CN111282318A - Macromolecular material waste water processing apparatus - Google Patents

Abstract

The invention discloses a high polymer material production wastewater treatment device, which comprises a treatment device main body, wherein a sieving cavity with an upward opening is arranged in the treatment device main body, a physical sieving device is arranged in the sieving cavity through chain wheel transmission and sieving net matching, a power generation cavity is communicated and arranged in the lower end wall of the sieving cavity, a turbine power generation device is arranged in the power generation cavity through a turbine and bevel gear combination matching, a sedimentation cavity is arranged at the lower side of the power generation cavity, a stirring and sedimentation device is arranged in the sedimentation cavity, a precipitator input pipe communicated with the outside is arranged at the upper side of the right end wall of the sedimentation cavity, and an input control valve is arranged on the upper side of the right end wall of the sedimentation cavity. Meanwhile, the precipitator is added quantitatively, so that the operation efficiency of the device is ensured.

Description

Macromolecular material waste water processing apparatus

Technical Field

The invention relates to the technical field of vulcanization wastewater treatment, in particular to a high polymer material production wastewater treatment device.

Background

Rubber can generate larger deformation under the action of smaller external force due to high elasticity, and meanwhile, the characteristics of remorse and recovery after the action of external force is removed and the like belong to a widely utilized one in high polymer materials, the rubber product needs to be vulcanized in the production process, then the waste liquid generated after the vulcanization treatment needs to be subjected to secondary treatment, the existing treatment modes are often carried out in large containers such as a reaction tank and the like, a precipitator cannot be added according to the amount of the waste liquid in the treatment process, the phenomena of insufficient precipitation or waste of the precipitator and the like are easily caused, the resources are not favorably and effectively and reasonably utilized, meanwhile, a large amount of electric energy needs to be externally provided by some existing wastewater treatment devices in the operation process, the energy-saving effect is poor, the kinetic energy generated in the operation process of the devices is always in a waste state, and the energy is not favorably recycled, ,.

Disclosure of Invention

The invention aims to provide a high polymer material production wastewater treatment device which is used for overcoming the defects in the prior art.

The invention relates to a polymer material production wastewater treatment device, which comprises a treatment device main body, wherein a sieving cavity with an upward opening is arranged in the treatment device main body, a physical sieving device is arranged in the sieving cavity through chain wheel transmission and a sieving net in a matching way, a power generation cavity is communicated and arranged in the lower end wall of the sieving cavity, a turbine power generation device is arranged in the power generation cavity through a turbine and a bevel gear assembly in a matching way, a sedimentation cavity is arranged at the lower side of the power generation cavity, a stirring and sedimentation device is arranged in the sedimentation cavity, a precipitant input pipe communicated with the outside and an input control valve are arranged at the upper side of the right end wall of the sedimentation cavity, a sliding rod is slidably arranged to control the on-off of the sedimentation cavity, a sedimentation outlet and an output control valve are arranged at the lower side of the right end wall of the sedimentation cavity, and a sealing cavity is communicated, the utility model discloses a deposit chamber, including setting up the driving chamber, setting up the driving chamber downside and setting up the gear train that staggers from top to bottom through the spline housing cooperation in the driving chamber, be provided with the kickboard that extends about extending in the settling chamber slidable, through the cooperation control between the oscilaltion of kickboard and drive belt and line wheel import sealing device passes through simultaneously the control of the oscilaltion of kickboard the precipitant input tube with the break-make of settling chamber is controlled, through the oscilaltion of kickboard is right the meshing of gear train is.

Further technical scheme, physics device that sieves is in including fixed setting sieve the motor that sieves in the chamber rear side end wall, sieve around the chamber rotationally be provided with bilateral symmetry's axle that sieves between the end wall, and the axle that sieves on right side with motor fixed connection sieves, be provided with fixed mounting in the chamber sieve the wheel that sieves of shaft surface, control two and be provided with the driving chain between the wheel of sieving, it installs to be provided with in the chamber sieve the net that sieves of transmission hinge surface, the chamber left side of sieving is provided with the storage space who is linked together with the external world, sieve be provided with in the chamber right side end wall with the transfer line that storage space is linked together.

