CN102945738A - Dual-output negative ion generator framework - Google Patents
Dual-output negative ion generator framework Download PDFInfo
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- CN102945738A CN102945738A CN2012104471993A CN201210447199A CN102945738A CN 102945738 A CN102945738 A CN 102945738A CN 2012104471993 A CN2012104471993 A CN 2012104471993A CN 201210447199 A CN201210447199 A CN 201210447199A CN 102945738 A CN102945738 A CN 102945738A
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- scolding tin
- tin pin
- dividing plate
- winding dividing
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Abstract
The invention relates to a dual-output negative ion generator framework, belonging to the technical field of a high voltage transformer. The dual-output negative ion generator framework comprises an insulating framework body, wherein multiple first secondary winding clapboards are arranged on one side of a first primary winding clapboard; multiple second secondary winding clapboards are arranged on one side of a second primary winding clapboard; a primary winding groove is arranged between the first primary winding clapboard and the second primary winding clapboard; first secondary winding grooves are arranged between the multiple first secondary winding clapboards; and second secondary winding grooves are arranged between the multiple second secondary winding clapboards. The dual-output negative ion generator framework is compact and rational in structure and has good heat dissipation effect; and in addition, the production cost is lowered and the installation size is decreased.
Description
Technical field
The present invention relates to a kind of dual output anion generator skeleton, belong to the high-tension transformer technical field.
Background technology
Along with the progress of society, the people's living standard is in continuous improve.Because day by day be subject to the pollution of environment, people are improved the requirement of ambient air quality in daily life.For this requirement, develop various anion generators.Anion generator is the principle of simulating nature circle lightning, comes the separated oxygen molecule by high voltage, produces negative ions and improves ambient air.The generation of anion generator mesohigh realizes by high-tension transformer.Use at present the anion generator in large area room, can only promote effect by the high voltage transformer more than 2 or 2 for guaranteeing ion generation concentration, this is just so that the product cost increasing.
Summary of the invention
The object of the invention is to overcome above-mentioned weak point, thereby a kind of dual output anion generator skeleton is provided, promote the magnitude of voltage of output by double winding, so that ion generation concentration is improved, reduced production cost, reduced installation volume.
According to technical scheme provided by the invention, dual output anion generator skeleton comprises the insulation framework body, insulation framework body center is provided with the iron core patchhole, insulation framework body middle part is provided with the first armature winding dividing plate and the second armature winding dividing plate, it is characterized in that: a side of the first armature winding dividing plate is provided with a plurality of the first secondary winding dividing plates, and a side of the second armature winding dividing plate is provided with a plurality of second subprime winding dividing plates.Be provided with the armature winding groove between the first armature winding dividing plate and the second armature winding dividing plate.Be provided with the level slot for winding first time between a plurality of the first secondary winding dividing plates, establish the second subprime slot for winding between a plurality of second subprime winding dividing plates.Connect the first scolding tin pin, the second scolding tin pin and the 3rd scolding tin pin on described the first armature winding dividing plate.Connect the 4th scolding tin pin, the 5th scolding tin pin and the 6th scolding tin pin on the second armature winding dividing plate.
Be in outermost upper first a scolding tin pin base that connects in described a plurality of the first secondary winding dividing plate, connect the 7th scolding tin pin, the 8th scolding tin pin and the 9th scolding tin pin on the first scolding tin pin base, the lower end of the 7th scolding tin pin, the 8th scolding tin pin and the 9th scolding tin pin passes the first scolding tin pin base.
Be in outermost upper second a scolding tin pin base that connects in described a plurality of second subprime winding dividing plate, connect the tenth scolding tin pin and the 11 scolding tin pin on the second scolding tin pin base, the lower end of the tenth scolding tin pin and the 11 scolding tin pin passes the second scolding tin pin base.
The junction of described the first armature winding dividing plate and the first scolding tin pin, the second scolding tin pin, the 3rd scolding tin pin is provided with the heat radiation gap, the second armature winding dividing plate and the 4th scolding tin pin, the 5th scolding tin pin, the 6th scolding tin pin junction are provided with the heat radiation gap, the junction of the first scolding tin pin base and the 7th scolding tin pin, the 8th scolding tin pin, the 9th scolding tin pin is provided with the heat radiation gap, and the junction of the second scolding tin pin base and the tenth scolding tin pin, the 11 scolding tin pin is provided with the heat radiation gap.Described a plurality of the first secondary winding dividing plate is provided with the first crossed beam trunking, and a plurality of second subprime winding dividing plates are provided with the second crossed beam trunking.
