CN204144025U - Water cooling reactor assembly - Google Patents

Abstract

The utility model provides a kind of water cooling reactor assembly, it is characterized in that, comprise the first water cooling reactor and the second water cooling reactor that are arranged side by side, the first described water cooling reactor comprises the first iron core, the first winding is provided with outside first iron core, the first water cooling tube and the second water cooling tube is provided with between first iron core and the first winding, the second described water cooling reactor comprises the second iron core, the second winding is provided with outside second iron core, the 3rd water cooling tube and the 4th water cooling tube is provided with between second iron core and the second winding, the downside of the first water cooling reactor and the second water cooling reactor is provided with positioning support frame plate, the downside of positioning support frame plate is provided with the first Inlet and outlet water water knockout drum, second Inlet and outlet water water knockout drum, first conversion water knockout drum and the second conversion water knockout drum, 3rd water cooling tube is connected the first conversion water knockout drum with the delivery port of the 4th water cooling tube.The utility model reduces space occupancy rate, decreases crushing, increases discharge, and then gives full play to its thermolysis, and then improves the efficiency of electricity generation system.

Description

Water cooling reactor assembly

Technical field

The utility model relates to a kind of water cooling reactor, especially a kind of reactor of water cooling method.The utility model belongs to reactor design field, in wind power generation drive system.

Background technology

Along with development and the application of wind generating technology, to the efficiency of wind power generation and the requirement of the quality of power supply more and more higher, the accessory of interior of equipment cabinet becomes undoubtedly pays close attention to object.For example, double-fed blower fan is increasing day by day for the demand of full power convertor.As shown in Figure 3, for traditional water cooling reactor structural representation, described traditional water cooling reactor comprises iron core 41, winding 42, lead-in line row 43, outlet row 44, reactor water pipe 45, water inlet 46, delivery port 47, water knockout drum 48, locating support 49 and water-cooling module 50.Winding 42 is located at outside iron core 41, iron core 41 connects lead-in line row 43 and outlet row 44 respectively, is provided with locating support 49 on the downside of iron core 41, is provided with water-cooling module 50 between iron core 41 and winding 42, water-cooling module 50 comprises reactor water pipe 45, and reactor water pipe 45 connects water knockout drum 48.When for meeting Large Copacity current transformer, be connected in parallel with regard to the water cooling reactor needing multiple stage such.So, interior of equipment cabinet can be caused crowded, the inconvenience that overlap joint row uses, even cause interference, lead to even more serious consequence.The utility model, by the radiating mode of two reactor commons water system, saves cabinet space, improves electric power quality.

Utility model content

The purpose of this utility model is to provide a kind of water cooling reactor assembly taken up room in less wind generator system.

In order to achieve the above object, the utility model provides a kind of water cooling reactor assembly, it is characterized in that, comprise the first water cooling reactor and the second water cooling reactor that are arranged side by side, the first described water cooling reactor comprises the first iron core, the first winding is provided with outside first iron core, the first water cooling tube and the second water cooling tube is provided with between first iron core and the first winding, the second described water cooling reactor comprises the second iron core, the second winding is provided with outside second iron core, the 3rd water cooling tube and the 4th water cooling tube is provided with between second iron core and the second winding, the downside of the first water cooling reactor and the second water cooling reactor is provided with positioning support frame plate, the downside of positioning support frame plate is provided with the first Inlet and outlet water water knockout drum, second Inlet and outlet water water knockout drum, first conversion water knockout drum and the second conversion water knockout drum, first water cooling tube is connected the first Inlet and outlet water water knockout drum with the water inlet of the second water cooling tube, first water cooling tube is connected the second Inlet and outlet water water knockout drum with the delivery port of the second water cooling tube, 3rd water cooling tube is connected the second conversion water knockout drum with the water inlet of the 4th water cooling tube, 3rd water cooling tube is connected the first conversion water knockout drum with the delivery port of the 4th water cooling tube, first Inlet and outlet water water knockout drum connects the second conversion water knockout drum through the first bend pipe, second Inlet and outlet water water knockout drum connects the first conversion water knockout drum through the second bend pipe, first bend pipe and the second bend pipe arranged in a crossed manner in the downside of positioning support frame plate.

Preferably, the first described water cooling reactor and the parallel connection of the second water cooling reactor.

More preferably, the two ends of the first described winding connect first respectively and to start copper bar and the first ending copper bar, the two ends of the second described winding connect second respectively and to start copper bar and the second ending copper bar, first wiring place of starting copper bar and the first ending copper bar is all positioned at the upside of the first winding, second wiring place of starting copper bar and the second ending copper bar is all positioned at the upside of the second winding, and the first copper bar and second copper bar of starting of starting is connected by the copper bar that overlaps in parallel.

