CN201113678Y - Large-capacity synchronizing generator cooling wind path - Google Patents

Abstract

The utility model relates to a large capacity synchronous generator cooling air path, which is mainly characterized in that: a cooler is arranged on the top of a main generator; cooling air inside the main generator is communicated respectively with an air inlet area and an air return area of the main generator through an air path channel, and is communicated with an air gap cooling air path, a rotor cooling air path, a stator cooling air path and an excitation cooling air path of the main generator; heat-carrying air after cooling enters the cooler through the air return area of the main generator, so as to form a complete multi-loop circulatory four air duct cooling path. The cooling air path ensures that each component of the generator can achieve ideal cooling effect, and has the advantages of reasonable structure design, high cooling coverage rate, good effect, reliable operation performance, convenient installation and maintenance, etc.

Description

The high capacity synchronous generator cooling air duct

Technical field

The utility model belongs to generator cooling technology field, particularly a kind of high capacity synchronous generator cooling air duct.

Background technology

High-rating generator must cool off, so that the hear rate that winding and iron core produced in stator and the rotor is dissipated in order to guarantee trouble-free operation and to make full use of for the purpose of its output capacity.In the generator operation process, the energy loss that is produced by magnetic force and electric energy can convert heat in generator inside, cause the each several part temperature to raise, cause the impedance of coil to raise thus, influence generating efficiency, can cause the damage of conductive member insulating barrier and the damage of other member simultaneously, thereby effectively cooling is one of main miscellaneous function of generator.In technique known, the cooling air duct of large-scale empty internal cooling generator is arranged on the bottom of main generator usually, the major defect of its existence is: (1) generator dispatches from the factory needs the split packed and transported, on-the-spot installation must be constructed huge melt pit basis, time-consuming taking a lot of work, cause installation period long, expense height, and cooler installation and maintenance inconvenience; (2) have only a heat exchanger in the cooler usually, in case break down, then fault power time is long, and the influence generating is produced; (3) generator amature is as main heat generating components, and only abutment surface contacts cooling air, and inside only depends on the heat conduction of self slowly to dispel the heat, take away heat very little, radiating effect is poor, causes coil burnout, failure of insulation easily, operational reliability is poor, especially end winding, centralized heat energy has the retaining ring cladding again, heat is difficult for distributing, the easiest breaking down; (4) exciter is generally adopted exposure formula or semi-enclosed air-cooled, cold air can only blow to its surface, and exciter inside is not reached desirable radiating effect, and greasy dirt, dust enter internal body easily simultaneously, cause accidents such as failure of insulation, short circuit.Though in the prior art generator cooling air duct is updated, cooling effect is all not ideal, and what for example have offers the axial ventilation groove in rotor coil bottom, but since cooling air enter in the groove from two ends, can't circulation cycle, do not reach the effect of cooling.

The utility model content

The purpose of this utility model provides a kind of can effectively the cooling each member in the generator, and reasonable in design, cooling coverage rate height, effective, runnability reliable, installation and maintenance high capacity synchronous generator cooling air duct easily.

Realize that the technical scheme that the purpose of this utility model is taked is: this cooling air duct is made up of cooler and generator cooling air duct, wherein: cooler places the top of main generator, cooling air in it is communicated with the air intake district and the return air district of main generator respectively by the wind path passage, and be communicated with air gap cooling air duct, rotor cooling air duct, stator cooling air duct, the excitation cooling air duct of main generator, cooled take hot-air by main generator the return air district and enter cooler, forms the four air channel cooling paths that a complete multiloop circulates.

Two cover heat exchanger package are set in the described cooler, and every cover heat exchanger package is made up of the heat exchanger of two phases and cascade.

Be provided with the return air baffler that is communicated with heat exchanger package respectively in the described cooler.

Described rotor cooling air duct is to be made of the radial ducts that between the rotor core nest plate of axial ventilation groove of offering on the rotor shaft and connection with it and rotor coil end is provided with respectively.

Described rotor core adopts grouping nest plate type structure, is provided with the tooth support of being with radial ducts between every group of nest plate.

