CN109248788A - Rotary adaptive coalescence optimum voltage formal character system - Google Patents

Abstract

Rotary adaptive coalescence optimum voltage formal character system, belongs to electrostatic precipitation field.It is mainly solving the technical problems that in order to which determination reaches applied voltage form required for the optimal coalescence effect of microparticle.It is by preceding dedusting dust collecting pole plate, preceding flue lower wall, flue entrance, preceding flue upper wall, preceding dedusting discharge plate, flue collector particle diameter distribution sensor, preceding upper dust board, preceding upper oblique cover plate, first partition, first coalescence face pole plate, shell on rotatable cabin, upper cover plate, upper fixed link, first coalescence post pole plate, upper flat plate, upper oblique cover plate afterwards, upper dust board afterwards, first cohesion cabin particle diameter distribution sensor, rear pass upper wall, dedusting discharge plate afterwards, flue outlet, dedusting dust collecting pole plate afterwards, rear pass lower wall, first sensor strut, rotating shaft support bar afterwards, second sensor strut, relative coding angular transducer composition.It is mainly used for electrostatic precipitation field.

Description

Rotary adaptive coalescence optimum voltage formal character system

Technical field

The invention belongs to electrostatic precipitation field, rotary adaptive coalescence optimum voltage formal character system is referred in particular to.

Background technique

In the improvement of atmosphere pollution, the improvement of microparticle is a big problem.Since the partial size of microparticle is very small, such as Well-known PM2.5.Microparticle is all difficult to obtain satisfied effect using filter bag method and the method for electrostatic precipitation.? Electrostatic methods handle microparticle object when, by coalescence, by microparticle coalescence at bulky grain, then by electrostatic precipitation processes be compared with Good method.Usual coalescence type has: the coulomb coalescence of heteropolarity electrically charged particle, same polarity electrically charged particle are in alternating electric field Coalescence, coalescence etc. of the heteropolarity electrically charged particle in alternating electric field, these coalescence modes need additional different electric field, direct current , AC field.Additional different voltage is just needed in order to generate different internal electric fields.DC electric field needs DC voltage, hands over Galvanic electricity field needs alternating voltage.Since there are many type of fuel, which kind of electric field is suitble to the coalescence of particulate matter after which kind of fuel combustion It is uncertain.In order to reaching the optimal coalescence effect of microparticle, optimal electric field form is needed, thus is needed optimal additional Voltage form.For this purpose, the invention proposes rotary adaptive coalescence optimum voltage formal character systems.

Summary of the invention

In order to which determination reaches applied voltage form required for the optimal coalescence effect of microparticle, the invention proposes rotations Rotatable adaptive coalescence optimum voltage formal character system.

