CN117181761A - Waste water sedimentation type treatment equipment of bio-pharmaceutical clean room - Google Patents

Abstract

The invention relates to the technical field of treatment of medicine waste residues, in particular to waste water sedimentation type treatment equipment of a bio-pharmaceutical clean room, which comprises a shell and a crushing and separating device; the bracket is arranged above the shell; the crushing shell is vertically and fixedly arranged at the lower part of the bracket, and a rotating groove is formed in the peripheral wall of the crushing shell; the screening shell is of a shell structure, the screening shell is sleeved on the periphery of the crushing shell along the axis of the crushing shell, a first opening and a second opening are respectively arranged at the upper part and the lower part of the screening shell, the first opening and the second opening are of circular structures, the diameter of the first opening is larger than that of the second opening, and a gap is reserved between the screening shell and the crushing shell; the driving device is arranged at the upper part of the screening shell; the pressing wheel is rotationally arranged in the rotating groove along the axis of the rotating groove; the bearing device is arranged on the screening shell in a penetrating way along the direction perpendicular to the side wall of the screening shell; the activation device is arranged at the upper part of the sieving shell. The invention can realize solid-liquid separation and is convenient for crushing solid matters.

Description

Waste water sedimentation type treatment equipment of bio-pharmaceutical clean room

Technical Field

The invention relates to the technical field of treatment of medicine waste residues, in particular to waste water sedimentation type treatment equipment of a bio-pharmaceutical clean room.

Background

The existing chemical waste treatment devices are either smashing treatment devices, combustion treatment devices or combination of two functions, but the devices with the structures cannot be flexibly and practically used according to actual conditions, particularly, some drug residues which do not need combustion treatment are required to be recycled, and smoke generated after combustion is mostly treated by adopting an air device in a matching way, so that the occupied area is large, the installation of the air filtering device relates to complicated circuit connection, and the noise generated during the operation of the mechanism is large.

Chinese patent CN110918612B discloses a chemical experiment chemical waste diversified water sedimentation treatment device, comprising a chassis, a filler port, a crushing cabin, a discharge port, a slot, a diversion hole, a combustion cabin, a crushing roller, a blanking pipe, a fan, a first air guide pipe, a sealing plate, a guide plate, a limiting plate, a second air guide pipe, a sedimentation cabin, a water filling port, a viewing window, a shielding plate, an air outlet and a combustion plate; the bottom frame is a rectangular welding frame part mechanism formed by welding, a crushing cabin is supported and arranged on the top surface of the bottom frame, and a crushing roller set of a compression roller type is arranged in the crushing cabin; the top surface of the crushing cabin is provided with a filling port which is an integral cabin cavity structure, and a sealing plate is inserted on the filling port in a sliding manner by means of a guide groove and a guide plate; an air outlet with a through hole structure is formed in the middle of the inner cavity of the filler port, a first air guide pipe is penetratingly matched with the air outlet, and a small fan is installed on the first air guide pipe in a pipe orifice connection mode; the combustion chamber is positioned at the bottom side of the underframe, a combustion plate electrically connected with an external electric control plate is arranged in the inner cavity of the combustion chamber, and the electric control plate is also electrically connected with the fan; the submerged cabin is arranged on a bottom cross brace of the underframe through bolts, is of a cabin cavity structure, is provided with a water filling port on the top surface, and is provided with a water outlet with a valve at the bottom.

According to the scheme, although the practicability of the equipment is improved, the effect of separating solid matters from liquid of waste is still required to be achieved through standing after chemical reaction in a water sedimentation treatment mode, the sedimentation time is long, even if the liquid is completely settled, the liquid is discharged, part of the liquid is mixed with the solid, the solid and the liquid cannot be completely separated, the solid waste is required to be crushed sufficiently finely during the solid waste treatment, the solid waste is required to be fully reacted with the added chemical reagent, new solid matters are generated in the reaction process, and therefore the reacted solid matters are required to be salvaged again and crushed again, so that the treatment time is increased.

