CN101835337A

CN101835337A - Plasma generator adopting parallel cooling mode

Info

Publication number: CN101835337A
Application number: CN 201010176674
Authority: CN
Inventors: 张志宏; 于宝成; 王华彬
Original assignee: WUHAN TIANHE TECHNOLOGY Co Ltd
Current assignee: WUHAN TIANHE TECHNOLOGY Co Ltd
Priority date: 2010-05-18
Filing date: 2010-05-18
Publication date: 2010-09-15
Anticipated expiration: 2030-05-18
Also published as: CN101835337B

Abstract

The invention relates to a plasma generator which adopts a parallel cooling mode, comprising an anode (1), a cathode (2) and water cooling systems; wherein the water cooling systems comprise two sets of water cooling systems which are respectively used for cooling the anode (1) and the cathode (2). The invention adopts two sets of water cooling systems which are connected in parallel and respectively used for cooling the anode and the cathode, has good cooling effect and creates conditions for improving the power of the plasma generator.

Description

Adopt the plasma generator of parallel cooling mode

Technical field

The present invention relates at coal fired boiler igniting, steady combustion, the plasma generator of direct firing coal-dust when combustion-supporting.

Background technology

Plasma generator is in the coal fired boiler extensive use, during plasma generator work, need its anode and negative electrode are cooled off, present plasma generator all adopts the water cooling system of series system, be that cooling circulating water elder generation's antianode (or negative electrode) cools off, and then target (or anode) cool off.The cooling effect of the water cooling system of series system is poor, has limited the raising of plasma generator power.

Summary of the invention

Technical problem to be solved by this invention is: provide a kind of plasma generator that adopts parallel cooling mode, the good cooling results of its cooling system.

The present invention solves the problems of the technologies described above the technical scheme that is adopted:

Adopt the plasma generator of parallel cooling mode, it comprises anode, negative electrode and water cooling system; Water cooling system comprises that two covers are respectively the water cooling system of anode, negative electrode cooling.

In the such scheme, the water cooling system that cools off for anode comprises anode inlet pipeline, anode discharge pipe line, anode intake tunnel, anode drainage channel, anode cooling chamber and anode drain chamber;

The water cooling system that cools off for negative electrode comprises negative electrode inlet pipeline, negative electrode discharge pipe line, negative electrode cooling chamber and negative electrode drain chamber;

The anode cooling chamber is arranged on the outer wall periphery of anode, and the anode drain chamber is arranged on the periphery of anode cooling chamber, and anode cooling chamber and anode drain chamber are in the front end UNICOM of anode;

The negative electrode cooling chamber is arranged on the outer wall periphery of negative electrode, and the negative electrode drain chamber is arranged on the periphery of negative electrode cooling chamber, and negative electrode drain chamber and negative electrode cooling chamber are in the front end UNICOM of negative electrode;

The anode intake tunnel is arranged on the periphery of negative electrode drain chamber, and the anode drainage channel is arranged on the periphery of anode intake tunnel;

In the rear end of anode, anode cooling chamber and anode intake tunnel UNICOM, anode drain chamber and anode drainage channel UNICOM;

In the rear end of negative electrode, negative electrode cooling chamber and negative electrode inlet pipeline UNICOM, negative electrode drain chamber and negative electrode discharge pipe line UNICOM, anode intake tunnel and anode inlet pipeline UNICOM, anode drainage channel and anode discharge pipe line UNICOM.

The present invention adopts two covers water cooling system in parallel to be respectively anode, negative electrode cooling, and good cooling results has been created condition for improving plasma generator power.

Description of drawings

Fig. 1 is the structural representation of the embodiment of the invention

Fig. 2 is the structural representation of anode and negative electrode cooling water system

Among the figure: 1, anode, 2, negative electrode, 3, the negative electrode cooling chamber, 4, negative electrode drain chamber, 5, anode intake tunnel, 6, the anode drainage channel, 7, the anode inlet pipeline, 8, anode discharge pipe line, 9, negative electrode discharge pipe line, 10, the negative electrode inlet pipeline, 11, plasma, 12, anode cooling chamber, 13, the anode drain chamber.The dotted arrow direction is an anode cooling water direction of travel, and the solid arrow direction is a negative electrode cooling water direction of travel.

Embodiment

Below in conjunction with drawings and Examples the present invention is described in further detail.

As shown in Figure 1, 2, the embodiment of the invention comprises anode 1, negative electrode 2 and water cooling system, and plasma 11 is from the front end ejection of anode 1; Water cooling system comprises two covers water cooling system in parallel, that be respectively anode 1, negative electrode 2 coolings.