Preferably, the first described water cooling tube, the second water cooling tube, the 3rd water cooling tube and the 4th water cooling tube all comprise the multiple U-shaped stainless steel hard tubes be connected successively.

Preferably, the first described bend pipe and the second bend pipe are stainless steel hard tube.

Preferably, described positioning support frame plate is fixed on the downside of the first iron core and the second iron core.

Preferably, the first described Inlet and outlet water water knockout drum and the second Inlet and outlet water water knockout drum lay respectively at the same side of the first iron core and the second iron core.

Compared with prior art, the beneficial effects of the utility model are:

1, the water cooling reactor assembly of the present utility model logical water cooling reactor of two Daeporis, by the water knockout drum that four idiotypes are less, realize the water cooling reactor that two share a water system, shorten whole water system water route, decrease number of times and the length of bend pipe, thus reduce space occupancy rate.System like this, greatly reduces crushing, increases discharge, and then gives full play to its thermolysis, and then improves the efficiency of electricity generation system.When ensureing that overall volume is constant, the utility model two reactors combine the electric current born and obviously increase, and can meet the powerful electrical network demand of big current.

2, the first bend pipe of the present utility model and the second bend pipe form X-shaped intersection water route, and not only space occupancy is little, also saves the length of tube needed for water circuit system, the prior pressure loss being the reduction of reactance.

3, the utility model is because adopt stainless steel hard tube as water route, so attractive appearance, and compact conformation.

Accompanying drawing explanation

Fig. 1 is water cooling reactor modular construction schematic diagram;

Fig. 2 is water knockout drum of the present utility model and plumbing diagram;

Fig. 3 is traditional water cooling reactor structural representation.

Embodiment

Below in conjunction with drawings and Examples, the utility model is described in further detail.

Embodiment

As shown in Figure 1, for water cooling reactor modular construction schematic diagram, described water cooling reactor assembly comprises the first water cooling reactor and the second water cooling reactor that are arranged side by side, the first described water cooling reactor comprises the first iron core 2, the first winding 1 is provided with outside first iron core 2, the first water cooling tube 4 and the second water cooling tube 13 is provided with between first iron core 2 and the first winding 1, the second described water cooling reactor comprises the second iron core 10, the second winding 12 is provided with outside second iron core 10, the 3rd water cooling tube 14 and the 4th water cooling tube 15 is provided with between second iron core 10 and the second winding 12, the first described water cooling tube 4, second water cooling tube 13, 3rd water cooling tube 14 and the 4th water cooling tube 15 all comprise three the U-shaped stainless steel hard tubes be connected successively.The first described bend pipe 28 and the second bend pipe 24 are stainless steel hard tube.The downside of the first water cooling reactor and the second water cooling reactor is provided with positioning support frame plate 25, described positioning support frame plate 25 is fixed on the downside of the first iron core 2 and the second iron core 10, the first described Inlet and outlet water water knockout drum 22 and the second Inlet and outlet water water knockout drum 30 lay respectively at the left side of the first iron core 2 and the second iron core 10, and the first conversion water knockout drum 27 and the second conversion water knockout drum 29 lay respectively at the right side of the first iron core 2 and the second iron core 10.The downside of positioning support frame plate 25 is provided with the first Inlet and outlet water water knockout drum 22, second Inlet and outlet water water knockout drum 30, first conversion water knockout drum 27 and the second conversion water knockout drum 29, first water cooling tube 4 is connected the first Inlet and outlet water water knockout drum 22 with the water inlet of the second water cooling tube 13 through hard tube water swivel 7, first water cooling tube 4 is connected the second Inlet and outlet water water knockout drum 30 with the delivery port of the second water cooling tube 13 through hard tube water swivel 7, 3rd water cooling tube 14 is connected the second conversion water knockout drum 29 with the water inlet of the 4th water cooling tube 15 through hard tube water swivel 7, 3rd water cooling tube 14 is connected the first conversion water knockout drum 27 with the delivery port of the 4th water cooling tube 15 through hard tube water swivel 7, first Inlet and outlet water water knockout drum 22 connects the second conversion water knockout drum 29 through the first bend pipe 28, second Inlet and outlet water water knockout drum 30 connects the first conversion water knockout drum 27 through the second bend pipe 24, first bend pipe 28 and the second bend pipe 24 arranged in a crossed manner in the downside of positioning support frame plate 25, define the intersection water route of X-shaped.Waterway structure like this is compact, and discharge is large, and water supply and drainage is easily smooth, reduces the fatigue loads on flexible wind power system driving-chain, and then reaches the effect of cost efficiency.The downside of positioning support frame plate 25 is also provided with the support 26 supporting reactor.

