CN110233035B - Automatic conveying belt structure for reactor insulation curing process and use method thereof - Google Patents
Automatic conveying belt structure for reactor insulation curing process and use method thereof Download PDFInfo
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- CN110233035B CN110233035B CN201910689409.1A CN201910689409A CN110233035B CN 110233035 B CN110233035 B CN 110233035B CN 201910689409 A CN201910689409 A CN 201910689409A CN 110233035 B CN110233035 B CN 110233035B
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- 238000000034 method Methods 0.000 title claims abstract description 47
- 238000009413 insulation Methods 0.000 title claims abstract description 10
- 239000003973 paint Substances 0.000 claims abstract description 53
- 238000007598 dipping method Methods 0.000 claims abstract description 48
- 238000001816 cooling Methods 0.000 claims abstract description 37
- 238000001035 drying Methods 0.000 claims abstract description 36
- 239000011347 resin Substances 0.000 claims abstract description 6
- 229920005989 resin Polymers 0.000 claims abstract description 6
- 238000007599 discharging Methods 0.000 claims description 5
- 238000005086 pumping Methods 0.000 claims description 3
- 230000014759 maintenance of location Effects 0.000 claims 1
- 230000005540 biological transmission Effects 0.000 description 6
- 230000002950 deficient Effects 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 239000002904 solvent Substances 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000003618 dip coating Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 239000004922 lacquer Substances 0.000 description 1
- 239000000463 material Substances 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000010422 painting Methods 0.000 description 1
- 238000005507 spraying Methods 0.000 description 1
- 230000007306 turnover Effects 0.000 description 1
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F41/00—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F41/00—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
- H01F41/005—Impregnating or encapsulating
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- Engineering & Computer Science (AREA)
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- Manufacturing & Machinery (AREA)
- Coating Apparatus (AREA)
- Application Of Or Painting With Fluid Materials (AREA)
Abstract
The invention relates to an automatic conveyor belt structure for an insulation curing process of a reactor and a using method thereof, and the automatic conveyor belt structure comprises a negative-pressure paint dipping chamber (B), a draining chamber (C), a drying chamber (D) and a cooling chamber (E) which are sequentially connected from front to back, wherein a PLC central control console (A) is also arranged above the negative-pressure paint dipping chamber (B), the draining chamber (C), the drying chamber (D) and the cooling chamber (E); an operator in the PLC center console operates the feeding manipulator, a hanging basket with the reactor is placed in the negative-pressure paint dipping chamber, negative pressure is pumped in the negative-pressure paint dipping chamber through the vacuum pump to remove moisture and air in the reactor, and then the PLC center console starts the first conveying belt to convey the reactor into the resin container for paint dipping.
Description
Technical Field
The invention relates to the technical field of insulating paint curing processes for reactors, in particular to an automatic conveyor belt structure for the insulating curing processes of reactors and a using method thereof.
Background
The automation degree of the insulating paint curing process of the reactor directly influences the labor intensity and the safety of operators. The insulating paint curing process in the prior art is open production, multiple persons are often required to participate in manual operation on one production line, the labor intensity is high, the working density is high, the working comfort level is poor, a place where the multiple persons work needs to be provided, defective products caused by manual operation errors of operators are easy to generate, and meanwhile, the field operators are greatly injured by the direct contact of the field operators and the resin solvent, and the safety threat to the field operators is high.
Disclosure of Invention
Aiming at the defects and shortcomings in the prior art, the invention provides an automatic conveyor belt structure for a reactor insulation curing process and a using method thereof.