Correspondence is provided with a plurality of ventilation holes on the inboard coil brace that is provided with of the retaining ring circumference of described rotor coil end and centering ring, and this ventilation hole is connected with the axial ventilation groove of rotor shaft.

Described stator cooling air duct is to be made of the main generator return air district that cavity between stator coil end cooling zone, stator end plate and the stator dividing plate forms.

Described air gap cooling air duct is to be made of the axial air-gap passage that is provided with between stator, the rotor, and crosses with rotor wind path and stator wind path and to enter main generator return air district.

The air intake district of described main generator is made of the re-entrant portion that forms between the reinforcement dividing plate of the box support left and right sides that is closed and the stator end plate.

Described exciter wind path be by the setting of exciter case top be communicated with main generator cooling air duct air intake district advance, the gap forms between return air duct and excitation generator two ends and the exciter housing advances, the air gap channel of return air district and excitation generator constitutes.

According to the high capacity synchronous generator cooling air duct that such scheme is made, its beneficial effect is:

(1) the rotor cooling air duct by setting up in the main generator ring cooling path, and offer respectively axially and radial ducts at rotor shaft, rotor core and end winding, interior each air quantity of generator is distributed rationally, stator, rotor temperature rise are even, make each member of generator all can reach desirable cooling effect, thereby can eliminate the various operation troubless that cause because of heating effectively, improve the production efficiency of generator greatly.

(2) cooler adopts the overhead structure, and installation and maintenance are convenient, and huge heavy pit foundation plinth need not be constructed in the scene of using, and can save a large amount of mounting costs, can shorten air pipe simultaneously, reduces the cooling energy loss and improves cooling effectiveness.

(3) heat exchanger adopts two groups of cascade structures, can strengthen the operational reliability and the fail safe of cooling air duct greatly, even if under the part heat exchanger breaks down the situation that lost efficacy or keeped in repair, also can ensure the underrun of generator, can avoid the generation of complete machine fault effectively.

(4) exciter is carried out closed circulation cooling, both can receive better heat radiating effect, also can avoid the intrusion of greasy dirt, dust, can protect the normal operation of excitation system effectively, prolong the useful life of exciter.

(5) this generator cooling air duct also has reasonable in design, cooling coverage rate height, effective, advantage such as runnability is reliable, installation and maintenance are easy.

Description of drawings

Fig. 1 is a generator cooling air duct structural representation of the present utility model;

Fig. 2 is the structural representation of rotor cooling air duct;

Fig. 3 is the partial enlarged drawing of I among Fig. 2;

Fig. 4 is the A-A cutaway view among Fig. 2;

Fig. 5 is the structural representation of exciter cooling air duct.

Embodiment

Referring to Fig. 1, generator cooling air duct of the present utility model, comprise by support 1, cooler 2, stator 3, rotor 4, main generator cooling air duct and exciter cooling air duct that exciter 5 constitutes, wherein, the support 1 of main generator is the case structure that closed circulation is ventilated, its left and right sides is support end plate 1-1, two end plates inboard and middle part are equipped with parallel with it reinforcement dividing plate 1-2, be formed for ventilate the air intake district f1 of cooling and the cooling zone f3 of stator coil 3-2 end between this dividing plate and the stator end plate 3-1, the main generator return air district f2 that cools off that is used to ventilate is made of stator end plate 3-1 and stator dividing plate 3-3 re-entrant portion each other, is provided with between support 1 top and the cooler 2, return air channel 1-3,1-4.

On-the-spot for convenience the installation, save the cooler basis and construct engineering, shorten wind path simultaneously, reduce the cooling energy loss, cooler 2 is arranged on the top of main generator support 1, in two cover heat exchanger package 2-1 and the herringbone return air baffler 2-2 that are communicated with two groups of heat exchangers respectively are housed, every cover heat exchanger package 2-1 is made up of the heat exchanger of two phases and cascade, in two cover heat exchanger package 2-1, there is a heat exchanger to break down, generator still can normally move under the situation with load more than 66%, the setting of return air baffler 2-2 can make the mobile current stabilization state that is in of taking hot-air of return air channel 1-4, and avoids forming eddy current or circulation dead angle.Cooling air in the cooler 2 respectively by advance, return air channel 1-3,1-4 be communicated with the air intake district f1 and the return air district f2 of main generator, and be communicated with air gap cooling air duct, rotor cooling air duct, stator cooling air duct, the excitation cooling air duct of main generator, the cooled hot-air of taking enters cooler 2 by the return air district f2 at main generator middle part and the return air channel 1-4 at support top, forms four air channel cooling paths of a complete multiloop circulation.

