spirit or essential characteristics thereof, and it is intended that the invention be limited not by the foregoing descriptions, but rather by the appended claims and their equivalents.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (4)

1. Through the rotatory compressed air feed mechanism of biological enzyme agitated vessel who gives vent to anger of annular, its structure includes: device casing (1), controller (2), activity are compressed air device (3) and are stirred frame (4), inside controller (2) and the stirring frame (4) of being equipped with of device casing (1), its characterized in that: the inside of stirring frame (4) is located in activity air compressor arrangement (3), activity air compressor arrangement (3) are equipped with cooling tank (31), cooperation pressure frame (32) and power throw-off frame (33), the upper and lower both ends surface mounting who cooperates pressure frame (32) has cooling tank (31) and power throw-off frame (33), cooperation pressure frame (32) are equipped with through hole pipe (321), membrane pad (322), input tube (323), arc piece (324) and bent frame (325), the downside terminal surface of through hole pipe (321) is located in bent frame (325), membrane pad (322) and through hole pipe (321) structure as an organic whole, arc piece (324) fixed mounting is inside through hole pipe (321), input tube (323) and through hole pipe (321) through connection, bent frame (325) are equipped with bent plate (3251), siphunculus (3252), arc frame (3253) and return bend (3254), the power throwing-out frame (33) is provided with an output frame (331), a gear shaft (332), a bevel gear (333), a joint seat (334) and a vane wheel (335), the vane wheel (335) and the bevel gear (333) are concentric wheels and are fixedly connected through a movable shaft rod, the gear shaft (332) is located on the lower side end face of the bevel gear (333), the joint seat (334) is located on the upper side end face of the vane wheel (335), and the output frame (331) is movably mounted on the lower side end face of the bevel gear (333).

2. The compressed air supply mechanism of the bio-enzyme stirring device for discharging air through annular rotation according to claim 1, wherein: output frame (331) is equipped with orifice plate (3311), baffle (3312), block rubber (3313), trachea (3314) and center pin (3315), the medial surface of center pin (3315) is located in trachea (3314), baffle (3312) are located the front end surface of trachea (3314) simultaneously with trachea (3314) interval swing joint, the downside terminal surface at baffle (3312) is installed in orifice plate (3311), block rubber (3313) and orifice plate (3311) adopt clearance fit.

3. The compressed air supply mechanism of the bio-enzyme stirring device for discharging air through annular rotation according to claim 1, wherein: the inside of the joint seat (334) is provided with a through hole structure of a conical pillar stand.

4. The compressed air supply mechanism of the bio-enzyme stirring device for discharging air through annular rotation according to claim 2, wherein: the fine pore plate (3311) is a movable structure with a fine pore net body in the center of a block body with soft two ends, and the inner side end face of the rubber block (3313) is provided with a roller-type movable clamping groove.

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