The technical solution adopted by the present invention to solve the technical problems is: apparatus of the present invention are by preceding dedusting dust collecting pole plate, preceding Flue lower wall, flue entrance, preceding flue upper wall, preceding dedusting discharge plate, flue collector particle diameter distribution sensor, preceding upper dust board, Preceding upper oblique cover plate, first partition, the first coalescence face pole plate, shell, upper cover plate, upper fixed link, the first coalescence post pole on rotatable cabin Plate, upper flat plate, afterwards upper oblique cover plate, upper dust board, the first cohesion cabin particle diameter distribution sensor, rear pass upper wall, rear dedusting are put afterwards Electrode plate, flue outlet, rear dedusting dust collecting pole plate, rear pass lower wall, first sensor strut, rear rotating shaft support bar, second pass Sensor strut, descends dust board afterwards, descends oblique cover plate, rotatable cabin lower casing, lower fixation afterwards the second cohesion cabin particle diameter distribution sensor Bar, pedestal, lower plate, lower cover plate, the second coalescence face pole plate, front lower oblique cover plate, front lower dust board, second partition, the second coalescence Post pole plate, shaft, front rotary shaft support rod, single-chip microcontroller, stepper motor, third partition, 3rd sensor strut, third cohesion cabin grain Diameter distribution sensor, third coalescence face pole plate, micro machine case, third coalescence post pole plate, rotatable cabin side shell, relative coding angle Sensor composition, it is characterized in that: the same flue lower wall of preceding dedusting dust collecting pole plate is connected, preceding dedusting dust collecting pole plate is in preceding flue lower wall Top, preceding the same dedusting discharge plate of flue upper wall is connected, and the same flue upper wall of flue collector particle diameter distribution sensor is connected, main Flue particle diameter distribution sensor is connected in the lower section of preceding flue upper wall, preceding upper the same flue upper wall of dust board, and preceding upper oblique cover plate is same Preceding flue upper wall is connected, and preceding upper oblique cover plate is connected with upper cover plate, and upper oblique cover plate is connected with upper cover plate afterwards, and upper oblique cover plate is the same as rear cigarette afterwards Road upper wall is connected, and upper dust board is connected with rear pass upper wall afterwards, and shell is same as above fixed link and is connected on rotatable cabin, the first coalescence face pole Plate is same as above fixed link and is connected, and upper flat plate is same as above fixed link and is connected, and the first coalescence face pole plate is connected with upper flat plate, rear dedusting discharge electrode Plate is connected with rear pass upper wall, and the first cohesion cabin particle diameter distribution sensor is connected with first sensor strut, and shaft is passed with first Sensor strut is connected, and the first coalescence post pole plate is connected with shaft, and the second coalescence post pole plate is connected with shaft, second sensor strut It is connected with shaft, the second cohesion cabin particle diameter distribution sensor is connected with second sensor strut, and micro machine case passes through relative coding Angular transducer is connected with shaft, and the same rotating shaft support bar of relative coding angular transducer is connected, the rear same shaft of rotating shaft support bar It is connected, first partition is connected with shaft, and second partition is connected with shaft, and rear rotating shaft support bar is connected with pedestal, front rotary shaft support Bar is connected with pedestal, and rear dedusting dust collecting pole plate is connected with rear pass lower wall, and lower oblique cover plate is connected with rear pass lower wall afterwards, rear lower block Dirt plate is connected with rear pass lower wall, and lower oblique cover plate is connected with lower cover plate afterwards, and second partition is connected with rotatable cabin lower casing, lower fixation Bar is connected with rotatable cabin lower casing, and lower fixed link is connected with the second coalescence face pole plate, and first partition is connected with shell on rotatable cabin, Lower fixed link is connected with lower plate, and lower plate is connected with the second coalescence face pole plate, and front lower oblique cover plate is connected with lower cover plate, preceding oblique The same flue lower wall of cover board is connected, and front lower the same flue lower wall of dust board is connected, the same single-chip microcontroller of flue collector particle diameter distribution sensor It is connected, the first cohesion cabin particle diameter distribution sensor is connected with single-chip microcontroller, and the second cohesion cabin particle diameter distribution sensor is the same as single-chip microcontroller phase Even, third agglomerates cabin particle diameter distribution sensor and is connected with single-chip microcontroller, and stepper motor is connected with single-chip microcontroller, relative coding angle sensor Device is connected with single-chip microcontroller；The length of first sensor strut is equal to the length of second sensor strut；First sensor strut Length is equal to the length of 3rd sensor strut；The length of first partition is equal to the length of third partition；The length of first partition Equal to the length of second partition.

This system is divided into three cabins, respectively the first coalescence cabin, the second coalescence cabin, third coalescence cabin.In first coalescence cabin There are the first coalescence face pole plate and the first coalescence post pole plate, the first coalescence face pole plate and the first coalescence post pole plate are connect into high pressure respectively and handed over The two poles of the earth in galvanic electricity source are high-voltage alternating electric field in this way between two pole plates in the first coalescence cabin；Have in second coalescence cabin Second coalescence face pole plate and the second coalescence post pole plate are connect high voltage direct current by two coalescence face pole plates and the second coalescence post pole plate respectively The anode and cathode in source are high voltage direct current negative electric field in this way between two pole plates in the second coalescence cabin；In third coalescence cabin There are third coalescence face pole plate and third coalescence post pole plate, third coalescence face pole plate and third coalescence post pole plate are connect into high straightening respectively The cathode and anode in galvanic electricity source are high voltage direct current positive electric field in this way between two pole plates in third coalescence cabin.

Since laminar flow of the microparticle object in flue is complicated, microparticle is distributed not in the different points in flue cross section Together, coalescence effect is also different.In order to accurately compare high voltage direct current positive electric field, high voltage direct current negative electric field, high-voltage alternating electric field, three The coalescence effect of which kind of electric field of person is more preferable, devises circular flue being divided into trisection, in such a way that circular flue rotates, So that each coalescence cabin is may be at position different in flue, thus eliminate in flue position difference to coalescence effect bring It influences.