The water cooling system that cools off for anode 1 comprises anode inlet pipeline 7, anode discharge pipe line 8, anode intake tunnel 5, anode drainage channel 6, anode cooling chamber 12 and anode drain chamber 13; Anode inlet pipeline 7 and anode discharge pipe line 8 respectively with the water supply and the drainage system UNICOM of outside.

The water cooling system that cools off for negative electrode 2 comprises negative electrode inlet pipeline 10, negative electrode discharge pipe line 9, negative electrode cooling chamber 3 and negative electrode drain chamber 4; Negative electrode inlet pipeline 10 and negative electrode discharge pipe line 9 respectively with the water supply and the drainage system UNICOM of outside.

Anode cooling chamber 12 is arranged on the outer wall periphery of anode 1, and anode drain chamber 13 is arranged on the periphery of anode cooling chamber 12, and anode cooling chamber 12 and anode drain chamber 13 are in the front end UNICOM of anode 1;

Negative electrode cooling chamber 3 is arranged on the outer wall periphery of negative electrode 2, and negative electrode drain chamber 4 is arranged on the periphery of negative electrode cooling chamber 3, and negative electrode drain chamber 4 and negative electrode cooling chamber 3 are in the front end UNICOM of negative electrode 2;

Anode intake tunnel 5 is arranged on the periphery of negative electrode drain chamber 4, and anode drainage channel 6 is arranged on the periphery of anode intake tunnel 5;

In the rear end of anode 1, anode cooling chamber 12 and anode intake tunnel 5 UNICOMs, anode drain chamber 13 and anode drainage channel 6 UNICOMs;

In the rear end of negative electrode 2, negative electrode cooling chamber 3 and negative electrode inlet pipeline 10 UNICOMs, negative electrode drain chamber 4 and negative electrode discharge pipe line 9 UNICOMs, anode intake tunnel 5 and anode inlet pipeline 7 UNICOMs, anode drainage channel 6 and anode discharge pipe line 8 UNICOMs.

For the cooling water of anode 1 cooling is discharged through anode inlet pipeline 7, anode intake tunnel 5, anode cooling chamber 12, anode drain chamber 13, anode drainage channel 6, anode discharge pipe line 8 successively.

For the cooling water of negative electrode 2 coolings is discharged through negative electrode inlet pipeline 10, negative electrode cooling chamber 3, negative electrode drain chamber 4, negative electrode discharge pipe line 9 successively.

Claims

1. adopt the plasma generator of parallel cooling mode, it comprises anode (1), negative electrode (2) and water cooling system; It is characterized in that: water cooling system comprises that two covers are respectively the water cooling system of anode (1), negative electrode (2) cooling.

2. plasma generator as claimed in claim 1 is characterized in that:

The water cooling system that cools off for anode (1) comprises anode inlet pipeline (7), anode discharge pipe line (8), anode intake tunnel (5), anode drainage channel (6), anode cooling chamber (12) and anode drain chamber (13);

The water cooling system that cools off for negative electrode (2) comprises negative electrode inlet pipeline (10), negative electrode discharge pipe line (9), negative electrode cooling chamber (3) and negative electrode drain chamber (4);

Anode cooling chamber (12) is arranged on the outer wall periphery of anode (1), and anode drain chamber (13) is arranged on the periphery of anode cooling chamber (12), and anode cooling chamber (12) and anode drain chamber (13) are in the front end UNICOM of anode (1);

Negative electrode cooling chamber (3) is arranged on the outer wall periphery of negative electrode (2), and negative electrode drain chamber (4) is arranged on the periphery of negative electrode cooling chamber (3), and negative electrode drain chamber (4) and negative electrode cooling chamber (3) are in the front end UNICOM of negative electrode (2);

Anode intake tunnel (5) is arranged on the periphery of negative electrode drain chamber (4), and anode drainage channel (6) is arranged on the periphery of anode intake tunnel (5);

Rear end in anode (1), anode cooling chamber (12) and anode intake tunnel (5) UNICOM, anode drain chamber (13) and anode drainage channel (6) UNICOM;

Rear end in negative electrode (2), negative electrode cooling chamber (3) and negative electrode inlet pipeline (10) UNICOM, negative electrode drain chamber (4) and negative electrode discharge pipe line (9) UNICOM, anode intake tunnel (5) and anode inlet pipeline (7) UNICOM, anode drainage channel (6) and anode discharge pipe line (8) UNICOM.