CN107457078A - The adjustable irregular arista electrode plate of Temperature Distribution based on Internet of Things - Google Patents

Abstract

The adjustable irregular arista electrode plate of Temperature Distribution based on Internet of Things, belongs to electrostatic precipitation field.It reaches suitable temperature conditionss in Electrostatic Treatment, so as to improve efficiency of dust collection mainly solving the technical problems that make the flue dust of different temperatures layer.It is by flue lower wall, flue entrance, first pyroelectricity temperature sensor, second pyroelectricity temperature sensor, 3rd pyroelectricity temperature sensor, sensor pull rod, flue upper wall, discharge electrode substrate, 3rd semiconductor refrigerating patch module, 3rd temperature conduction block, second temperature conductive block, second semiconductor refrigerating patch module, first temperature conduction block, first semiconductor refrigerating patch module, flue outlet, first prickle, second prickle, dust collecting pole plate, 3rd prickle, CC2530 modules, first resistor, first triode, first relay, 3rd relay, second resistance, second triode, second relay, 3rd triode, 3rd resistor forms.It is mainly used in electrostatic precipitation field.

Description

The adjustable irregular arista electrode plate of Temperature Distribution based on Internet of Things

Technical field

The invention belongs to electrostatic precipitation field, refers in particular to the adjustable irregular arista electrode of Temperature Distribution based on Internet of Things Plate.

Background technology

All there is high requirement in the purification of air contaminant treatment and gas laser chamber to the clearance of dust, and dust Ratio resistance is to determine a principal element of ESP Efficiency height.Fly ash resistivity value is higher, is to influence electric precipitation The key factor of device efficiency, how to improve the dust collection efficiency of high specific resistance ash is a great problem.Fly ash resistivity and flue gas temperature Spend it is relevant, between its peak value appears in 1 21 DEG C~232 DEG C according to coal ash characteristic, when more than 232 DEG C, the ratio resistance of flying dust with Absolute temperature is inversely proportional, unrelated with exhaust gas components；And when less than 121 DEG C, fly ash resistivity and PTAT.Dust Ratio resistance can regard as and be made up of two resistance in parallel, one of them is volume resistivity, i.e., is in by dust inner conductive Existing resistance, one is surface specific resistance, i.e., the resistance presented by dust surface conductance, and the various composition for forming dust is led Electrical property determines dust volume resistivity size, form the various materials of dust electric conductivity be affected by temperature significantly, when When temperature is higher, the ion of conduction electric current raises the conductive capability of dust layer with electronics by bigger energy is obtained in dust, Volume resistivity declines.The general ratio resistance for requiring flue dust is optimal in 104~1012 ohm/cms, as long as ensureing electric precipitation Device inlet temperature is between 135 DEG C~140 DEG C, with regard to that can reduce ratio resistance (p) value.p<104 ohm/cms, cause secondary fly-up, Efficiency of dust collection declines, the ohm/cm of p=104~1010, efficiency of dust collection highest, the ohm/cm of p≤1012, under dust-collecting efficiency Drop, p>1012 ohm/cms, efficiency of dust collection aggravate.Analyzed more than, ensure the temperature of flue before Electrostatic Treatment It is the essential condition for improving electrostatic precipitation efficiency between 135 DEG C~140 DEG C.In flue and laser resonance intracavitary Temperature Distribution It is not quite similar, it is so obviously unreasonable using same temperature processing for different temperatures layer, do not reach the purpose of accurate dedusting, be This present invention proposes the adjustable irregular arista electrode plate of Temperature Distribution based on Internet of Things.

The content of the invention

In order that the flue dust of different temperatures layer, suitable temperature conditionss are reached in Electrostatic Treatment, so as to improve dedusting effect Rate, the present invention propose the adjustable irregular arista electrode plate of Temperature Distribution based on Internet of Things.