Flue dust enters circular flue, the electric field pair of preceding dedusting discharge plate and preceding dedusting dust collecting pole plate composition by flue entrance The coarse granule of flue dust is dusted processing.Flue collector particle diameter distribution sensor monitoring treated flue dust microparticle distribution situation is simultaneously It is sent to single-chip microcontroller.Treated, and the flue dust containing microparticle respectively enters three coalescence cabins.Respectively in three coalescence cabins Internal electric field effect it is lower carry out coalescence, the particle situation after coalescence is coagulated by the first cohesion cabin particle diameter distribution sensor, second respectively Poly- cabin particle diameter distribution sensor, third cohesion cabin particle diameter distribution sensor record and are sent to single-chip microcontroller.Single-chip microcontroller records data Afterwards, issue instruction rotate stepper motor, the angle turned over is monitored by relative coding angular transducer and is sent to single-chip microcontroller, when turn Axis turns over 120 degree of angles, and single-chip microcontroller issues instruction step motor stalls, turned over a freight space at this time.

Treated, and the flue dust containing microparticle respectively enters three coalescence cabins.Internal electric field in three coalescence cabins respectively Effect is lower to carry out coalescence, and the particle situation after coalescence is respectively by the first cohesion cabin particle diameter distribution sensor, the second cohesion cabin partial size Distribution sensor, third cohesion cabin particle diameter distribution sensor record and are sent to single-chip microcontroller.After single-chip microcontroller records data, sending refers to Order rotates stepper motor, and the angle turned over is monitored by relative coding angular transducer and be sent to single-chip microcontroller, when shaft turns over 120 Angle is spent, single-chip microcontroller issues instruction step motor stalls, turned over a freight space at this time.

Treated, and the flue dust containing microparticle respectively enters three coalescence cabins.Internal electric field in three coalescence cabins respectively Effect is lower to carry out coalescence, and the particle situation after coalescence is respectively by the first cohesion cabin particle diameter distribution sensor, the second cohesion cabin partial size Distribution sensor, third cohesion cabin particle diameter distribution sensor record and are sent to single-chip microcontroller.Single-chip microcontroller is by three where cabin Angle, the particle data in each cabin recorded respectively are averaged, are then compared, and determine the big cabin of particle size For best coalescence cabin, institute's making alive is optimum voltage form.It then can achieve best coalescence effect by optimum voltage form making alive Fruit.Flue dust after coalescence is again introduced into electric field and does final dusting processing, to reach good dust removing effects.

The beneficial effects of the invention are as follows can determine applied voltage required for reaching the optimal coalescence effect of microparticle Form.It is mainly used for electrostatic precipitation field.

Detailed description of the invention

Present invention will be further explained below with reference to the attached drawings and examples.

Fig. 1 is the side sectional structural map of rotary adaptive coalescence optimum voltage formal character system.

Fig. 2 is coalescence cabin cross section right view.

Fig. 3 is circuit diagram of the invention.

Dedusting dust collecting pole plate before 1. in figure, flue lower wall before 2., 3. flue entrances, flue upper wall before 4., dedusting is put before 5. Electrode plate, 6. flue collector particle diameter distribution sensors, upper dust board before 7., upper oblique cover plate before 8., 9. first partitions, 10. first is solidifying And face pole plate, shell on 11. rotatable cabins, 12. upper cover plates, fixed link on 13., 14. first coalescence post pole plates, 15. upper flat plates, 16. upper oblique cover plate after, upper dust board after 17., 18. first cohesion cabin particle diameter distribution sensors, 19. rear pass upper walls remove after 20. Dirt discharge plate, 21. flue outlets, dedusting dust collecting pole plate after 22., 23. rear pass lower walls, 24. first sensor struts, 25. Rotating shaft support bar afterwards, 26. second sensor struts, 27. second cohesion cabin particle diameter distribution sensors, lower dust board after 28., 29. Oblique cover plate is descended afterwards, and 30. rotatable cabin lower casings, 31. lower fixed links, 32. pedestals, 33. lower plates, 34. lower cover plates, 35. second is solidifying And face pole plate, 36. front lower oblique cover plates, 37. front lower dust boards, 38. second partitions, 39. second coalescence post pole plates, 40. shafts, 41. front rotary shaft support rod, 42. single-chip microcontrollers, 43. stepper motors, 44. third partitions, 45. 3rd sensor struts, 46. thirds are solidifying Poly- cabin particle diameter distribution sensor, 47. third coalescence face pole plates, 48. micro machine casees, 49. third coalescence post pole plates, 50. rotatable cabins Side shell, 51. relative coding angular transducers.