Disclosure of Invention

To above-mentioned problem, the utility model provides a waste water sedimentation formula treatment facility in bio-pharmaceuticals toilet, upper portion at the crushing shell is provided with the feeding device, feeding device is with the mixture after the reaction directly take out, and throw the mixture into the space between screening shell and the crushing shell, afterwards, drive arrangement drive screening shell rotates, the screening shell drives the adapting unit who sets up above that rotates, can have the solution in the mixture of throwing into the space, can fall on the inner wall of screening shell after the mixture drops into the space, because the inner wall of screening shell is in contact state all the time with the pressing wheel, so the pressing wheel just can extrude the mixture on the screening shell inner wall, adapting unit can accept the mixture, still can extrude the residual solution in the mixture that is extruded when pressing wheel extrusion crushing, be provided with the screening hole on the lateral wall of screening shell, solution can overflow from the screening hole, the activating device who sets up on screening shell upper portion rotates along with screening shell is synchronous, the throwing material position of throwing device who is located the crushing shell is fixed, can just fall on the activating device when throwing material device throws material, just in order to guarantee, just in time can fall on the activating device, just in time need throwing material device to activate device to move to monitor the throwing device, throwing material position, throwing device can also be realized when the separator is controlled to be controlled to throwing material, the separator when throwing material has been realized, simultaneously, the solid-liquid separator can be launched, the time is reduced, can be controlled to throwing device.

In order to solve the problems in the prior art, the waste water sedimentation type treatment equipment of the biopharmaceutical clean room comprises a shell and a crushing and separating device; the crushing and separating device comprises a driving device, a bracket, a screening shell, a crushing shell, a pressing wheel, a bearing device and an activating device; the bracket is arranged above the shell; the crushing shell is of a rotary body structure, the crushing shell is vertically and fixedly arranged at the lower part of the bracket, a rotary groove is formed in the peripheral wall of the crushing shell, and the axis of the rotary groove is parallel to the inclined direction of the peripheral wall of the crushing shell; the screening shell is of a shell structure, the screening shell is sleeved on the periphery of the crushing shell along the axis of the crushing shell, a first opening and a second opening are respectively arranged at the upper part and the lower part of the screening shell, the first opening and the second opening are of circular structures, the diameter of the first opening is larger than that of the second opening, and a gap is reserved between the screening shell and the crushing shell; the driving device is arranged at the upper part of the screening shell and is used for driving the screening shell to rotate; the pressing wheel is rotationally arranged in the rotating groove along the axis of the rotating groove, and is contacted with the inner wall of the screening shell; the bearing devices are arranged on the screening shell in a penetrating manner along the direction perpendicular to the side wall of the screening shell, the bearing devices are in sliding fit with the screening shell, the bearing devices are uniformly distributed around the axis of the screening shell, the upper end faces of the bearing devices in the screening shell are coplanar with the lower end faces of the pressing wheels, the bearing devices are elastic, a discharge groove is formed in the inner wall of the shell, and the inner wall of the shell has a pressing effect on the bearing devices; the activation device is arranged on the upper portion of the screening shell, the activation device rotates simultaneously with the screening shell, a controller is arranged on one side of the activation device, a feeding device is arranged on the upper portion of the crushing shell, and the activation device controls the feeding device to feed materials through the controller.

Preferably, the bearing device comprises a first bearing plate, a spring and a limiting plate; the first bearing plate is arranged on the side wall of the screening shell in a penetrating manner along the direction perpendicular to the side wall of the screening shell, and is in sliding fit with the screening shell; the limiting plate is fixedly arranged at one end of the first bearing plate, which is positioned at the outer side of the screening shell, and a gap is reserved between the limiting plate and the screening shell; the spring is disposed in the gap.

Preferably, the bearing device further comprises a second bearing plate; the second is accepted the board and is fixed to be set up on the inner wall of screening shell along the incline direction of screening shell perisporium, and the second is accepted the board and is located one side of first board that accepts, first board that accepts when stretching into screening shell with the bottom lateral wall sliding fit of second board that accepts, offered through the groove on the press wheel.

Preferably, the activating device comprises a trigger block, a trigger button and a feed chute; the trigger blocks are uniformly arranged at the upper part of the screening shell around the axis of the screening shell, the trigger blocks are in one-to-one correspondence with the bearing devices, and the trigger blocks synchronously rotate along with the screening shell; the feeding groove is formed in the side wall of the crushing shell, and the feeding device is used for feeding the mixture into the feeding groove; the trigger button sets up in the bottom of support, and trigger button is located the top of feed chute, and trigger piece can trigger button.