Described the first secondary winding dividing plate is three.
Described second subprime winding dividing plate is three.
Be in outermost one in described a plurality of the first secondary winding dividing plate and be provided with the first Stress Release post.
Be in outermost one in described a plurality of second subprime winding dividing plate and be provided with the second Stress Release post.
Described the first scolding tin pin, the second scolding tin pin are different with the length of the 3rd scolding tin pin.
Described the 4th scolding tin pin, the 5th scolding tin pin are different with the length of the 6th scolding tin pin.
Described the 7th scolding tin pin, the 8th scolding tin pin are different with the length of the 9th scolding tin pin.
Described the tenth scolding tin pin is different with the length of the 11 scolding tin pin.
Compared with the prior art the present invention has the following advantages:
Compact conformation of the present invention, rationally; Good heat dissipation effect has reduced production cost, has reduced installation volume.
Description of drawings
Fig. 1 is front view of the present invention.
Fig. 2 is vertical view of the present invention.
Fig. 3 is end view of the present invention.
Description of reference numerals: 1-insulation framework body, 2-iron core patchhole, 3-armature winding groove, first level slot for winding of 4-, 5-second subprime slot for winding, 6-the first armature winding dividing plate, 7-the first secondary winding dividing plate, 8-second subprime winding dividing plate, 9-the first scolding tin pin base, 10-the second scolding tin pin base, 11-the first scolding tin pin, 12-the second scolding tin pin, 13-the 3rd scolding tin pin, 14-the 4th scolding tin pin, 15-the 5th scolding tin pin, 16-the 6th scolding tin pin, 17-the 7th scolding tin pin, 18-the 8th scolding tin pin, 19-the 9th scolding tin pin, 20-the tenth scolding tin pin, 21-the 11 scolding tin pin, 22-the first Stress Release post, 23-the second Stress Release post, 24-the second armature winding dividing plate, 25-the first crossed beam trunking, 26-the second crossed beam trunking.
Embodiment
Following the present invention is further described in connection with the embodiment in the accompanying drawing:
Shown in Fig. 1 ~ 3, the present invention mainly comprises insulation framework body 1, and insulation framework body 1 center is provided with iron core patchhole 2.The side that the side that insulation framework body 1 middle part is provided with the first armature winding dividing plate 6 and the second armature winding dividing plate 24, the first armature winding dividing plates 6 is provided with a plurality of the first secondary winding dividing plate 7, the second armature winding dividing plates 24 is provided with a plurality of second subprime winding dividing plates 8.Be provided with armature winding groove 3 between the first armature winding dividing plate 6 and the second armature winding dividing plate 24.Be provided with level slot for winding 4 first time between a plurality of the first secondary winding dividing plates 7, establish second subprime slot for winding 5 between a plurality of second subprime winding dividing plates 8.The first secondary winding dividing plate 7 is three among the embodiment as shown in Figure 1, and second subprime winding dividing plate 8 is three.
Be in outermost one in described a plurality of the first secondary winding dividing plate 7 and be provided with the first Stress Release post 25, be in outermost one in a plurality of second subprime winding dividing plates 8 and be provided with the second Stress Release post 26.The stress that enamelled wire produces because of tension force in the first Stress Release post 25 and the second Stress Release post 26 control coiling processes, for stress plays good release action, allow enamelled wire be in relaxed state, guarantee that the probability of generation broken string in the curable epoxide in rear road is lower, keep higher on-state rate.
Connect the first scolding tin pin 11, the second scolding tin pin 12 and the 3rd scolding tin pin 13 on described the first armature winding dividing plate 6; Connect the 4th scolding tin pin 14, the 5th scolding tin pin 15 and the 6th scolding tin pin 16 on the second armature winding dividing plate 24.Described the first scolding tin pin 11, the second scolding tin pin 12 are different with the length of the 3rd scolding tin pin 13, so that the first scolding tin pin 11, the second scolding tin pin 12 and the 3rd scolding tin pin 13 radiating effect when high temperature scolding tin is better.Described the 4th scolding tin pin 14, the 5th scolding tin pin 15 are different with the length of the 6th scolding tin pin 16, so that the first scolding tin pin 11, the second scolding tin pin 12 and the 3rd scolding tin pin 13 radiating effect when high temperature scolding tin is better.