The technical solution adopted for the present invention to solve the technical problems is：Apparatus of the present invention by flue lower wall, flue entrance, First pyroelectricity temperature sensor, the second pyroelectricity temperature sensor, the 3rd pyroelectricity temperature sensor, sensor pull rod, cigarette Road upper wall, electric discharge electrode substrate, the 3rd semiconductor refrigerating patch module, the 3rd temperature conduction block, second temperature conductive block, the second half Conductor refrigeration patch module, the first temperature conduction block, the first semiconductor refrigerating patch module, flue outlet, the first prickle, second Prickle, dust collecting pole plate, the 3rd prickle, CC2530 modules, first resistor, the first triode, the first relay, the 3rd relay, Second resistance, the second triode, the second relay, the 3rd triode, 3rd resistor composition, it is characterized in that：Flue lower wall is the same as receipts Dirt pole plate is connected, and the first pyroelectricity temperature sensor is connected with sensor pull rod, the second same sensor of pyroelectricity temperature sensor Pull bar is connected, and the 3rd pyroelectricity temperature sensor is connected with sensor pull rod, and flue upper wall is connected with sensor pull rod, discharge electrode Substrate is connected with flue upper wall, and the 3rd prickle is connected with the 3rd temperature conduction block, and the 3rd semiconductor refrigerating patch module is the same as the 3rd Temperature conduction block is connected, and the 3rd prickle is connected with electric discharge electrode substrate, and the second prickle is connected with electric discharge electrode substrate, and the first prickle is same to be put Electrode base board is connected, and the second prickle is connected with second temperature conductive block, and the second semiconductor refrigerating patch module passes with second temperature Guide block is connected, and the first prickle is connected with the first temperature conduction block, and the first semiconductor refrigerating patch module is the same as the first temperature conduction block It is connected, the first pyroelectricity temperature sensor is connected with CC2530 modules, and the second pyroelectricity temperature sensor is the same as CC2530 module phases Even, the 3rd pyroelectricity temperature sensor is connected with CC2530 modules, and first resistor is connected with CC2530 modules, and second resistance is same CC2530 modules are connected, and 3rd resistor is connected with CC2530 modules, and the first triode is connected with first resistor, and second resistance is the same as the Two triodes are connected, and the 3rd triode is connected with 3rd resistor, and the first semiconductor refrigerating patch module is same by the first relay First triode is connected, and the second semiconductor refrigerating patch module is connected by the second relay with the second triode, and the 3rd half leads The cold patch module of system is connected by the 3rd relay with the 3rd triode；The lower edge of first pyroelectricity temperature sensor is the same as the The lower prong of one prickle is on the same line；The lower prong of same second prickle of the lower edge of second pyroelectricity temperature sensor is same On one straight line；The lower prong of same 3rd prickle of the lower edge of 3rd pyroelectricity temperature sensor is on the same line；Any two The difference of prickle length is more than the width of the first pyroelectricity temperature sensor.

The lower prong of same first prickle of the lower edge of first pyroelectricity temperature sensor on the same line, can so make Temperature sensor measurement point is the first prickle tip；Lower prong of the lower edge of second pyroelectricity temperature sensor with the second prickle On the same line, temperature sensor measurement point can so be made for the second prickle tip；3rd pyroelectricity temperature sensor The lower prong of same 3rd prickle of lower edge on the same line, can so make temperature sensor measurement point for the 3rd prickle point End；The difference of any two prickle length is more than the width of the first pyroelectricity temperature sensor, can so ensure that sensor is surveyed The temperature value of amount is the tip temperature of a certain prickle, and is unlikely to two prickle tip temperatures and obscures.

Each prickle tip is important discharge end, and temperature when it discharges and the dust temperature around it are present Certain relation, while there is also difference for the different place laminar flow different temperatures of distribution of dust in flue.By each prickle tip Demarcation limiting figure exist in the single-chip microcomputer internal memory of CC2530 modules, each pyroelectricity temperature sensor is each by what is measured The temperature value at prickle tip is sent to CC2530 modules, and CC2530 modules are by the temperature value that sensor is sent with respective in internal memory Demarcation limiting figure compares, if less than demarcation limiting figure, no instruction is sent；If above limiting figure is demarcated, then CC2530 modules will send instruction, by resistance, triode, relay, connect the power supply of each semiconductor refrigerating patch module It is logical.Each semiconductor refrigerating patch module will freeze.Because each semiconductor refrigerating patch module is attached on temperature conduction block (temperature Degree conductive block is made up of temperature good conductor), the temperature of prickle will be adjusted.Each semiconductor refrigerating patch module, temperature pass Guide block, prickle, three pass through heat-conducting insulating silicon glue bond.