Preferably, the crushing and separating device further comprises a liquid discharging device, wherein the liquid discharging device comprises a collecting shell and a switch valve; the collecting shell is of an annular structure, an annular opening is formed in the upper portion of the collecting shell along a winding line of the collecting shell, and the collecting shell is fixedly arranged at the bottom of the sieving shell

The switch valve is arranged at the bottom of the collecting shell.

Preferably, the crushing and separating device further comprises an anti-blocking device, wherein the anti-blocking device comprises a blower and an air pump; the blower is arranged on the side wall of the shell at the bottom of the discharge groove; the air pump sets up in one side of blast air ware, and the air pump supplies air to the blast air ware.

Preferably, the receiving means further comprises a sleeve; the sleeve is a corrugated pipe, the sleeve is arranged in the gap along the straight line of the spring, and two ends of the sleeve are fixedly connected with the screening shell and the limiting plate respectively.

Preferably, the receiving device further comprises a roller; the even setting of gyro wheel is close to one side of shell at the limiting plate, and the gyro wheel rolls the cooperation with the inner wall of shell.

Preferably, the drive means comprises a first rotary drive, a gear and a toothed ring; the first rotary driver is arranged on the bracket, and the output end of the first rotary driver is vertically downward; the gear is fixedly arranged at the output end of the first rotary driver; the gear ring is fixedly arranged at the upper part of the screening shell along the axis of the screening shell, and the gear ring are meshed with each other.

Preferably, the crushing and separating device further comprises a conveying device, wherein the conveying device comprises a conveying pipe, a connecting pipe, a second rotary driver and a spiral blade; the connecting pipe is fixedly arranged at the bottom of the collecting shell along the axis of the screening shell; the conveying pipe is horizontally arranged at the bottom of the connecting pipe, and the conveying pipe is communicated with the connecting pipe; the second rotary driver is horizontally and fixedly arranged at the end part of the conveying pipe; the helical blade rotates along the axis of the conveying pipe and is arranged in the conveying pipe, and the second rotary driver drives the helical blade to rotate.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, the driving device, the support, the screening shell, the crushing shell, the pressing wheel, the receiving device and the activating device are arranged, the feeding device is arranged at the upper part of the crushing shell, the reacted mixture is directly extracted by the feeding device and is thrown into a gap between the screening shell and the crushing shell, then the driving device drives the screening shell to rotate, the receiving device arranged on the screening shell is driven by the screening shell to rotate, solution exists in the mixture thrown into the gap, the mixture falls on the inner wall of the screening shell after being thrown into the gap, the inner wall of the screening shell is always in a contact state with the pressing wheel, the pressing wheel can squeeze the mixture on the inner wall of the screening shell, the receiving device can receive the mixture, residual solution in the squeezed mixture can be extruded while the pressing wheel is used for squeezing and crushing the mixture, the screening hole is formed in the side wall of the screening shell, the solution can overflow from the screening hole, the activating device arranged at the upper part of the screening shell rotates synchronously with the screening shell, the feeding position of the feeding device is fixed, the material throwing device can fall on the inner wall of the screening shell after the material throwing device is thrown into the gap, the receiving device is always in a contact state, the material can fall on the inner wall of the receiving device, the receiving device is required to be controlled by the pressing device, the material throwing device is also can be controlled to be just in a solid material throwing device is separated, the material can be just separated, and the working procedure can be simultaneously can be prevented from being started, and the working procedure is also can be controlled.

Drawings

Fig. 1 is a schematic perspective view of a waste water sink type treatment facility for a biopharmaceutical clean room.

Fig. 2 is a side view of a waste water sink type treatment facility of a biopharmaceutical clean room.

Fig. 3 is a schematic cross-sectional view of a waste water sink type treatment facility of the biopharmaceutical clean room at A-A in fig. 2.

Fig. 4 is an enlarged schematic view of a portion of a biopharmaceutical clean room waste water sink type processing apparatus at B in fig. 3.

Fig. 5 is a schematic perspective view of a biopharmaceutical clean room waste water sink treatment facility with the conveyor and drain removed.

Fig. 6 is an enlarged schematic view of a portion of the biopharmaceutical clean room waste water sink type processing apparatus at C in fig. 5.