According to the technical scheme, the turbine power generation device comprises a turbine motor arranged in the left end wall of a power generation cavity, a first rotating shaft is fixedly arranged at the right end of the turbine motor, a first bevel gear fixedly arranged on the right end face of the first rotating shaft is arranged in the power generation cavity, an installation block is fixedly arranged between the left end wall and the right end wall of the power generation cavity, a second rotating shaft extending up and down is rotatably arranged between the upper end face and the lower end face of the installation block, a second bevel gear fixedly arranged on the lower end face of the second rotating shaft and meshed with the first bevel gear is arranged in the power generation cavity, and a turbine fixedly arranged on the upper end face of the second rotating shaft is arranged in the power generation cavity.

A further technical scheme, the stirring sediment device sets up including the intercommunication the left first lift space of precipitation chamber, precipitation chamber right side intercommunication is provided with second lift space, just the kickboard left side is run through precipitation chamber left end wall and is stretched into in the first lift space, the kickboard right side is run through precipitation chamber right end wall and is stretched into in the second lift space, the intercommunication is provided with the spout that upwards extends in the second lift space upper end wall, just the spout upwards runs through the precipitant input tube, be provided with gliding wall pole from top to bottom in the spout, just wall pole lower extreme with kickboard up end fixed connection, the intercommunication is provided with the through-hole between the end wall about the wall pole.

In a further technical scheme, a third lifting space is arranged at the lower side of the first lifting space, a connecting plate capable of sliding up and down is arranged in the third lifting space, a first rack extending upwards is fixedly arranged on the upper end face of the connecting plate, the upper end of the first rack can extend into the first lifting space in a sliding manner, a first gear meshed with the first lifting space is rotatably arranged between the front end wall and the rear end wall of the first lifting space, a second rack fixedly arranged at the lower end of the floating plate and meshed with the first gear is arranged in the first lifting space, a push rod extending downwards is fixedly arranged on the lower end face of the connecting plate, the lower end of the push rod can extend into the transmission cavity in a sliding manner, a third rotating shaft extending up and down is rotatably arranged between the transmission cavity and the sedimentation cavity, and the lower end of the third rotating shaft is connected with the lower end wall of the transmission cavity in a rotating and matching manner, be provided with fixed mounting in the drip chamber the stirring piece of third pivot upper end, be provided with fixed mounting in the transmission chamber the spline housing of third pivot surface, third pivot surface is provided with gliding first spur gear from top to bottom, be provided with the ascending annular spacing groove of opening in the first spur gear, be provided with the stopper in the annular spacing groove slidable, just the push rod lower extreme with stopper upper end fixed connection, the fixed rotation motor that is provided with in the transmission chamber lower extreme wall, the fixed fourth pivot that is provided with in rotation motor upper end, be provided with fixed mounting in the transmission chamber fourth pivot upper end and with there is the second spur gear of meshing relation in first spur gear.

In a further technical scheme, the inlet sealing device comprises a transmission space arranged at the left side of the sedimentation chamber, an upward extending installation rod is fixedly arranged at the upper end of the floating plate, the upper end of the installation rod can slidably extend into the transmission space, a spring groove with an opening facing to the left upper part is arranged in the transmission space, a third rack capable of sliding left and right is arranged in the spring groove, a first electromagnet is arranged in the right end surface of the third rack, a second electromagnet matched with the first electromagnet is arranged in the right end wall of the spring groove, a second spring is fixedly arranged between the right end surface of the third rack and the right end wall of the spring groove, a third rotating shaft is connected between the front end wall and the rear end wall of the transmission space in a rotating matching manner, and a transmission gear which is fixedly arranged on the outer surface of the third rotating shaft and meshed with the third rack is arranged in the transmission space, the transmission space is internally provided with a ratchet wheel fixedly arranged on the outer surface of the third rotating shaft and a torsion spring, the transmission space is internally provided with a first belt wheel fixedly arranged on the outer surface of the third rotating shaft, the front end surface and the rear end surface of the transmission space are rotatably provided with a fourth rotating shaft, the transmission space is internally provided with a second belt wheel fixedly arranged on the outer surface of the fourth rotating shaft, and a transmission belt is arranged between the first belt wheel and the second belt wheel in a winding manner.