The technical scheme adopted by the invention for solving the technical problem is as follows:
an automatic conveyor belt structure for an insulation curing process of a reactor comprises a negative-pressure paint dipping chamber, a draining chamber, a drying chamber and a cooling chamber which are sequentially connected from front to back, wherein a PLC central console is further arranged above the negative-pressure paint dipping chamber, the draining chamber, the drying chamber and the cooling chamber;
the method is characterized in that:
a first conveyor belt is arranged above the insides of the negative-pressure paint dipping chamber and the draining chamber;
a second conveyor belt is arranged in the draining chamber;
a third conveyor belt is arranged in the drying chamber;
a fourth conveyor belt is arranged in the cooling chamber;
a fifth conveyor belt is arranged outside the negative-pressure paint dipping chamber, the draining chamber, the drying chamber and the cooling chamber, wherein,
the fifth conveyor belt is positioned above the first conveyor belt, and the second conveyor belt, the third conveyor belt and the fourth conveyor belt are positioned at the same height position and are positioned below the first conveyor belt;
the conveying length of the fifth conveying belt is greater than that of the first conveying belt, and the conveying lengths of the second conveying belt, the third conveying belt and the fourth conveying belt are equal and less than that of the first conveying belt;
the reactor is arranged in the hanging basket and is connected with one end of the first conveyor belt;
the PLC center console is respectively connected with the first conveyor belt, the second conveyor belt, the third conveyor belt, the fourth conveyor belt and the fifth conveyor belt to realize the starting, stopping and conveying speed control of the first conveyor belt, the second conveyor belt, the third conveyor belt, the fourth conveyor belt and the fifth conveyor belt.
Further, a hook device is arranged at the right end of the fifth conveying belt.
Further, the reactor sequentially passes through a negative-pressure paint dipping chamber, a draining chamber, a drying chamber and a cooling chamber in a manner of being located in the hanging basket.
Further, the bottom of the hanging basket is provided with a positioning bulge to ensure that the reactor is stably positioned in the hanging basket.
Further, the total time of the reactor passing through the negative-pressure paint dipping chamber, the draining chamber, the drying chamber and the cooling chamber in sequence is 20 hours, and the residence time ratio of the reactor in the negative-pressure paint dipping chamber, the draining chamber, the drying chamber and the cooling chamber is tB: tC: tD: tE =1:1:2: 1.
Further, the total time of taking, placing, standing and conveying the reactor in the hanging basket and on the fifth conveying belt is 4 hours.
Furthermore, a feeding manipulator is arranged at the left end of the first conveying belt, and a discharging manipulator is arranged at the left end of the fifth conveying belt.
Further, the invention also provides a use method of the automatic conveyor belt structure for the reactor insulation curing process, which is characterized in that: the method comprises the following steps:
1) an operator in the PLC center console operates a feeding manipulator, a hanging basket provided with a reactor is placed in a negative pressure paint dipping chamber, a vacuum pump is used for pumping negative pressure in the negative pressure paint dipping chamber to remove moisture and air in the reactor, and then the PLC center console starts a first conveyor belt to convey the reactor into a resin container for paint dipping;
2) after the paint dipping procedure is completed, a PLC central console starts a first conveyor belt to move the reactor to a second conveyor belt in the draining chamber, and the PLC central console starts the second conveyor belt to move a hanging basket with the reactor to the middle position of the draining chamber, so as to perform the draining procedure on the reactor;
3) after the draining process is finished, a second conveyor belt is started through a PLC central console to move the reactor to a third conveyor belt in the drying chamber, the third conveyor belt is started through the PLC central console to place a hanging basket provided with the reactor at the middle position of the drying chamber, and the reactor is dried;
4) after the drying process is finished, a third conveyor belt is started through a PLC center console to move the reactor to a fourth conveyor belt in the cooling chamber, the fourth conveyor belt is started through the PLC center console to move the hanging basket with the reactor to the middle position of the cooling chamber, and the reactor is cooled;
5) and starting a lifting hook device arranged at the right end of the fifth conveyor belt through the PLC center console to lift the hanging basket with the reactor in the cooling chamber onto the fifth conveyor belt, conveying the hanging basket to the left end of the fifth conveyor belt through the fifth conveyor belt, and operating the discharging manipulator by an operator in the PLC center console to take out the hanging basket on the fifth conveyor belt.
Further, the conveying speeds of the second conveyor belt, the third conveyor belt and the fourth conveyor belt after being started are equal.
Further, the starting transmission speed of the first conveyor belt is higher than the starting transmission speeds of the second conveyor belt, the third conveyor belt and the fourth conveyor belt, and the starting transmission speed of the first conveyor belt is lower than the starting transmission speed of the fifth conveyor belt.