Be in outermost upper first a scolding tin pin base 9 that connects in described a plurality of the first secondary winding dividing plate 7, connect the 7th scolding tin pin 17, the 8th scolding tin pin 18 and the 9th scolding tin pin 19 on the first scolding tin pin base 9, the lower end of the 7th scolding tin pin 17, the 8th scolding tin pin 18 and the 9th scolding tin pin 19 passes the first scolding tin pin base 9, and radiating effect is strengthened.The 7th scolding tin pin 17, the 8th scolding tin pin 18 are different with the length of the 9th scolding tin pin 19, so that the 7th scolding tin pin 17, the 8th scolding tin pin 18 and the 9th scolding tin pin 19 radiating effect when high temperature scolding tin is better.
Be in outermost upper second a scolding tin pin base 10 that connects in described a plurality of second subprime winding dividing plate 8, connect the tenth scolding tin pin 20 and the 11 scolding tin pin 21 on the second scolding tin pin base 10, the lower end of the tenth scolding tin pin 20 and the 11 scolding tin pin 21 passes the second scolding tin pin base 10, and radiating effect is strengthened.The tenth scolding tin pin 20 is different with the length of the 11 scolding tin pin 21, so that radiating effect is better.
The junction of described the first armature winding dividing plate 6 and the first scolding tin pin 11, the second scolding tin pin 12, the 3rd scolding tin pin 13 is provided with the heat radiation gap, the junction of the second armature winding dividing plate 24 and the 4th scolding tin pin 14, the 5th scolding tin pin 15, the 6th scolding tin pin 16 is provided with the heat radiation gap, the junction of the first scolding tin pin base 9 and the 7th scolding tin pin 17, the 8th scolding tin pin 18, the 9th scolding tin pin 19 is provided with the heat radiation gap, and the junction of the second scolding tin pin base 10 and the tenth scolding tin pin 20, the 11 scolding tin pin 21 is provided with the heat radiation gap.These gaps allow each scolding tin pin when high temperature scolding tin good radiating effect be arranged, and have effectively prevented because the scolding tin pin is heated and causes crooked bad phenomenon.
Described a plurality of the first secondary winding dividing plate 7 is provided with the first crossed beam trunking 25, and a plurality of second subprime winding dividing plates 8 are provided with the second crossed beam trunking 26.
The present invention has improved the quality of product, has reduced production cost.By doublewound export structure, promote the high-voltage value of output so that ion generation concentration is improved, have 2 groups of 1 group of elementary drives secondary, produce 2 groups of high-tension functions simultaneously, in installation volume and manufacturing cost to a certain degree decline is arranged.
Claims (9)
1. dual output anion generator skeleton, comprise insulation framework body (1), insulation framework body (1) center is provided with iron core patchhole (2), insulation framework body (1) middle part is provided with the first armature winding dividing plate (6) and the second armature winding dividing plate (24), it is characterized in that: a side of the first armature winding dividing plate (6) is provided with a plurality of the first secondary winding dividing plates (7), and a side of the second armature winding dividing plate (24) is provided with a plurality of second subprime winding dividing plates (8); Be provided with armature winding groove (3) between the first armature winding dividing plate (6) and the second armature winding dividing plate (24); Be provided with first level slot for winding (4) between a plurality of the first secondary winding dividing plates (7), establish second subprime slot for winding (5) between a plurality of second subprime winding dividing plates (8); Upper the first scolding tin pin (11), the second scolding tin pin (12) and the 3rd scolding tin pin (13) of connecting of described the first armature winding dividing plate (6); Upper the 4th scolding tin pin (14), the 5th scolding tin pin (15) and the 6th scolding tin pin (16) of connecting of the second armature winding dividing plate (24);
Be in outermost upper first a scolding tin pin base (9) that connects in described a plurality of the first secondary winding dividing plate (7), upper the 7th scolding tin pin (17), the 8th scolding tin pin (18) and the 9th scolding tin pin (19) of connecting of the first scolding tin pin base (9), the lower end of the 7th scolding tin pin (17), the 8th scolding tin pin (18) and the 9th scolding tin pin (19) passes the first scolding tin pin base (9):