The first described water cooling reactor and the parallel connection of the second water cooling reactor.The two ends of the first described winding connect first respectively and to start copper bar and the first ending copper bar 3, the two ends of the second described winding connect second respectively and to start copper bar and the second ending copper bar 11, first wiring place of starting copper bar and the first ending copper bar 3 is all positioned at the upside of the first winding 1, second wiring place of starting copper bar and the second ending copper bar 11 is all positioned at the upside of the second winding 12, and the first copper bar and second copper bar of starting of starting is connected by overlap joint copper bar 9 in parallel.2 small area analysis are merged into a larger current by overlap joint copper bar 9 in parallel.

During use, the flow route of the first water cooling reactor is for intake from the first Inlet and outlet water water knockout drum 22, respectively after the first water cooling tube 4, second water cooling tube 13, from the second Inlet and outlet water water knockout drum 30 water outlet, the flow route of the second water cooling reactor is for intake from the first Inlet and outlet water water knockout drum 22, flow through the second conversion water knockout drum 29, then after flowing through the 3rd water cooling tube 14 and the 4th water cooling tube 15 respectively, through the first conversion water knockout drum 27 from the second Inlet and outlet water water knockout drum 30 water outlet.

The utility model relates to a kind of water cooling reactor, in wind generator system, adopts the frame mode in hard tube intersection water route to reduce the temperature rise of reactor, and then is better that wind generator system improves wind energy conversion efficiency, improve electric power quality.

Claims (7)

1. a water cooling reactor assembly, it is characterized in that, comprise the first water cooling reactor and the second water cooling reactor that are arranged side by side, the first described water cooling reactor comprises the first iron core (2), first iron core (2) outside is provided with the first winding (1), the first water cooling tube (4) and the second water cooling tube (13) is provided with between first iron core (2) and the first winding (1), the second described water cooling reactor comprises the second iron core (10), second iron core (10) outside is provided with the second winding (12), the 3rd water cooling tube (14) and the 4th water cooling tube (15) is provided with between second iron core (10) and the second winding (12), the downside of the first water cooling reactor and the second water cooling reactor is provided with positioning support frame plate (25), the downside of positioning support frame plate (25) is provided with the first Inlet and outlet water water knockout drum (22), second Inlet and outlet water water knockout drum (30), first conversion water knockout drum (27) and the second conversion water knockout drum (29), first water cooling tube (4) is connected the first Inlet and outlet water water knockout drum (22) with the water inlet of the second water cooling tube (13), first water cooling tube (4) is connected the second Inlet and outlet water water knockout drum (30) with the delivery port of the second water cooling tube (13), 3rd water cooling tube (14) is connected the second conversion water knockout drum (29) with the water inlet of the 4th water cooling tube (15), 3rd water cooling tube (14) is connected the first conversion water knockout drum (27) with the delivery port of the 4th water cooling tube (15), first Inlet and outlet water water knockout drum (22) connects the second conversion water knockout drum (29) through the first bend pipe (28), second Inlet and outlet water water knockout drum (30) connects the first conversion water knockout drum (27) through the second bend pipe (24), first bend pipe (28) and the second bend pipe (24) arranged in a crossed manner in the downside of positioning support frame plate (25).

2. water cooling reactor assembly as claimed in claim 1, is characterized in that, the first described water cooling reactor and the parallel connection of the second water cooling reactor.

3. water cooling reactor assembly as claimed in claim 2, it is characterized in that, the two ends of the first described winding connect first respectively and to start copper bar and the first ending copper bar (3), the two ends of the second described winding connect second respectively and to start copper bar and the second ending copper bar (11), first wiring place of starting copper bar and the first ending copper bar (3) is all positioned at the upside of the first winding (1), second wiring place of starting copper bar and the second ending copper bar (11) is all positioned at the upside of the second winding (12), first copper bar and second copper bar of starting of starting is connected by overlap joint copper bar (9) in parallel.

4. water cooling reactor assembly as claimed in claim 1, it is characterized in that, described the first water cooling tube (4), the second water cooling tube (13), the 3rd water cooling tube (14) and the 4th water cooling tube (15) all comprise the multiple U-shaped stainless steel hard tubes be connected successively.

5. water cooling reactor assembly as claimed in claim 1, it is characterized in that, described the first bend pipe (28) and the second bend pipe (24) are stainless steel hard tube.

6. water cooling reactor assembly as claimed in claim 1, it is characterized in that, described positioning support frame plate (25) is fixed on the downside of the first iron core (2) and the second iron core (10).

7. water cooling reactor assembly as claimed in claim 1, it is characterized in that, the first described Inlet and outlet water water knockout drum (22) and the second Inlet and outlet water water knockout drum (30) lay respectively at the same side of the first iron core (2) and the second iron core (10).