The invention has the beneficial effects that:
(1) the full-automatic paint dipping process is adopted, each conveyor belt is respectively controlled by the PLC central console to sequentially convey hanging baskets provided with reactors from a negative-pressure paint dipping chamber, a draining chamber, a drying chamber to a cooling chamber, manual contact with resin and workpieces used for paint dipping is effectively avoided, only workpieces with completely volatilized solvents and workpieces without paint dipping are treated after paint dipping is finished and cooling, the positions of the operator console in the PLC are only kept while high efficiency and stability and low defective rate are ensured, and therefore operation safety of the operator is guaranteed as far as possible.
(2) Through from last fifth conveyer belt, first conveyer belt and second conveyer belt, third conveyer belt, fourth conveyer belt of having set gradually extremely down to effectively realize the material loading of reactor, soak the lacquer, the unloading process separates mutually, avoids mutual interference and the influence that the reactor is located the conveying position of same height probably brought, effectively reduces the holistic space of arranging of this automatic conveyer belt through reciprocating arrangement simultaneously.
(3) The conveying length through specifically setting up the fifth conveyer belt is greater than the conveying length of first conveyer belt, the second conveyer belt, the third conveyer belt, and the conveying length of fourth conveyer belt equals and is less than the conveying length of first conveyer belt, thereby realize through the relatively longer first conveyer belt that the transmission of reactor in negative pressure dip coating and draining process is stable, and with the second conveyer belt, the third conveyer belt, and the conveying length of fourth conveyer belt equals and sets up to be the shortest in order to adapt to the conveying of relatively stable reactor between the draining, drying, and cooling process, and realize reciprocating the arranging with the fifth conveyer belt then can effectively reduce the holistic space of arranging of this automatic conveyer belt.
Drawings
The invention is further illustrated with reference to the following figures and examples.
Fig. 1 is a schematic structural diagram of an automatic conveyor belt structure for a reactor insulation curing process according to the invention.
Detailed Description
The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.
As shown in fig. 1, an automatic conveyor belt structure for a reactor insulation curing process comprises a negative pressure paint dipping chamber B, a draining chamber C, a drying chamber D and a cooling chamber E which are sequentially connected from front to back, wherein a PLC center console a is further arranged above the negative pressure paint dipping chamber B, the draining chamber C, the drying chamber D and the cooling chamber E;
a first conveyor belt 1 is arranged above the insides of the negative-pressure paint dipping chamber B and the draining chamber C;
a second conveyor belt 2 is arranged in the draining chamber C;
a third conveyor belt 3 is arranged inside the drying chamber D;
a fourth conveyor belt 4 is arranged inside the cooling chamber E;
a fifth conveyor belt 5 is arranged outside the negative pressure paint dipping chamber B, the draining chamber C, the drying chamber D and the cooling chamber E, wherein,
the fifth conveyor belt 5 is positioned above the first conveyor belt 1, and the second conveyor belt 2, the third conveyor belt 3 and the fourth conveyor belt 4 are positioned at the same height position and below the first conveyor belt 1; the fifth conveyor belt, the first conveyor belt, the second conveyor belt, the third conveyor belt and the fourth conveyor belt are sequentially arranged from top to bottom, so that the reactor is effectively separated in the processes of feeding, paint dipping and blanking, mutual interference and influence possibly caused by the fact that the reactor is located at the same height at the conveying position are avoided, and meanwhile, the arrangement space of the whole automatic conveyor belt is effectively reduced through reciprocating arrangement;
the conveying length of the fifth conveyor belt 5 is longer than that of the first conveyor belt 1, and the conveying lengths of the second conveyor belt 2, the third conveyor belt 3 and the fourth conveyor belt 4 are equal and shorter than that of the first conveyor belt 1; the conveying length of the fifth conveying belt is set to be greater than that of the first conveying belt, the conveying lengths of the second conveying belt, the third conveying belt and the fourth conveying belt are equal to each other and are smaller than that of the first conveying belt, so that the stable transmission of the reactor in the negative-pressure paint dipping and draining processes is realized through the relatively long first conveying belt, the conveying lengths of the second conveying belt, the third conveying belt and the fourth conveying belt are equal to each other and are set to be shortest to adapt to the conveying of the relatively stable reactor among the draining, drying and cooling processes, and the reciprocating arrangement of the fifth conveying belt can effectively reduce the overall arrangement space of the automatic conveying belt;
the reactor 7 is arranged in the hanging basket 6 and is connected with one end of the first conveyor belt 1, so that the hanging basket 6 is lifted and conveyed when the first conveyor belt 1 is started;
the PLC center console A is respectively connected with the first conveyor belt 1, the second conveyor belt 2, the third conveyor belt 3, the fourth conveyor belt 4 and the fifth conveyor belt 5 to realize the control of the starting, stopping and conveying speeds of the first conveyor belt 1, the second conveyor belt 2, the third conveyor belt 3, the fourth conveyor belt 4 and the fifth conveyor belt 5, so that the starting, stopping and conveying speed control of each conveyor belt is reasonably controlled according to different actual needs.