Specific embodiment

In Fig. 1, the same flue lower wall 2 of preceding dedusting dust collecting pole plate 1 is connected, and preceding dedusting dust collecting pole plate 1 is in preceding flue lower wall 2 Top, the same dedusting discharge plate 5 of preceding flue upper wall 4 be connected, the same 4 phase of flue upper wall of flue collector particle diameter distribution sensor 6 Even, in the lower section of preceding flue upper wall 4, the same flue upper wall 4 of preceding upper dust board 7 is connected flue collector particle diameter distribution sensor 6, it is preceding on The same flue upper wall 4 of oblique cover plate 8 is connected, and preceding upper oblique cover plate 8 is connected with upper cover plate 12, and upper oblique cover plate 16 is the same as 12 phase of upper cover plate afterwards Even, upper oblique cover plate 16 is connected with rear pass upper wall 19 afterwards, and upper dust board 17 is connected with rear pass upper wall 19 afterwards, shell on rotatable cabin 11, which are same as above fixed link 13, is connected, and the first coalescence face pole plate 10 is same as above fixed link 13 and is connected, and ibid fixed link 13 is connected for upper flat plate 15, First coalescence face pole plate 10 is connected with upper flat plate 15, and rear dedusting discharge plate 20 is connected with rear pass upper wall 19, the first cohesion cabin Particle diameter distribution sensor 18 is connected with first sensor strut 24, and shaft 40 is connected with first sensor strut 24, the first coalescence Positive plate 14 is connected with shaft 40, and the second coalescence positive plate 39 is connected with shaft 40, and second sensor strut 26 is the same as 40 phase of shaft Even, the second cohesion cabin particle diameter distribution sensor 27 is connected with second sensor strut 26, and micro machine case 48 passes through relative coding angle It spends sensor 51 to be connected with shaft 40, the same rotating shaft support bar 41 of relative coding angular transducer 51 is connected, rear rotating shaft support bar 25 are connected with shaft 40, and first partition 9 is connected with shaft 40, and second partition 38 is connected with shaft 40, and rear rotating shaft support bar 25 is same Pedestal 32 is connected, and front rotary shaft support rod 41 is connected with pedestal 32, and rear dedusting dust collecting pole plate 22 is connected with rear pass lower wall 23, under rear Oblique cover plate 29 is connected with rear pass lower wall 23, and lower dust board 28 is connected with rear pass lower wall 23 afterwards, afterwards the lower same lower cover of oblique cover plate 29 Plate 34 is connected, and second partition 38 is connected with rotatable cabin lower casing 30, and lower fixed link 31 is connected with rotatable cabin lower casing 30, lower fixation Bar 31 is connected with the second coalescence face pole plate 35, and first partition 9 is connected with shell 11 on rotatable cabin, and lower fixed link 31 is the same as lower plate 33 It is connected, lower plate 33 is connected with the second coalescence face pole plate 35, and front lower oblique cover plate 36 is connected with lower cover plate 34, and front lower oblique cover plate 36 is same Preceding flue lower wall 2 is connected, and the same flue lower wall 2 of front lower dust board 37 is connected.

In Fig. 2, third agglomerates cabin particle diameter distribution sensor 46 and is connected with 3rd sensor strut 45, the first cohesion cabin grain Diameter distribution sensor 18 is connected with first sensor strut 24, and the second cohesion cabin particle diameter distribution sensor 27 is the same as second sensor branch Bar 26 is connected, and shell 11 and rotatable cabin lower casing 30 and rotatable cabin side shell 50 surround a circle on rotatable cabin.

In Fig. 3, flue collector particle diameter distribution sensor 6 is connected with single-chip microcontroller 42, the first cohesion cabin particle diameter distribution sensor 18 are connected with single-chip microcontroller 42, and the second cohesion cabin particle diameter distribution sensor 27 is connected with single-chip microcontroller 42, and third agglomerates cabin particle diameter distribution Sensor 46 is connected with single-chip microcontroller 42, and stepper motor 43 is connected with single-chip microcontroller 42, the same single-chip microcontroller of relative coding angular transducer 51 42 are connected.