Fig. 7 is a schematic perspective view of a biopharmaceutical clean room waste water sink treatment apparatus with brackets, conveyors and drains removed.

Fig. 8 is a schematic perspective view of a biopharmaceutical clean room waste water sink treatment apparatus with the drive, rack, conveyor and drain removed.

Fig. 9 is a schematic perspective view of a waste water sink-type treatment facility of a biopharmaceutical clean room with the pulverizing shells, driving means, brackets, conveying means and draining means removed.

Fig. 10 is a schematic perspective view of a biopharmaceutical clean room waste water sink type treatment apparatus with the outer housing, the pulverizing housing, the driving means, the frame, the conveyor and the drain removed.

The reference numerals in the figures are:

1-a housing; 11-a discharge chute; 2-a crushing and separating device; 21-a drive device; 211-a first rotary drive; 212-a gear; 213-tooth ring; 22-a bracket; 23-sieving the shell; 24-crushing the shell; 241-pressing wheel; 25-a receiving device; 251-a first receiving plate; 252-springs; 2521-cannula; 253—a limiting plate; 2531-a roller; 254-a second socket plate; 26-activating means; 261-trigger block; 262-a trigger button; 263-feed tank; 27-a liquid discharge device; 271-collecting the shells; 272-switching a valve; 28-conveying device; 281-conveying pipe; 282-connecting tube; 283-a second rotary drive; 284-helical blades; 29-an anti-blocking device; 291-blower; 292-air pump.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

Referring to fig. 1-3 and 8: a waste water sedimentation type treatment device of a biopharmaceutical clean room comprises a shell 1 and a crushing and separating device 2; the crushing and separating device 2 comprises a driving device 21, a bracket 22, a screening shell 23, a crushing shell 24, a pressing wheel 241, a receiving device 25 and an activating device 26; the bracket 22 is arranged above the shell 1; the crushing shell 24 is of a rotary body structure, the crushing shell 24 is vertically and fixedly arranged at the lower part of the bracket 22, a rotary groove is formed in the peripheral wall of the crushing shell 24, and the axis of the rotary groove is parallel to the inclination direction of the peripheral wall of the crushing shell 24; the screening shell 23 is of a shell structure, the screening shell 23 is sleeved on the periphery of the crushing shell 24 along the axis of the crushing shell 24, a first opening and a second opening are respectively arranged at the upper part and the lower part of the screening shell 23, the first opening and the second opening are of a round structure, the diameter of the first opening is larger than that of the second opening, and a gap is reserved between the screening shell 23 and the crushing shell 24; the driving device 21 is arranged at the upper part of the sieving shell 23, and the driving device 21 is used for driving the sieving shell 23 to rotate; the pressing wheel 241 is rotatably arranged in the rotating groove along the axis of the rotating groove, and the pressing wheel 241 is contacted with the inner wall of the screening shell 23; the bearing devices 25 are arranged on the screening shell 23 in a penetrating manner along the direction perpendicular to the side wall of the screening shell 23, the bearing devices 25 are in sliding fit with the screening shell 23, the bearing devices 25 are provided with a plurality of bearing devices 25 which are uniformly distributed around the axis of the screening shell 23, the upper end surfaces of the bearing devices 25 in the screening shell 23 are coplanar with the lower end surfaces of the pressing wheels 241, the bearing devices 25 have elasticity, the inner wall of the shell 1 is provided with the discharge groove 11, and the inner wall of the shell 1 has a pressing effect on the bearing devices 25; the activating device 26 is arranged on the upper portion of the sieving shell 23, the activating device 26 rotates along with the sieving shell 23, a controller is arranged on one side of the activating device 26, a feeding device is arranged on the upper portion of the crushing shell 24, and the activating device 26 controls the feeding device to feed materials through the controller.