The technical scheme is that a left sealing block and a right sealing block are slidably arranged in the sealing space, a third spring is fixedly arranged between the left end face of the left sealing block and the left end wall of the sealing space, a fourth rack which is symmetrical in the front-back direction is fixedly arranged on the right end face of the left sealing block, the right end of the fourth rack slidably penetrates through the right sealing block, a fifth rotating shaft which is symmetrical in the front-back direction is rotatably arranged between the upper end wall and the lower end wall of the sealing space, a meshing gear meshed with the fourth rack is fixedly arranged on the outer surface of the fifth rotating shaft, a fifth rack which is symmetrical in the front-back direction and meshed with the meshing gear is fixedly arranged on the right end face of the right sealing block, a wire cavity is arranged on the right side of the sealing space, and wire wheels are rotatably matched with the front end wall and the rear end wall of the wire, the wire chamber with the intercommunication is provided with first wire guide between the confined space, the wire chamber with the intercommunication is provided with the second wire guide between the transmission space, be provided with fixed mounting in the transmission space the reel of fourth pivot surface, the reel external fixation twines has sealed acting as go-between, sealed acting as go-between is kept away from the one end of reel is passed through the wire chamber with stretch into after the wire wheel cooperation among the confined space with left side sealing block left end face fixed connection.

The invention has the beneficial effects that: the waste water treatment device is simple in structure and convenient to operate, the turbine is driven to rotate by the impact force generated when the waste water falls down, so that energy is provided for the operation of the device, meanwhile, the precipitator is added quantitatively according to the height of the liquid level of the waste water in the device and is stirred, the waste water treatment device is favorable for rapid precipitation, and the working efficiency is further accelerated.

Drawings

FIG. 1 is a schematic view of the internal overall structure of a wastewater treatment apparatus for polymer material production according to the present invention;

FIG. 2 is a schematic cross-sectional view taken along the line A-A of FIG. 1 according to the present invention;

FIG. 3 is a schematic top cross-sectional view of the inlet seal assembly of FIG. 1 according to the present invention;

FIG. 4 is a schematic diagram of the structure of FIG. 1 at B in accordance with the present invention;

fig. 5 is a schematic view of the structure of fig. 1 at C in the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1-5, a polymer material production wastewater treatment device according to an embodiment of the present invention includes a treatment device main body 100, a sieving cavity 127 with an upward opening is provided in the treatment device main body 100, a physical sieving device is provided in the sieving cavity 127 through a sprocket drive and a sieving mesh, a power generation cavity 135 is provided in the lower end wall of the sieving cavity 127 in a communication manner, a turbine power generation device is provided in the power generation cavity 135 through a turbine and bevel gear set in a combination manner, a settling cavity 143 is provided on the lower side of the power generation cavity 135, a stirring and settling device is provided in the settling cavity 143, a precipitant input pipe 141 communicated with the outside and provided with an input control valve 140 are provided on the upper side of the right end wall of the settling cavity 143, a sliding rod is slidably provided to control the on-off of the settling cavity 143, a settling outlet 148 and an output control valve 150 are provided on the lower side of the, the power generation cavity 135 with it is provided with sealed chamber 137 to communicate between the precipitation chamber 143, precipitation chamber 143 downside is provided with transmission chamber 105, be provided with the gear train that staggers from top to bottom through the spline housing cooperation in the transmission chamber 105, be provided with about extending kickboard 145 in the precipitation chamber 143 slidable, through the cooperation control between the upper and lower float of kickboard 145 and drive belt and the line wheel import sealing device, simultaneously through the upper and lower float control of kickboard 145 precipitant input tube 141 with the on-off of precipitation chamber 143 is controlled, through the upper and lower float of kickboard 145 is right the meshing of gear train is controlled in the transmission chamber 105.