Be in outermost upper second a scolding tin pin base (10) that connects in described a plurality of second subprime winding dividing plates (8), upper the tenth scolding tin pin (20) and the 11 scolding tin pin (21) of connecting of the second scolding tin pin base (10), the lower end of the tenth scolding tin pin (20) and the 11 scolding tin pin (21) passes the second scolding tin pin base (10);
Described the first armature winding dividing plate (6) and the first scolding tin pin (11), the second scolding tin pin (12), the junction of the 3rd scolding tin pin (13) is provided with the heat radiation gap, the second armature winding dividing plate (24) and the 4th scolding tin pin (14), the 5th scolding tin pin (15), the junction of the 6th scolding tin pin (16) is provided with the heat radiation gap, the first scolding tin pin base (9) and the 7th scolding tin pin (17), the 8th scolding tin pin (18), the junction of the 9th scolding tin pin (19) is provided with heat radiation gap, the second scolding tin pin base (10) and the tenth scolding tin pin (20), the junction of the 11 scolding tin pin (21) is provided with the heat radiation gap; Described a plurality of the first secondary winding dividing plate (7) is provided with the first crossed beam trunking (25), and a plurality of second subprime winding dividing plates (8) are provided with the second crossed beam trunking (26).
2. dual output anion generator skeleton as claimed in claim 1, it is characterized in that: described the first secondary winding dividing plate (7) is three.
3. dual output anion generator skeleton as claimed in claim 1, it is characterized in that: described second subprime winding dividing plate (8) is three.
4. dual output anion generator skeleton as claimed in claim 1 is characterized in that: be in outermost one in described a plurality of the first secondary winding dividing plates (7) and be provided with the first Stress Release post (25).
5. dual output anion generator skeleton as claimed in claim 1 is characterized in that: be in outermost one in described a plurality of second subprime winding dividing plates (8) and be provided with the second Stress Release post (26).
6. dual output anion generator skeleton as claimed in claim 1 is characterized in that: described the first scolding tin pin (11), the second scolding tin pin (12) are different with the length of the 3rd scolding tin pin (13).
7. dual output anion generator skeleton as claimed in claim 1 is characterized in that: described the 4th scolding tin pin (14), the 5th scolding tin pin (15) are different with the length of the 6th scolding tin pin (16).
8. dual output anion generator skeleton as claimed in claim 1 is characterized in that: described the 7th scolding tin pin (17), the 8th scolding tin pin (18) are different with the length of the 9th scolding tin pin (19).
9. dual output anion generator skeleton as claimed in claim 1, it is characterized in that: described the tenth scolding tin pin (20) is different with the length of the 11 scolding tin pin (21).
Priority Applications (1)
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CN201210447199.3A CN102945738B (en) | 2012-11-10 | 2012-11-10 | Dual output anion generator skeleton |
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CN201210447199.3A CN102945738B (en) | 2012-11-10 | 2012-11-10 | Dual output anion generator skeleton |
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CN102945738A true CN102945738A (en) | 2013-02-27 |
CN102945738B CN102945738B (en) | 2015-07-29 |
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CN201210447199.3A Active CN102945738B (en) | 2012-11-10 | 2012-11-10 | Dual output anion generator skeleton |
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Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201196901Y (en) * | 2008-04-30 | 2009-02-18 | 台龙电子股份有限公司 | Winding structure for transformer |
US8242871B2 (en) * | 2009-08-24 | 2012-08-14 | Tdk Corporation | Transformer |
CN202871533U (en) * | 2012-11-10 | 2013-04-10 | 无锡东洋电器有限公司 | Dual output anion generator framework |
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2012
- 2012-11-10 CN CN201210447199.3A patent/CN102945738B/en active Active
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201196901Y (en) * | 2008-04-30 | 2009-02-18 | 台龙电子股份有限公司 | Winding structure for transformer |
US8242871B2 (en) * | 2009-08-24 | 2012-08-14 | Tdk Corporation | Transformer |
CN202871533U (en) * | 2012-11-10 | 2013-04-10 | 无锡东洋电器有限公司 | Dual output anion generator framework |
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CN102945738B (en) | 2015-07-29 |
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