The upper part of the crushing shell 24 is provided with a feeding device, the feeding device directly extracts the reacted mixture, the mixture is composed of solid matters and solution, the mixture is fed into a gap between the screening shell 23 and the crushing shell 24, then the driving device 21 drives the screening shell 23 to rotate, the screening shell 23 drives the receiving device 25 arranged on the screening shell 23 to rotate, solution is stored in the mixture fed into the gap, the mixture falls on the inner wall of the screening shell 23 after being fed into the gap, the inner wall of the screening shell 23 is always in contact with the pressing wheel 241, the pressing wheel 241 can squeeze the mixture on the inner wall of the screening shell 23, the receiving device 25 can receive the mixture, residual solution in the squeezed mixture can be extruded while the pressing wheel 241 is used for squeezing and crushing the mixture, screening holes are formed in the side wall of the screening shell 23, the solution can overflow from the screening holes, the activating device 26 arranged on the upper part of the screening shell 23 synchronously rotates along with the screening shell 23, the feeding position of the feeding device positioned on the upper part of the crushing shell 24 is fixed, the feeding device can fall on the inner wall of the screening shell 23 when the feeding device is ensured to fall on the inner wall of the screening shell 23, the feeding device 25 can just need to be controlled to move to the activating device 26, and the feeding device 26 is just above the feeding device is required to be controlled to move, and the feeding device 26 is just controlled to start. It is worth noting that, because the solid and the solution are mixed together, under the soaking of the solution, the hardness of the solid is limited, so that the pressing wheel 241 is more convenient for extruding and crushing the solid, the time cost input that the traditional water sedimentation needs to take more time to wait for sedimentation is avoided, because the bearing device 25 has elasticity, when the bearing device 25 does not pass through the discharge groove 11, the bearing device 25 protrudes from the inner wall of the screening shell 23 under the pressure action of the inner wall of the shell 1, after the bearing device 25 passes through the discharge groove 11, the bearing device 25 can retract under the action of self elasticity, the bearing device 25 does not bear the bearing action on the crushed solid, the solid falls under the action of self gravity, the device also avoids the process that the worker salvages the sediment, the time of solid-liquid separation is reduced, and the crushing can be realized while the separation is realized.

Referring to fig. 3 and 4: the bearing device 25 comprises a first bearing plate 251, a spring 252 and a limiting plate 253; the first bearing plate 251 is arranged on the side wall of the sieving shell 23 in a penetrating way along the direction vertical to the side wall of the sieving shell 23, and the first bearing plate 251 is in sliding fit with the sieving shell 23; the limiting plate 253 is fixedly arranged at one end of the first bearing plate 251, which is positioned outside the screening shell 23, and a gap is reserved between the limiting plate 253 and the screening shell 23; a spring 252 is disposed within the gap.

When the first receiving plate 251 does not pass through the discharge groove 11, the limiting plate 253 is extruded by the inner wall of the housing 1, so that the first receiving plate 251 extends out of the inner wall of the screening shell 23, at the moment, the spring 252 is in a compressed state, the extending first receiving plate 251 has a receiving effect on solids, solution can be discharged from the screening holes on the screening shell 23, when the first receiving plate 251 passes through the position of the discharge groove 11, the limiting plate 253 is not limited by the inner wall of the housing 1 any more, the spring 252 drives the limiting plate 253 to reset, the first receiving plate 251 is retracted under the driving of the spring 252, the solids received on the first receiving plate 251 also fall, and after the solid passes through the discharge groove 11 completely, the inner wall of the housing 1 can jack up the limiting plate 253.

Referring to fig. 10: the bearing 25 further includes a second bearing plate 254; the second receiving plate 254 is fixedly arranged on the inner wall of the sieving shell 23 along the inclined direction of the peripheral wall of the sieving shell 23, the second receiving plate 254 is positioned on one side of the first receiving plate 251, the first receiving plate 251 is in sliding fit with the bottom side wall of the second receiving plate 254 when extending into the sieving shell 23, and the pressing wheel 241 is provided with a through groove.

When the sieving shell 23 rotates, the solid objects falling on the first receiving plate 251 will slide to one end of the first receiving plate 251 under the action of inertia, if no shielding object is arranged at one end of the first receiving plate 251, the situation that part of the solid objects slide from the first receiving plate 251 is caused, so that the situation that the solid objects cannot slide can be ensured by arranging the solid objects at the second receiving plate 254 at one end of the first receiving plate 251, meanwhile, the solid objects limited by the first receiving plate 251 and the second receiving plate 254 together can be normally pressed by the pressing wheel 241, and the blocking of the second receiving plate 254 can be avoided by the through groove arranged on the pressing wheel 241, so that the pressing wheel 241 can be ensured to normally roll.