Specifically, the right end of the fifth conveyor belt 5 is provided with a hook device 5-1, so that the hanging basket 6 is hung up from the fourth conveyor belt 4 and transferred onto the fifth conveyor belt 5 by the hook device 5-1.
Specifically, the reactor 7 sequentially passes through the negative-pressure paint dipping chamber B, the draining chamber C, the drying chamber D and the cooling chamber E in a manner of being located in the basket 6, so that the paint dipping operation of the plurality of reactors at a time is realized, and the surface which is not painted is subjected to the subsequent turn-over and paint re-painting treatment to realize the overall paint spraying operation of the reactor 7.
Specifically, the bottom of the hanging basket 6 is provided with a positioning bulge to ensure stable positioning of the reactor 7 inside the hanging basket 6, so as to ensure stable positioning effect of the reactor 7 in the conveying process.
Specifically, the total time of the reactor passing through the negative-pressure paint dipping chamber B, the draining chamber C, the drying chamber D and the cooling chamber E in sequence is 20 hours, and the residence time ratio of the reactor in the negative-pressure paint dipping chamber B, the draining chamber C, the drying chamber D and the cooling chamber E is tB: tC: tD: tE =1:1:2:1, so that the complete process treatment of the reactor in each chamber is ensured through reasonable time distribution.
Specifically, the total time for taking, placing, standing and conveying the parts by the reactor 7 in the basket 6 on the fifth conveyor belt 5 is 4 hours, so that enough time is provided for taking and placing the parts to ensure that the process is complete.
Specifically, a feeding manipulator is arranged at the left end of the first conveyor belt 1, a discharging manipulator is arranged at the left end of the fifth conveyor belt 5, and the reactor 7 is grabbed and positioned accurately through the feeding manipulator and the discharging manipulator.
Specifically, the invention also provides a use method of the automatic conveyor belt structure for the reactor insulation curing process, which is characterized in that: the method comprises the following steps:
1) an operator in the PLC center console A operates a feeding manipulator, a hanging basket 6 provided with a reactor 7 is placed in a negative-pressure paint dipping chamber B, a vacuum pump is used for pumping negative pressure in the negative-pressure paint dipping chamber B to remove moisture and air in the reactor 7, and then the PLC center console A starts a first conveyor belt 1 to convey the reactor 7 into a resin container for paint dipping;
2) after the paint dipping procedure is completed, the PLC central console A starts the first conveyor belt 1 to move the reactor 7 to the second conveyor belt 2 in the draining chamber C, the PLC central console A starts the second conveyor belt 2 to move the hanging basket 6 provided with the reactor 7 to the middle position of the draining chamber C, and the reactor 7 is drained;
3) after the draining process is finished, the second conveyor belt 2 is started through the PLC center console A, the reactor 7 is moved to the third conveyor belt 3 in the drying chamber D, the third conveyor belt 3 is started through the PLC center console A, the hanging basket 6 with the reactor 7 is placed in the middle of the drying chamber D, and the reactor 7 is dried;
4) after the drying process is finished, the third conveyor belt 3 is started through the PLC center console A, the reactor 7 is moved to the fourth conveyor belt 4 in the cooling chamber E, the fourth conveyor belt 4 is started through the PLC center console A, the hanging basket 6 with the reactor 7 is moved to the middle position of the cooling chamber E, and the reactor 7 is cooled;
5) and starting a lifting hook device 5-1 arranged at the right end of the fifth conveyor belt 5 through the PLC central console A to lift a hanging basket 6 provided with a reactor 7 in the cooling chamber E onto the fifth conveyor belt 5, conveying the hanging basket 6 to the left end of the fifth conveyor belt 5 through the fifth conveyor belt 5, and operating an unloading manipulator by an operator in the PLC central console A to take out the hanging basket 6 on the fifth conveyor belt 5.