Stator cooling air duct in the main generator is to be made of the main generator return air district f2 that cavity between stator coil end cooling zone f3, stator end plate 3-1 and the stator dividing plate 3-3 forms, stator end plate 3-1 is fixed on the connection support plate 3-5 of stator supporter, and and the reinforcement dividing plate 1-2 of generator pit two end plates 1-1 inboard between form the air intake district f1 of main generator cooling air duct, be provided with the radially cooling air channel that is communicated with main generator return air district in the stator core.In order to be beneficial to ventilation and heat, the end of the concentrated stator coil 3-2 of heat is effectively cooled off, end grouping colligation 3-4 on the coil brace in the stator end plate 3-1 outside of stator coil 3-2.

Referring to Fig. 2, Fig. 3, Fig. 4, the rotor cooling air duct in the main generator is to be made of the axial ventilation groove 4-9 that is communicated with radial ducts that offers on radial ducts that is provided with between the rotor core nest plate and the rotor shaft 4-1.The cooling heat dissipation of rotor 4 is difficult points of whole generating unit cooling, in order to address this problem preferably, rotor 4 adopts grouping nest plate type structure, be provided with the tooth support 4-8 that is with the radial ventilation groove between every group of nest plate, and offer the axial ventilation groove 4-9 that several are communicated with the radial ventilation groove at the excircle position of rotor shaft 4-1, cooling air can cool off the nest plate 4-3 and the rotor coil 4-2 body of rotor core simultaneously by the slit between axial ventilation groove 4-9 and the rotor coil 4-2.In the generator operation process, refrigerating gas is entered by ventilation slot 4-9 two ends, flows into air gap through the air duct of tooth support 4-8, and is back in the cooler by the radially return air channel of stator.Can make rotor coil 4-2 and rotor nest plate 4-3 receive good result of ventilating heat dissipation.Rotor coil 4-2 end is the position that heat is comparatively concentrated, therefore on the coil brace 4-10 of rotor end bell 4-4 and centering ring 4-7, be laid with a plurality of ventilation hole 4-6,4-11, and be connected with the axial ventilation groove 4-9 of rotor shaft 4-1, the refrigerating gas of air intake district f1 is at first cooled off rotor tip by the axial ventilation groove 4-9 of rotor shaft 4-1 and the radial ventilation hole of tooth support 4-8.Rotor fan 4-5 adopts radially centrifugal fan, and in order to strengthen the operating rigidity of fan, rotor fan is directly installed on the centering ring 4-7 of rotor coil end, also can reduce the axial dimension of whole generating machine simultaneously, makes its structure compact more.

Referring to Fig. 5, the exciter wind path is that the air gap channel by advancing of forming of gap between the advancing of being communicated with main generator cooling air duct air intake district f1 of being provided with of exciter housing 5-1 top, return air duct 5-2,5-3 and excitation generator 5 two ends and the exciter housing 5-1, return air district f5, f6 and excitation generator 5-4 constitutes.The exciter wind path enters exciter air intake district f5 through intake stack 5-2 by main generator cooling air duct air intake district f1 under the graviational interaction of exciter fan 5-5, after cooling off excitation generator, the air gap of excitation generator 5-4 enters return air district f6, rotary rectifier assembly 5-6 and permanent magnet generator 5-7 also obtain cooling simultaneously, take hot-air by the air intake district f1 that the return air duct 5-3 of exciter 5 gets back to the main generator cooling air duct again, form the exciter cooling circuit thus.Because it is less that this part air carries heat, therefore can be used for once more the main generator cool cycles.