Referring to fig. 2, 5 and 6: the activation device 26 includes a trigger block 261, a trigger button 262, and a feed chute 263; the trigger blocks 261 are uniformly arranged at the upper part of the screening shell 23 around the axis of the screening shell 23, the trigger blocks 261 are in one-to-one correspondence with the bearing devices 25, and the trigger blocks 261 synchronously rotate along with the screening shell 23; the feed chute 263 is formed on the side wall of the crushing shell 24, and the feeding device inputs the mixture into the feed chute 263; the trigger button 262 is disposed at the bottom of the support 22, the trigger button 262 is located above the feed chute 263, and the trigger block 261 can trigger the trigger button 262.

Since the trigger block 261 rotates synchronously with the sieving shell 23, and the trigger block 261 corresponds to the receiving device 25 one by one, when the trigger block 261 moves to the trigger button 262 and triggers the trigger button 262, it is indicated that the receiving device 25 is located below the feed chute 263, and the mixture just falls on the receiving device 25 at this time, it should be noted that since the sieving shell 23 is in a rotating state, the trigger block 261 needs to be disposed before the receiving device 25, so the trigger block 261 can trigger the trigger button 262 in advance, and a certain time is needed for the mixture delivered by the feeding device to fall on the receiving device 25 completely, so the quantity of the mixture received by the receiving device 25 can be increased by the advanced triggering.

Referring to fig. 1 and 2: the crushing and separating device 2 further includes a liquid discharging device 27, the liquid discharging device 27 including a collecting housing 271 and an on-off valve 272; the collecting shell 271 has a ring structure, the upper part of the collecting shell 271 is provided with a ring opening along the winding line of the collecting shell 271, and the collecting shell 271 is fixedly arranged at the bottom of the sieving shell 23

The switching valve 272 is provided at the bottom of the collection case 271.

The solution in the mixture flows into the collection case 271 after being extruded from the screening hole, and the on-off valve 272 is used to discharge water in the collection case 271.

Referring to fig. 2 and 5: the crushing and separating device 2 further comprises an anti-blocking device 29, and the anti-blocking device 29 comprises a blower 291 and an air pump 292; the blower 291 is arranged on the side wall of the shell 1 at the bottom of the discharge groove 11; an air pump 292 is provided at one side of the blower 291, and the air pump 292 supplies air to the blower 291.

After the device is started, the air pump 292 is continuously in an operating state, and the air blown by the air blower 291 can blow down the solid matters clamped on the screening holes, so that the screening holes are prevented from being blocked by the solid matters.

Referring to fig. 4: the receiving means 25 further comprises a sleeve 2521; the sleeve 2521 is a bellows, the sleeve 2521 is arranged in the gap along the straight line of the spring 252, and two ends of the sleeve 2521 are fixedly connected with the screening shell 23 and the limiting plate 253 respectively.

By sleeving the sleeve 2521 on the outside of the spring 252, it is ensured that the spring 252 is not corroded by external solutions.

Referring to fig. 10: the receiving device 25 further comprises a roller 2531; the roller 2531 is uniformly arranged on one side of the limiting plate 253, which is close to the shell 1, and the roller 2531 is in rolling fit with the inner wall of the shell 1.

If the roller 2531 is not arranged, the limiting plate 253 is in direct contact with the inner wall of the shell 1, so that the limiting plate 253 and the inner wall of the shell 1 are excessively worn, and after the roller 2531 is arranged, the friction coefficient between the limiting plate 253 and the shell 1 is greatly reduced, and further the wear of the limiting plate 253 and the shell 1 is reduced.

Referring to fig. 1 and 7: the drive means 21 comprises a first rotary drive 211, a gear 212 and a toothed ring 213; the first rotary driver 211 is disposed on the bracket 22, and an output end of the first rotary driver 211 is vertically downward; the gear 212 is fixedly arranged on the output end of the first rotary driver 211; the toothed ring 213 is fixedly provided at an upper portion of the sieving case 23 along an axis of the sieving case 23, and the gear 212 and the toothed ring 213 are engaged with each other.