Beneficially or exemplarily, the physical sieving device comprises a sieving motor fixedly arranged in the rear end wall of the sieving chamber 127, a left-right symmetrical sieving shaft 128 is rotatably arranged between the front end wall and the rear end wall of the sieving chamber 127, the right sieving shaft 128 is fixedly connected with the sieving motor, a sieving wheel 123 fixedly arranged on the outer surface of the sieving shaft 128 is arranged in the sieving chamber 127, a transmission chain 125 is arranged between the left sieving wheel 123 and the right sieving wheel 123, a sieving net 126 arranged on the outer surface of the transmission hinge 125 is arranged in the sieving chamber 127, a storage space 122 communicated with the outside is arranged at the left side of the sieving chamber 127, a transmission pipeline 124 communicated with the storage space 122 is arranged in the right end wall of the sieving chamber 127, production wastewater is slowly introduced through the sieving chamber 127, the sieving motor is started at the moment, and the sieving shaft 128 is driven to rotate by the sieving motor, the sieving shaft 128 drives the transmission hinge 125 to rotate counterclockwise through a chain transmission, and then the liquid flows downwards through the sieving mesh 126, and solid large particles enter the storage space 122 through the conveying pipeline 124, so that the collection of large particle waste in the wastewater is completed.

Advantageously or exemplarily, the turbine power generation device comprises a turbine motor 121 disposed in a left end wall of the power generation cavity 135, a first rotating shaft 133 is fixedly disposed at a right end of the turbine motor 121, a first bevel gear 134 is fixedly disposed in the power generation cavity 135 and is fixedly mounted on a right end surface of the first rotating shaft 133, a mounting block 131 is fixedly disposed between a left end wall and a right end wall of the power generation cavity 135, a second rotating shaft 130 extending up and down is rotatably disposed between an upper end surface and a lower end surface of the mounting block 131, a second bevel gear 132 is disposed in the power generation cavity 135 and is fixedly mounted on a lower end surface of the second rotating shaft 130 and is engaged with the first bevel gear 134, a turbine 129 is disposed in the power generation cavity 135 and is fixedly mounted on an upper end surface of the second rotating shaft 130, the second rotating shaft 130 is driven to rotate by an impact on the turbine 129 caused by a waste water flowing down, and the second rotating shaft 130 drives the first rotating shaft through an engagement relationship between the second The shaft 133 is rotated and the turbo motor 121 starts generating electricity.

Beneficially or exemplarily, the stirring and settling device comprises a first lifting space 167 disposed at the left side of the settling chamber 143 in a communicating manner, a second lifting space 146 is disposed at the right side of the settling chamber 143 in a communicating manner, the left side of the floating plate 145 penetrates through the left end wall of the settling chamber 143 and extends into the first lifting space 167, the right side of the floating plate 145 penetrates through the right end wall of the settling chamber 143 and extends into the second lifting space 146, an upwardly extending chute 136 is disposed in the upper end wall of the second lifting space 146 in a communicating manner, the chute 136 penetrates upwards through the precipitant input pipe 141, a blocking rod 138 capable of sliding up and down is disposed in the chute 136, the lower end of the blocking rod 138 is fixedly connected with the upper end surface of the floating plate 145, a through hole 142 is disposed between the left end wall and the right end wall of the blocking rod 138 in a communicating manner, the floating plate 145 is driven by the increase of wastewater in the settling chamber 143 to move upwards continuously, at this time, the through hole 142 is communicated with the precipitant input tube 141, the precipitant flows into the precipitation chamber 143 through the precipitant input tube 141 and the through hole 142, the blocking rod 138 is driven to move upwards with the rise of the liquid level, and after a proper amount of precipitant is introduced, the through hole 142 is located just above the precipitant input tube 141 and blocks the precipitant input tube 141 again.