CC2530 is Internet of Things conventional chip.It is a real on-chip system of the ZigBee applications for 2.4GHz Solution.It can establish powerful network node with low-down total material cost.The chip combines leading RF The premium properties of transceiver, the enhanced 8051CPU of industrywide standard, In-System Programmable flash memory.CC2530 has different fortune Row mode so that the system that it especially adapts to super low-power consumption requirement.Conversion time between operational mode is short to be further ensure that Low energy expenditure.

The beneficial effects of the invention are as follows the flue dust for making different temperatures layer, and suitable temperature conditionss are reached in Electrostatic Treatment, So as to improve efficiency of dust collection.It is mainly used in electrostatic precipitation field.

Brief description of the drawings

The present invention is further described with reference to the accompanying drawings and examples.

Fig. 1 is the side sectional structural map of the adjustable irregular arista electrode plate of the Temperature Distribution based on Internet of Things.

Fig. 2 is the circuit diagram of the present invention.

1. flue lower wall in figure, 2. flue entrances, 3. first pyroelectricity temperature sensors, 4. second pyroelectricity TEMPs Device, 5. the 3rd pyroelectricity temperature sensors, 6. sensor pull rods, 7. flue upper walls, 8. electric discharge electrode substrates, 9. the 3rd semiconductor systems Cold patch module, 10. the 3rd temperature conduction blocks, 11. second temperature conductive blocks, 12. second semiconductor refrigerating patch modules, 13. First temperature conduction block, 14. first semiconductor refrigerating patch modules, 15. flue outlets, 16. first prickles, 17. second prickles, 18. dust collecting pole plate, 19. the 3rd prickles, 20.CC2530 modules, 21. first resistors, 22. first triodes, 23. first relays Device, 24. the 3rd relays, 25. second resistances, 26. second triodes, 27. second relays, 28. the 3rd triodes, 29. Three resistance.

Embodiment

In Fig. 1, flue lower wall 1 is connected with dust collecting pole plate 18, and the first pyroelectricity temperature sensor 3 is the same as sensor pull rod 6 It is connected, the second pyroelectricity temperature sensor 4 is connected with sensor pull rod 6,5 same sensor pull rod of the 3rd pyroelectricity temperature sensor 6 are connected, and flue upper wall 7 is connected with sensor pull rod 6, and electric discharge electrode substrate 8 is connected with flue upper wall 7, and the 3rd prickle 19 is the same as the 3rd Temperature conduction block 10 is connected, and the 3rd temperature conduction block 10 is connected the 3rd semiconductor refrigerating patch module 9 together, and the 3rd prickle 19 is put together Electrode base board 8 is connected, and the second prickle 17 is connected with electric discharge electrode substrate 8, and the first prickle 16 is connected with electric discharge electrode substrate 8, the second awns Thorn 17 is connected with second temperature conductive block 11, and the second semiconductor refrigerating patch module 12 is connected with second temperature conductive block 11, the One prickle 16 is connected with the first temperature conduction block 13, and the first semiconductor refrigerating patch module 14 is the same as the phase of the first temperature conduction block 13 Even.