The first rotary driver 211 is started, the first rotary driver 211 drives the gear 212 to rotate, and then the toothed ring 213 meshed with the gear 212 rotates, and the sieving shell 23 can be driven to rotate because the toothed ring 213 is fixedly connected with the upper part of the sieving shell 23.

Referring to fig. 1-3: the crushing and separating device 2 further includes a conveying device 28, and the conveying device 28 includes a conveying pipe 281, a connecting pipe 282, a second rotation driver 283, and a spiral blade 284; the connection pipe 282 is fixedly provided at the bottom of the collection housing 271 along the axis of the sieving housing 23; the conveying pipe 281 is horizontally arranged at the bottom of the connecting pipe 282, and the conveying pipe 281 is communicated with the connecting pipe 282; the second rotary driver 283 is horizontally fixedly provided at an end of the conveying pipe 281; the spiral blade 284 is rotatably provided in the conveying pipe 281 along the axis of the conveying pipe 281, and the second rotation driver 283 drives the spiral blade 284 to rotate.

When the receiving device 25 passes through the discharge groove 11, the receiving device 25 is retracted, the solid received by the receiving device 25 falls down, and the solid falls into the conveying pipe 281 through the connecting pipe 282 and is discharged under the driving of the spiral blade 284 driven by the second rotation driver 283.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. A waste water sedimentation type treatment device of a biopharmaceutical clean room comprises a shell (1) and a crushing and separating device (2);

the crushing and separating device (2) is characterized by comprising a driving device (21), a bracket (22), a screening shell (23), a crushing shell (24), a pressing wheel (241), a receiving device (25) and an activating device (26);

the bracket (22) is arranged above the shell (1);

the crushing shell (24) is of a rotary structure, the crushing shell (24) is vertically and fixedly arranged at the lower part of the bracket (22), a rotary groove is formed in the peripheral wall of the crushing shell (24), and the axis of the rotary groove is parallel to the inclined direction of the peripheral wall of the crushing shell (24);

the screening shell (23) is of a shell structure, the screening shell (23) is sleeved on the periphery of the crushing shell (24) along the axis of the crushing shell (24), a first opening and a second opening are respectively arranged at the upper part and the lower part of the screening shell (23), the first opening and the second opening are of circular structures, the diameter of the first opening is larger than that of the second opening, and a gap is reserved between the screening shell (23) and the crushing shell (24);

the driving device (21) is arranged at the upper part of the sieving shell (23), and the driving device (21) is used for driving the sieving shell (23) to rotate;

the pressing wheel (241) is rotationally arranged in the rotating groove along the axis of the rotating groove, and the pressing wheel (241) is contacted with the inner wall of the screening shell (23);

the bearing devices (25) are arranged on the screening shell (23) in a penetrating mode along the direction perpendicular to the side wall of the screening shell (23), the bearing devices (25) are in sliding fit with the screening shell (23), the bearing devices (25) are arranged in a plurality, the bearing devices (25) are uniformly distributed around the axis of the screening shell (23), the upper end faces of the bearing devices (25) in the screening shell (23) are coplanar with the lower end faces of the pressing wheels (241), the bearing devices (25) are elastic, the discharge grooves (11) are formed in the inner wall of the shell (1), and the inner wall of the shell (1) has a pressing effect on the bearing devices (25);

the activating device (26) is arranged on the upper portion of the screening shell (23), the activating device (26) rotates simultaneously with the screening shell (23), a controller is arranged on one side of the activating device (26), a feeding device is arranged on the upper portion of the crushing shell (24), and the activating device (26) controls the feeding device to feed through the controller.

2. The waste sink treatment facility of a biopharmaceutical clean room according to claim 1, wherein the receiving means (25) comprises a first receiving plate (251), a spring (252) and a limiting plate (253);

the first bearing plate (251) is arranged on the side wall of the screening shell (23) in a penetrating way along the direction perpendicular to the side wall of the screening shell (23), and the first bearing plate (251) is in sliding fit with the screening shell (23);

the limiting plate (253) is fixedly arranged at one end of the first bearing plate (251) positioned at the outer side of the screening shell (23), and a gap is reserved between the limiting plate (253) and the screening shell (23);

a spring (252) is disposed within the gap.