The main generator cooling air duct adopts four air channel cooling paths of multiloop circulation, its cooling principle is: cooling air enters the air intake district f1 of main generator end by the air intake passage 1-3 at support 1 top board two ends, by being divided into rotor cooling air duct, stator cooling air duct and air gap cooling air duct behind the rotor fan 4-5.The air-flow of rotor cooling air duct enters rotor along the axial ventilation groove 4-9 on the rotor shaft 4-1, enter air gap f4 between the stator and rotor by the ventilation hole 4-6 on the retaining ring 4-4 behind wherein a part of cooled rotor coil 4-2 end, the radial ducts of another part between rotor core nest plate 4-3 also enters the air gap f4 between the stator and rotor, and two strands of air-flows are together incorporated the air gap cooling air duct into and circulated therewith.The air-flow of stator cooling air duct enters air gap f4 after stator coil end cooling zone f3 cooling, incorporate the air gap wind path into and circulate together.The air communication of air gap cooling air duct is crossed the air gap f4 that directly enters behind the rotor fan 4-5 between stator and the rotor, and enters in the radially wind path passage between the stator core lamination with the air-flow that rotor and stator end coil come out.The hot-air of taking that confluxes enters cooler 2 by the return air channel 1-4 at support top, divide two-way to cool off by two groups of heat exchangers respectively along herringbone dividing plate 2-2 then, cooled air enters the main generator cooling air duct through the air intake passage 1-3 at support top once more, thereby forms a complete sealing and circulating cooling path.

Claims (10)

1, a kind of high capacity synchronous generator cooling air duct, form by cooler and generator cooling air duct, it is characterized in that: cooler places the top of main generator, cooling air in it is communicated with the air intake district and the return air district of main generator respectively by the wind path passage, and be communicated with air gap cooling air duct, rotor cooling air duct, stator cooling air duct, the excitation cooling air duct of main generator, cooled take hot-air by main generator the return air district and enter cooler, forms the four air channel cooling paths that a complete multiloop circulates.

2, high capacity synchronous generator cooling air duct according to claim 1 is characterized in that: two cover heat exchanger package are set in the described cooler, and every cover heat exchanger package is made up of the heat exchanger of two phases and cascade.

3, high capacity synchronous generator cooling air duct according to claim 1 is characterized in that: be provided with the return air baffler that is communicated with heat exchanger package respectively in the described cooler.

4, high capacity synchronous generator cooling air duct according to claim 1 is characterized in that: described rotor cooling air duct is to be made of the radial ducts that between the rotor core nest plate of axial ventilation groove of offering on the rotor shaft and connection with it and rotor coil end is provided with respectively.

5, high capacity synchronous generator cooling air duct according to claim 4 is characterized in that: described rotor core adopts grouping nest plate type structure, is provided with the tooth support of being with radial ducts between every group of nest plate.

6, high capacity synchronous generator cooling air duct according to claim 4, it is characterized in that: correspondence is provided with a plurality of ventilation holes on the inboard coil brace that is provided with of the retaining ring circumference of described rotor coil end and centering ring, and this ventilation hole is connected with the axial ventilation groove of rotor shaft.

7, high capacity synchronous generator cooling air duct according to claim 1 is characterized in that: described stator cooling air duct is to be made of the main generator return air district that cavity between stator coil end cooling zone, stator end plate and the stator dividing plate forms.

8, high capacity synchronous generator cooling air duct according to claim 1, it is characterized in that: described air gap cooling air duct is to be made of the axial air-gap passage that is provided with between stator, the rotor, and crosses with rotor wind path and stator wind path and to enter main generator return air district.

9, high capacity synchronous generator cooling air duct according to claim 1 is characterized in that: the air intake district of described main generator is made of the re-entrant portion that forms between the reinforcement dividing plate of the box support left and right sides that is closed and the stator end plate.

10, high capacity synchronous generator cooling air duct according to claim 1 is characterized in that: described exciter wind path be by the setting of exciter case top be communicated with main generator cooling air duct air intake district advance, the gap forms between return air duct and excitation generator two ends and the exciter housing advances, the air gap channel of return air district and excitation generator constitutes.

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