Specifically, the conveying speeds of the second conveyor belt 2, the third conveyor belt 3, and the fourth conveyor belt 4 after starting are equal, so that the reactor 7 can be stably conveyed in the draining chamber C, the drying chamber D, and the cooling chamber E.
Specifically, the conveying speed of the first conveyor belt 1 after being started is greater than the conveying speed of the second conveyor belt 2, the third conveyor belt 3 and the fourth conveyor belt 4 after being started, and the conveying speed of the first conveyor belt 1 after being started is less than the conveying speed of the fifth conveyor belt 5 after being started, so that the reactor 7 is conveyed on the fifth conveyor belt 5 with the longest length at the relatively highest conveying speed, the lifting, paint dipping and draining operations of the reactor 7 are realized at the relatively higher speed, and the paint dipping and draining processes are effectively and stably completed.
In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.
Claims (1)
1. A use method of an automatic conveyor belt structure for a reactor insulation curing process is characterized in that: the automatic conveyor belt comprises a negative-pressure paint dipping chamber (B), a draining chamber (C), a drying chamber (D) and a cooling chamber (E) which are sequentially connected from front to back, wherein a PLC central console (A) is also arranged above the negative-pressure paint dipping chamber (B), the draining chamber (C), the drying chamber (D) and the cooling chamber (E);
the method is characterized in that:
a first conveyor belt (1) is arranged above the inner parts of the negative-pressure paint dipping chamber (B) and the draining chamber (C);
a second conveyor belt (2) is arranged in the draining chamber (C);
a third conveyor belt (3) is arranged inside the drying chamber (D);
a fourth conveyor belt (4) is arranged in the cooling chamber (E);
a fifth conveyor belt (5) is arranged at the outer sides of the negative pressure paint dipping chamber (B), the draining chamber (C), the drying chamber (D) and the cooling chamber (E), and in addition,
the fifth conveyor belt (5) is positioned above the first conveyor belt (1), and the second conveyor belt (2), the third conveyor belt (3) and the fourth conveyor belt (4) are positioned at the same height position and below the first conveyor belt (1);
the conveying length of the fifth conveying belt (5) is greater than that of the first conveying belt (1), and the conveying lengths of the second conveying belt (2), the third conveying belt (3) and the fourth conveying belt (4) are equal and less than that of the first conveying belt (1);
the reactor (7) is arranged in the hanging basket (6) and is connected with one end of the first conveyor belt (1);
the PLC center console (A) is respectively connected with the first conveyor belt (1), the second conveyor belt (2), the third conveyor belt (3), the fourth conveyor belt (4) and the fifth conveyor belt (5) to realize starting, stopping and conveying speed control of the first conveyor belt (1), the second conveyor belt (2), the third conveyor belt (3), the fourth conveyor belt (4) and the fifth conveyor belt (5);
a hook device (5-1) is arranged at the right end of the fifth conveyor belt (5);
the reactor (7) sequentially passes through a negative-pressure paint dipping chamber (B), a draining chamber (C), a drying chamber (D) and a cooling chamber (E) in a manner of being positioned in the hanging basket (6);
a positioning bulge is arranged at the bottom of the hanging basket (6) to ensure that the reactor (7) is stably positioned in the hanging basket (6);
the reactor sequentially passes through a negative-pressure paint dipping chamber (B), a draining chamber (C), a drying chamber (D) and a cooling chamber (E) for 20 hours, and the retention time ratio of the reactor in the negative-pressure paint dipping chamber (B), the draining chamber (C), the drying chamber (D) and the cooling chamber (E) is tB: tC: tD: tE =1:1:2: 1;
the reactor (7) is arranged in the hanging basket (6) and positioned on the fifth conveyor belt (5), and the total time of taking, placing, standing and conveying is 4 hours;