Beneficially or exemplarily, a third lifting space 163 is provided at the lower side of the first lifting space 167, a connecting plate 164 capable of sliding up and down is provided in the third lifting space 163, a first rack 165 extending upward is fixedly provided at the upper end surface of the connecting plate 164, the upper end of the first rack 165 slidably extends into the first lifting space 167, a first gear 162 engaged with the first lifting space 167 is rotatably provided between the front and rear end walls of the first lifting space 167, a second rack 161 fixedly mounted at the lower end of the floating plate 145 and engaged with the first gear 162 is provided in the first lifting space 167, a push rod 111 extending downward is fixedly provided at the lower end surface of the connecting plate 164, the lower end of the push rod 111 slidably extends into the transmission chamber 105, a third rotating shaft 104 extending up and down is rotatably provided between the transmission chamber 105 and the settling chamber 143, the lower end of the third rotating shaft 104 is connected with the lower end wall of the transmission cavity 105 in a rotating fit manner, the settling cavity 143 is provided with a stirring block 147 fixedly mounted at the upper end of the third rotating shaft 104, the transmission cavity 105 is provided with a spline housing 103 fixedly mounted on the outer surface of the third rotating shaft 104, the outer surface of the third rotating shaft 104 is provided with a first straight gear 102 capable of sliding up and down, the first straight gear 102 is provided with an annular limiting groove 101 with an upward opening, the annular limiting groove 101 is slidably provided with a limiting block 106, the lower end of the push rod 111 is fixedly connected with the upper end of the limiting block 106, the lower end wall of the transmission cavity 105 is fixedly provided with a rotating motor 107, the upper end of the rotating motor 107 is fixedly provided with a fourth rotating shaft 108, the transmission cavity 105 is provided with a second straight gear 110 fixedly mounted at the upper end of the fourth rotating shaft 108 and meshed with the first, through the kickboard 145 drives second rack 161 rebound to drive through the meshing relation between the rack and pinion first rack 165 downstream, first rack 165 passes through push rod 111 drives first straight-tooth gear 102 downstream with the meshing of second straight-tooth gear 110, starts this moment rotate the motor 107 and drive fourth pivot 108 rotates, fourth pivot 108 passes through second straight-tooth gear 110 with the meshing relation of first straight-tooth gear 102 drives third pivot 104 rotates, thereby drives stirring block 147 rotates and accelerates the reaction of waste water and precipitant in the precipitation chamber 143.

Beneficially or exemplarily, the inlet sealing device comprises a transmission space 115 arranged at the left side of the settling chamber 143, an upward extending mounting rod 168 is fixedly arranged at the upper end of the floating plate 145, the upper end of the mounting rod 168 slidably extends into the transmission space 115, a spring slot 171 with an opening facing to the upper left is arranged in the transmission space 115, a third rack 172 capable of sliding left and right is arranged in the spring slot 171, a first electromagnet 182 is arranged in the right end surface of the third rack 172, a second electromagnet 183 matched with the first electromagnet 182 is arranged in the right end wall of the spring slot 171, a second spring 170 is fixedly arranged between the right end surface of the third rack 172 and the right end wall of the spring slot 171, a third rotating shaft 180 is connected between the front and rear end walls of the transmission space 115 in a rotating fit manner, a transmission gear 181 fixedly arranged on the outer surface of the third rotating shaft 180 and meshed with the third rack 172 is arranged in the transmission space 115, a ratchet wheel 175 fixedly mounted on the outer surface of the third rotating shaft 180 and a torsion spring 176 are arranged in the transmission space 115, a first belt wheel 174 fixedly mounted on the outer surface of the third rotating shaft 180 is arranged in the transmission space 115, a fourth rotating shaft 113 is rotatably arranged on the front and rear end surfaces of the transmission space 115, a second belt wheel 112 fixedly mounted on the outer surface of the fourth rotating shaft 113 is arranged in the transmission space 115, a transmission belt 109 is wound between the first belt wheel 174 and the second belt wheel 112, the floating plate 145 moves upwards to push the mounting rod 168 to move upwards, at this time, the third rack 172 is meshed with the transmission gear 181 to drive the torsion spring 176 to start to accumulate force, at this time, the ratchet wheel 175 is in an idle state, and when the third rack 172 rises to the top, the first electromagnet 182 and the second electromagnet 183 are started to drive the third rack 172 to overcome the elasticity of the second spring 170 and slide rightwards, at this time, the third rotating shaft 180 is driven to rotate by the torsion spring 176, and the second belt wheel 112 is driven to rotate by the driving belt 109, so as to drive the fourth rotating shaft 113 to rotate.