3. Waste water-sinking processing plant of a biopharmaceutical clean room according to claim 2, wherein the receiving means (25) further comprises a second receiving plate (254);

the second bearing plate (254) is fixedly arranged on the inner wall of the screening shell (23) along the inclined direction of the peripheral wall of the screening shell (23), the second bearing plate (254) is positioned on one side of the first bearing plate (251), the first bearing plate (251) is in sliding fit with the bottom side wall of the second bearing plate (254) when extending into the screening shell (23), and the pressing wheel (241) is provided with a through groove.

4. Waste water sink treatment plant of a biopharmaceutical clean room according to claim 1, wherein the activation device (26) comprises a trigger block (261), a trigger button (262) and a feed chute (263);

the trigger blocks (261) are uniformly arranged at the upper part of the screening shell (23) around the axis of the screening shell (23), the trigger blocks (261) are in one-to-one correspondence with the bearing devices (25), and the trigger blocks (261) synchronously rotate along with the screening shell (23);

the feeding groove (263) is formed in the side wall of the crushing shell (24), and the feeding device is used for feeding the mixture into the feeding groove (263);

the trigger button (262) is arranged at the bottom of the bracket (22), the trigger button (262) is positioned above the feeding chute (263), and the trigger block (261) can trigger the trigger button (262).

5. Waste water sedimentation treatment equipment of a biopharmaceutical clean room according to claim 1, wherein the comminution separation device (2) further comprises a drain device (27), the drain device (27) comprising a collecting housing (271) and a switching valve (272);

the collecting shell (271) is of an annular structure, an annular opening is formed in the upper part of the collecting shell (271) along a winding line of the collecting shell (271), and the collecting shell (271) is fixedly arranged at the bottom of the sieving shell (23)

The on-off valve (272) is provided at the bottom of the collection case (271).

6. A waste water sedimentation treatment plant of a biopharmaceutical clean room according to claim 1, wherein the comminution separation device (2) further comprises an anti-blocking device (29), the anti-blocking device (29) comprising a blower (291) and an air pump (292);

the blower (291) is arranged on the side wall of the shell (1) at the bottom of the discharge groove (11);

an air pump (292) is provided on one side of the blower (291), and the air pump (292) supplies air to the blower (291).

7. Waste water sink treatment plant of a biopharmaceutical clean room according to claim 2, wherein the receiving means (25) further comprises a sleeve (2521);

the sleeve pipe (2521) is a corrugated pipe, the sleeve pipe (2521) is arranged in the gap along the straight line of the spring (252), and two ends of the sleeve pipe (2521) are fixedly connected with the screening shell (23) and the limiting plate (253) respectively.

8. Waste water-sink treatment plant of a biopharmaceutical clean room according to claim 1, wherein the receiving means (25) further comprises rollers (2531);

the rollers (2531) are uniformly arranged on one side, close to the shell (1), of the limiting plate (253), and the rollers (2531) are in rolling fit with the inner wall of the shell (1).

9. Waste water sink treatment plant of a biopharmaceutical clean room according to claim 1, wherein the driving means (21) comprise a first rotary drive (211), a gear (212) and a toothed ring (213);

the first rotary driver (211) is arranged on the bracket (22), and the output end of the first rotary driver (211) is vertically downward;

the gear (212) is fixedly arranged on the output end of the first rotary driver (211);

the toothed ring (213) is fixedly arranged at the upper part of the sieving shell (23) along the axis of the sieving shell (23), and the gear (212) is meshed with the toothed ring (213).

10. The waste water sedimentation treatment apparatus of a biopharmaceutical clean room according to claim 5, wherein the comminution separation device (2) further comprises a conveying device (28), the conveying device (28) comprising a conveying pipe (281), a connecting pipe (282), a second rotary drive (283) and a screw blade (284);

the connecting pipe (282) is fixedly arranged at the bottom of the collecting shell (271) along the axis of the screening shell (23);

the conveying pipe (281) is horizontally arranged at the bottom of the connecting pipe (282), and the conveying pipe (281) is communicated with the connecting pipe (282);

the second rotary driver (283) is horizontally and fixedly arranged at the end part of the conveying pipe (281);

the spiral blade (284) is rotatably disposed in the conveying pipe (281) along the axis of the conveying pipe (281), and the second rotary driver (283) drives the spiral blade (284) to rotate.