In fig. 2, the first pyroelectricity temperature sensor 3 is connected with CC2530 modules 20, the second pyroelectricity temperature sensor 4 It is connected with CC2530 modules 20, the 3rd pyroelectricity temperature sensor 5 is connected with CC2530 modules 20,21 same CC2530 of first resistor Module 20 is connected, and second resistance 25 is connected with CC2530 modules 20, and 3rd resistor 29 is connected with CC2530 modules 20, the one or three pole Pipe 22 is connected with first resistor 21, and second resistance 25 is connected with the second triode 26, and the 3rd triode 28 is the same as the phase of 3rd resistor 29 Even, the first semiconductor refrigerating patch module 14 is connected by the first relay 23 with the first triode 22, the second semiconductor refrigerating Patch module 12 is connected by the second relay 27 with the second triode 26, and the 3rd semiconductor refrigerating patch module 9 passes through the 3rd Relay 24 is connected with the 3rd triode 28.

Claims (5)

1. the adjustable irregular arista electrode plate of Temperature Distribution based on Internet of Things, by flue lower wall, flue entrance, the first pyroelectricity temperature Spend sensor, the second pyroelectricity temperature sensor, the 3rd pyroelectricity temperature sensor, sensor pull rod, flue upper wall, discharge electrode Substrate, the 3rd semiconductor refrigerating patch module, the 3rd temperature conduction block, second temperature conductive block, the second semiconductor refrigerating paster Module, the first temperature conduction block, the first semiconductor refrigerating patch module, flue outlet, the first prickle, the second prickle, dust collector pole Plate, the 3rd prickle, CC2530 modules, first resistor, the first triode, the first relay, the 3rd relay, second resistance, Two triodes, the second relay, the 3rd triode, 3rd resistor composition, it is characterized in that：Flue lower wall is connected with dust collecting pole plate, First pyroelectricity temperature sensor is connected with sensor pull rod, and the second pyroelectricity temperature sensor is connected with sensor pull rod, the Three pyroelectricity temperature sensors are connected with sensor pull rod, and flue upper wall is connected with sensor pull rod, and discharge the same flue of electrode substrate Upper wall is connected, and the 3rd prickle is connected with the 3rd temperature conduction block, and the 3rd semiconductor refrigerating patch module is the same as the 3rd temperature conduction block It is connected, the 3rd prickle is connected with electric discharge electrode substrate, and the second prickle is connected with electric discharge electrode substrate, and the first prickle is the same as electric discharge electrode substrate phase Even, the second prickle is connected with second temperature conductive block, and the second semiconductor refrigerating patch module is connected with second temperature conductive block, the One prickle is connected with the first temperature conduction block, and the first semiconductor refrigerating patch module is connected with the first temperature conduction block, the first heat Release temperature sensor with CC2530 modules to be connected, the second pyroelectricity temperature sensor is connected with CC2530 modules, and the 3rd heat is released Temperature sensor is connected with CC2530 modules, and first resistor is connected with CC2530 modules, and second resistance is the same as CC2530 module phases Even, 3rd resistor is connected with CC2530 modules, and the first triode is connected with first resistor, and second resistance is the same as the second triode phase Even, the 3rd triode is connected with 3rd resistor, and the first semiconductor refrigerating patch module is by the first relay with the first triode It is connected, the second semiconductor refrigerating patch module is connected by the second relay with the second triode, the 3rd semiconductor refrigerating paster Module is connected by the 3rd relay with the 3rd triode.

2. the Temperature Distribution according to claim 1 based on Internet of Things is adjustable irregular arista electrode plate, it is characterized in that：First The lower prong of same first prickle of the lower edge of pyroelectricity temperature sensor is on the same line.

3. the Temperature Distribution according to claim 1 based on Internet of Things is adjustable irregular arista electrode plate, it is characterized in that：Second The lower prong of same second prickle of the lower edge of pyroelectricity temperature sensor is on the same line.

4. the Temperature Distribution according to claim 1 based on Internet of Things is adjustable irregular arista electrode plate, it is characterized in that：3rd The lower prong of same 3rd prickle of the lower edge of pyroelectricity temperature sensor is on the same line.

5. the Temperature Distribution according to claim 1 based on Internet of Things is adjustable irregular arista electrode plate, it is characterized in that：Arbitrarily The difference of two prickle length is more than the width of the first pyroelectricity temperature sensor.