Beneficially or exemplarily, a left sealing space 153 extending left and right is communicated with and arranged in left and right end walls of the sealing cavity 137, a left sealing block 155 and a right sealing block 157 are slidably arranged in the sealing space 153, a third spring 154 is fixedly arranged between a left end surface of the left sealing block 155 and a left end wall of the sealing space 153, a fourth rack 156 symmetrical front and back is fixedly arranged on a right end surface of the left sealing block 155, a right end of the fourth rack 156 slidably passes through the right sealing block 157, a fifth rotating shaft 178 symmetrical front and back is rotatably arranged between upper and lower end walls of the sealing space 153, an engaging gear 158 engaged with the fourth rack 156 is fixedly arranged on an outer surface of the fifth rotating shaft 178, a fifth rack 160 symmetrical front and back and engaged with the engaging gear 158 is fixedly arranged on a right end surface of the right sealing block 157, and a lead cavity 118 is arranged on the right side of the sealing space 153, the front end wall and the rear end wall of the wire cavity 118 are provided with a wire guide wheel 117 in a rotating fit manner, a first wire guide hole 120 is communicated between the wire cavity 118 and the sealing space 153, a second wire guide hole 116 is communicated between the wire cavity 118 and the transmission space 115, a wire winding wheel 152 fixedly installed on the outer surface of the fourth rotating shaft 113 is arranged in the transmission space 115, a sealing pull wire 114 is fixedly wound on the outer surface of the wire winding wheel 152, one end, far away from the wire winding wheel 152, of the sealing pull wire 114 extends into the sealing space 153 through the cooperation of the wire cavity 118 and the wire guide wheel 117 and is fixedly connected with the left end surface of the left sealing block 155, the wire winding wheel 152 is driven to rotate through the fourth rotating shaft 113, the sealing pull wire 114 is discharged through the wire winding wheel 152 at the moment, and the left sealing block 155 is driven to move rightwards under the, meanwhile, the fourth rack 156 is driven to move rightwards by the left sealing block 155, and the right sealing block 157 is driven to move leftwards by the meshing relationship between the gear and the rack, so that the sealing cavity 137 is sealed.

In an initial state, the floating plate 145 is at the lowest point in the settling chamber 143, the through hole 142 and the precipitant input pipe 141 are vertically staggered, the first spur gear 102 is located at the upper side of the second spur gear 110, and the left sealing block 155 and the right sealing block 157 are maximally away from each other, so that the sealing chamber 137 is in an open state.

When the device is used, an operator introduces wastewater through the sieving cavity 127, then the sieving motor is started, large particles are sieved out and transferred to the storage space 122 through a physical sieving device, the first rotating shaft 133 is driven to rotate through the impact of the wastewater on the turbine 129 and the meshing between gear sets, electricity is generated through the turbine motor 121 to provide power for the rotation motor 107 to operate, the floating plate 145 is driven to move upwards along with the rise of the liquid level in the settling cavity 143, the through hole 142 is driven to be communicated with the precipitating agent input pipe 141, then precipitating agent is introduced through the precipitating agent input pipe 141, the blocking rod 138 is enabled to close the precipitating agent input pipe 141 again along with the continuous rise of the liquid level, and simultaneously the first straight gear 102 is driven to move downwards through the meshing relationship between the gear racks on the lower side to be meshed with the second straight gear 110, at this time, the rotating motor 107 is started, the third rotating shaft 104 is driven to rotate through the meshing relationship between the second spur gear 110 and the first spur gear 102, the stirring block 147 is used for stirring waste liquid to accelerate the generation of precipitate, the mounting rod 168 is driven to move upwards at the same time, the sealing pull wire 114 is loosened through transmission fit, the left sealing block 155 is driven to move rightwards under the action of the third spring 154, the right sealing block 157 is driven to move leftwards through the meshing relationship between the gear and the rack, the sealing cavity 137 is further closed, the output control valve 150 is opened to discharge the waste liquid after the precipitate is completely generated, at this time, the first electromagnet 182 and the second electromagnet 183 are closed, the third rack 172 is re-meshed with the transmission gear 181 under the action of the elasticity of the second spring 170, and the liquid level in the device continuously drops, the device resumes the initial state.