Claims (5)

1. rotary adaptive coalescence optimum voltage formal character system, is entered by preceding dedusting dust collecting pole plate, preceding flue lower wall, flue Mouth, preceding flue upper wall, preceding dedusting discharge plate, flue collector particle diameter distribution sensor, preceding upper dust board, preceding upper oblique cover plate, first It is partition, the first coalescence face pole plate, shell on rotatable cabin, upper cover plate, upper fixed link, the first coalescence post pole plate, upper flat plate, rear oblique Cover board, afterwards upper dust board, the first cohesion cabin particle diameter distribution sensor, rear pass upper wall, rear dedusting discharge plate, flue outlet, Dedusting dust collecting pole plate, rear pass lower wall, first sensor strut, rear rotating shaft support bar, second sensor strut, the second cohesion afterwards Cabin particle diameter distribution sensor descends dust board afterwards, descends oblique cover plate, rotatable cabin lower casing, lower fixed link, pedestal, lower plate, lower cover afterwards Plate, the second coalescence face pole plate, front lower oblique cover plate, front lower dust board, second partition, the second coalescence post pole plate, shaft, front rotary shaft branch Strut, single-chip microcontroller, stepper motor, third partition, 3rd sensor strut, third cohesion cabin particle diameter distribution sensor, third are solidifying And face pole plate, micro machine case, third coalescence post pole plate, rotatable cabin side shell, relative coding angular transducer composition, feature Be: preceding the same flue lower wall of dedusting dust collecting pole plate is connected, and preceding dedusting dust collecting pole plate is in the top of preceding flue lower wall, preceding flue upper wall The same dedusting discharge plate is connected, and the same flue upper wall of flue collector particle diameter distribution sensor is connected, flue collector particle diameter distribution sensing Device is connected in the lower section of preceding flue upper wall, preceding upper the same flue upper wall of dust board, and preceding upper the same flue upper wall of oblique cover plate is connected, preceding Upper oblique cover plate is connected with upper cover plate, and upper oblique cover plate is connected with upper cover plate afterwards, and upper oblique cover plate is connected with rear pass upper wall afterwards, rear upper gear Dirt plate is connected with rear pass upper wall, and shell is same as above fixed link and is connected on rotatable cabin, and the first coalescence face pole plate is same as above fixed link and is connected, Upper flat plate is same as above fixed link and is connected, and the first coalescence face pole plate is connected with upper flat plate, and rear dedusting discharge plate is the same as rear pass upper wall phase Even, the first cohesion cabin particle diameter distribution sensor is connected with first sensor strut, and shaft is connected with first sensor strut, and first Coalescence post pole plate is connected with shaft, and the second coalescence post pole plate is connected with shaft, and second sensor strut is connected with shaft, and second is solidifying Poly- cabin particle diameter distribution sensor is connected with second sensor strut, and micro machine case is by relative coding angular transducer with shaft phase Even, the same rotating shaft support bar of relative coding angular transducer is connected, and rear rotating shaft support bar is connected with shaft, the same shaft of first partition It is connected, second partition is connected with shaft, and rear rotating shaft support bar is connected with pedestal, and front rotary shaft support rod is connected with pedestal, rear dedusting Dust collecting pole plate is connected with rear pass lower wall, and lower oblique cover plate is connected with rear pass lower wall afterwards, and lower dust board is the same as rear pass lower wall phase afterwards Even, lower oblique cover plate is connected with lower cover plate afterwards, and second partition is connected with rotatable cabin lower casing, and lower fixed link is the same as rotatable cabin lower casing phase Even, lower fixed link is connected with the second coalescence face pole plate, and first partition is connected with shell on rotatable cabin, and lower fixed link is the same as lower plate phase Even, lower plate is connected with the second coalescence face pole plate, and front lower oblique cover plate is connected with lower cover plate, front lower the same flue lower wall phase of oblique cover plate Even, front lower the same flue lower wall of dust board is connected, and flue collector particle diameter distribution sensor is connected with single-chip microcontroller, the first cohesion cabin partial size Distribution sensor is connected with single-chip microcontroller, and the second cohesion cabin particle diameter distribution sensor is connected with single-chip microcontroller, and third agglomerates cabin partial size point Cloth sensor is connected with single-chip microcontroller, and stepper motor is connected with single-chip microcontroller, and relative coding angular transducer is connected with single-chip microcontroller.

2. rotary adaptive coalescence optimum voltage formal character system according to claim 1, it is characterized in that: first passes The length of sensor strut is equal to the length of second sensor strut.

3. rotary adaptive coalescence optimum voltage formal character system according to claim 1, it is characterized in that: first passes The length of sensor strut is equal to the length of 3rd sensor strut.

4. rotary adaptive coalescence optimum voltage formal character system according to claim 1, it is characterized in that: first every The length of plate is equal to the length of third partition.

5. rotary adaptive coalescence optimum voltage formal character system according to claim 1, it is characterized in that: first every The length of plate is equal to the length of second partition.