a feeding manipulator is arranged at the left end of the first conveyor belt (1), a discharging manipulator is arranged at the left end of the fifth conveyor belt (5), and the using method comprises the following steps:
1) an operator in the PLC center console (A) operates a feeding manipulator, a hanging basket (6) provided with a reactor (7) is placed in a negative-pressure paint dipping chamber (B), a vacuum pump is used for pumping negative pressure in the negative-pressure paint dipping chamber (B) so as to remove moisture and air in the reactor (7), and then a first conveyor belt (1) is started through the PLC center console (A) to convey the reactor (7) into a resin container for a paint dipping process;
2) after the paint dipping procedure is finished, a PLC central console (A) is used for starting a first conveyor belt (1) to move the reactor (7) to a second conveyor belt (2) in a draining chamber (C), the PLC central console (A) is used for starting the second conveyor belt (2) to move a hanging basket (6) provided with the reactor (7) to the middle position of the draining chamber (C), and the reactor (7) is subjected to a draining procedure;
3) after the draining process is finished, the second conveyor belt (2) is started through the PLC central console (A), the reactor (7) is moved to the third conveyor belt (3) in the drying chamber (D), the third conveyor belt (3) is started through the PLC central console (A), the hanging basket (6) provided with the reactor (7) is placed in the middle of the drying chamber (D), and the reactor (7) is dried;
4) after the drying process is finished, a third conveyor belt (3) is started through a PLC central console (A) to move the reactor (7) to a fourth conveyor belt (4) in a cooling chamber (E), the fourth conveyor belt (4) is started through the PLC central console (A) to move a hanging basket (6) provided with the reactor (7) to the middle position of the cooling chamber (E), and the reactor (7) is cooled;
5) a lifting hook device (5-1) arranged at the right end of a fifth conveyor belt (5) is started through a PLC central console (A) to lift a hanging basket (6) provided with a reactor (7) in a cooling chamber (E) onto the fifth conveyor belt (5), the hanging basket (6) is conveyed to the left end of the fifth conveyor belt (5) through the fifth conveyor belt (5), and an operator in the PLC central console (A) operates a blanking manipulator to take out the hanging basket (6) on the fifth conveyor belt (5);
the conveying speeds of the second conveyor belt (2), the third conveyor belt (3) and the fourth conveyor belt (4) after being started are equal;
the conveying speed of the first conveying belt (1) after being started is larger than the conveying speeds of the second conveying belt (2), the third conveying belt (3) and the fourth conveying belt (4) after being started, and the conveying speed of the first conveying belt (1) after being started is smaller than the conveying speed of the fifth conveying belt (5) after being started.
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CN204892273U (en) * | 2015-09-06 | 2015-12-23 | 江西中铸科技股份有限公司 | But lacquer assembly line is covered in circulation of foundry goods of rapid draing |
CN107895647A (en) * | 2017-12-04 | 2018-04-10 | 陕西驰诺电子科技有限公司 | A kind of vacuum paint dipping method of differential transformer linear movement pick-up |
CN108565113A (en) * | 2018-01-03 | 2018-09-21 | 常州市南方电器元件厂有限公司 | A kind of fixed inductance coil noise reducing technique |
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CN2829907Y (en) * | 2005-08-03 | 2006-10-25 | 中山市大洋电机有限公司 | High efficiency insulation paint dipping appts |
CN101244414A (en) * | 2008-03-07 | 2008-08-20 | 范名业 | Full-automatic dipping lacquer drying stove |
US8575796B1 (en) * | 2010-02-26 | 2013-11-05 | Dayton-Phoenix Group, Inc. | Heavy duty stator core and coil assembly |
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Denomination of invention: An automatic conveyor belt structure and its usage method for insulation solidification process of reactors Granted publication date: 20211001 Pledgee: Bank of China Limited Dingmaoqiao Branch, Zhenjiang Pledgor: JIANGSU SONERGY ELECTRONICS TECHNOLOGY CO.,LTD. Registration number: Y2024980001452 |
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