The invention has the beneficial effects that: the waste water treatment device is simple in structure and convenient to operate, the turbine is driven to rotate by the impact force generated when the waste water falls down, so that energy is provided for the operation of the device, meanwhile, the precipitator is added quantitatively according to the height of the liquid level of the waste water in the device and is stirred, the waste water treatment device is favorable for rapid precipitation, and the working efficiency is further accelerated.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (7)

1. The utility model provides a macromolecular material waste water processing apparatus, includes processing apparatus main substrate, its characterized in that: the device is characterized in that a sieving cavity with an upward opening is arranged in a main body of the treatment device, a physical sieving device is arranged in the sieving cavity in a matching way through a chain wheel transmission and a sieving net, a power generation cavity is communicated and arranged in the lower end wall of the sieving cavity, a turbine power generation device is arranged in the power generation cavity in a matching way through a turbine and a bevel gear, a sedimentation cavity is arranged at the lower side of the power generation cavity, a stirring sedimentation device is arranged in the sedimentation cavity, a precipitant input pipe communicated with the outside and an input control valve are arranged at the upper side of the right end wall of the sedimentation cavity, a sliding rod is arranged in the power generation cavity in a sliding way to control the on-off of the sedimentation cavity, a sedimentation outlet is arranged at the lower side of the right end wall of the sedimentation cavity and an output control valve are arranged, a sealing cavity is communicated and arranged between the power generation cavity and, the sedimentation chamber is provided with a floating plate extending left and right in a sliding mode, the inlet sealing device is controlled through up-and-down floating of the floating plate and matching between a transmission belt and a wire wheel, meanwhile, the precipitant input pipe and the sedimentation chamber are controlled through up-and-down floating of the floating plate, and meshing of the gear set in the transmission chamber is controlled through up-and-down floating of the floating plate.

2. The apparatus for treating wastewater from polymer production according to claim 1, wherein: physics device that sieves is including fixed setting sieve the motor that sieves in the chamber rear side end wall, sieve around the chamber rotationally be provided with bilateral symmetry's axle that sieves between the end wall, and the axle that sieves on right side with the motor fixed connection that sieves, be provided with fixed mounting in the chamber of sieving sieve the wheel that sieves of off-axial surface, control two and be provided with the driving chain between the wheel of sieving, it installs to be provided with in the chamber of sieving the net that sieves of transmission hinge surface, the chamber left side of sieving is provided with the storage space who is linked together with the external world, sieve be provided with in the chamber right side end wall with the transfer line that storage space is linked together.

3. The apparatus for treating wastewater from polymer production according to claim 1, wherein: the turbine power generation device comprises a turbine motor arranged in the left end wall of the power generation cavity, a first rotating shaft is fixedly arranged at the right end of the turbine motor, a first bevel gear fixedly arranged on the right end face of the first rotating shaft is arranged in the power generation cavity, an installation block is fixedly arranged between the left end wall and the right end wall of the power generation cavity, a second rotating shaft extending from top to bottom is rotatably arranged between the upper end face and the lower end face of the installation block, a second bevel gear fixedly arranged on the lower end face of the second rotating shaft and meshed with the first bevel gear is arranged in the power generation cavity, and a turbine fixedly arranged on the upper end face of the second rotating shaft is arranged in the power generation cavity.

4. The apparatus for treating wastewater from polymer production according to claim 3, wherein: the stirring sediment device sets up including the intercommunication the left first lift space of precipitation chamber, precipitation chamber right side intercommunication is provided with second lift space, just the kickboard left side is run through precipitation chamber left end wall and stretch into in the first lift space, the kickboard right side is run through precipitation chamber right end wall and stretch into in the second lift space, the intercommunication is provided with the spout that upwards extends in the second lift space upper end wall, just the spout upwards runs through the precipitant input tube, be provided with gliding wall pole from top to bottom in the spout, just wall pole lower extreme with kickboard up end fixed connection, the intercommunication is provided with the through-hole between the wall about the wall pole.

5. The apparatus for treating wastewater from polymer production according to claim 3, wherein: a third lifting space is arranged at the lower side of the first lifting space, a connecting plate capable of sliding up and down is arranged in the third lifting space, a first rack extending upwards is fixedly arranged on the upper end face of the connecting plate, the upper end of the first rack can extend into the first lifting space in a sliding manner, a first gear meshed with the first lifting space is rotatably arranged between the front end wall and the rear end wall of the first lifting space, a second rack fixedly arranged at the lower end of the floating plate and meshed with the first gear is arranged in the first lifting space, a push rod extending downwards is fixedly arranged on the lower end face of the connecting plate, the lower end of the push rod can extend into the transmission cavity in a sliding manner, a third rotating shaft extending up and down is rotatably arranged between the transmission cavity and the sedimentation cavity, and the lower end of the third rotating shaft is connected with the lower end wall of the transmission cavity in a rotating and matching manner, be provided with fixed mounting in the drip chamber the stirring piece of third pivot upper end, be provided with fixed mounting in the transmission chamber the spline housing of third pivot surface, third pivot surface is provided with gliding first spur gear from top to bottom, be provided with the ascending annular spacing groove of opening in the first spur gear, be provided with the stopper in the annular spacing groove slidable, just the push rod lower extreme with stopper upper end fixed connection, the fixed rotation motor that is provided with in the transmission chamber lower extreme wall, the fixed fourth pivot that is provided with in rotation motor upper end, be provided with fixed mounting in the transmission chamber fourth pivot upper end and with there is the second spur gear of meshing relation in first spur gear.

6. The apparatus for treating wastewater from polymer production according to claim 1, wherein: the inlet sealing device comprises a transmission space arranged on the left side of the sedimentation chamber, an upward extending installation rod is fixedly arranged at the upper end of the floating plate, the upper end of the installation rod can slidably extend into the transmission space, a spring groove with an opening facing to the upper left is arranged in the transmission space, a third rack capable of sliding left and right is arranged in the spring groove, a first electromagnet is arranged in the right end surface of the third rack, a second electromagnet matched with the first electromagnet is arranged in the right end wall of the spring groove, a second spring is fixedly arranged between the right end surface of the third rack and the right end wall of the spring groove, a third rotating shaft is connected between the front end wall and the rear end wall of the transmission space in a rotating matching manner, a transmission gear fixedly arranged on the outer surface of the third rotating shaft and meshed with the third rack is arranged in the transmission space, a ratchet wheel fixedly arranged on the outer surface of the third rotating shaft is arranged in the transmission space, and a, the transmission space is internally provided with a first belt wheel fixedly arranged on the outer surface of the third rotating shaft, the front end surface and the rear end surface of the transmission space are rotatably provided with a fourth rotating shaft, the transmission space is internally provided with a second belt wheel fixedly arranged on the outer surface of the fourth rotating shaft, and a transmission belt is wound between the first belt wheel and the second belt wheel.

7. The apparatus for treating wastewater from polymer production according to claim 6, wherein: a left sealing block and a right sealing block are slidably arranged in the sealing space, a third spring is fixedly arranged between the left end surface of the left sealing block and the left end wall of the sealing space, a fourth rack which is symmetrical front and back is fixedly arranged on the right end surface of the left sealing block, the right end of the fourth rack slidably penetrates through the right sealing block, a fifth rotating shaft which is symmetrical front and back is rotatably arranged between the upper end wall and the lower end wall of the sealing space, an engaging gear which is engaged with the fourth rack is fixedly arranged on the outer surface of the fifth rotating shaft, a fifth rack which is symmetrical front and back and is engaged with the engaging gear is fixedly arranged on the right end surface of the right sealing block, a wire cavity is arranged on the right side of the sealing space, a wire guide wheel is arranged on the front end wall and the rear end wall of the wire cavity in a rotating fit manner, and a first wire guide hole is communicated between the wire cavity and, the wire chamber with the intercommunication is provided with the second wire guide between the transmission space, be provided with fixed mounting in the transmission space the reel of fourth pivot surface, the reel external fixation winding has sealed acting as go-between, sealed acting as go-between is kept away from the one end of reel is passed through the wire chamber with stretch into after the wire wheel cooperation in the sealed space with left side sealed piece left end face fixed connection.

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