CN216719685U - Multifunctional transformer framework - Google Patents
Multifunctional transformer framework Download PDFInfo
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- CN216719685U CN216719685U CN202122195378.XU CN202122195378U CN216719685U CN 216719685 U CN216719685 U CN 216719685U CN 202122195378 U CN202122195378 U CN 202122195378U CN 216719685 U CN216719685 U CN 216719685U
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Abstract
The utility model relates to the technical field of transformers and discloses a multifunctional transformer framework which comprises a shell, wherein an overheating protection mechanism is movably connected inside the shell and comprises a fixed frame, a transmission component for collecting heat inside the fixed frame and a heat dissipation component for collecting heat for cooling; absorb the heat on transportation mount surface through the copper pipe, the inside that the water-collecting plate was carried through the distilled water to the heat that makes the copper pipe absorb that the pressure plate slides simultaneously, and then realizes the thermal high-efficient absorption in transformer skeleton surface, and the guide plate rotates simultaneously and drives air and condenser pipe and carry out the heat exchange, and then realizes transformer skeleton inside heat balance, guarantees that the transformer is in good running state all the time, improves the operating efficiency of transformer.
Description
Technical Field
The utility model relates to the technical field of transformers, in particular to a multifunctional transformer framework.
Background
The transformer is a device for changing alternating voltage by utilizing the principle of electromagnetic induction, the main components are a primary coil, a secondary coil and an iron core, the transformer is commonly used for voltage lifting, impedance matching, safety isolation and the like in electrical equipment and wireless circuits, wherein a transformer framework is used as an important part for fixing the coil and the iron core, the transformer framework can be used for fixing the magnetic core in the transformer and providing winding space for copper wires in the transformer, wire grooves in the framework provide wire passing paths for production winding wires of the transformer, the conventional transformer framework only can improve the simple installation and fixation function and cannot realize the function of intelligently balancing the heat in the transformer, the heat in the conventional transformer framework can be radiated only through a simple vent, and the mode cannot dynamically and efficiently control the heat in the transformer so as to further reduce the operation efficiency of the transformer framework, meanwhile, the problem of damage caused by overhigh temperature of the transformer can be caused.
Therefore, to these problems, we need a multifunctional transformer framework to solve, the heat on the surface of the fixing frame is absorbed and transported through the copper pipe, and meanwhile, the pressure plate slides to enable the heat absorbed by the copper pipe to be transported to the inside of the water collecting plate through distilled water, so that the heat on the surface of the transformer framework is efficiently absorbed, meanwhile, the guide plate rotates to drive air and the condensation pipe to carry out heat exchange, further, the heat balance inside the transformer framework is realized, the transformer is guaranteed to be always in a good running state, and the running efficiency of the transformer is improved.
SUMMERY OF THE UTILITY MODEL
Aiming at the defects of the prior art, the utility model provides a multifunctional transformer framework which has the advantages of intelligent detection, high-efficiency heat balance, high operation efficiency and prolonged service life, and solves the problems that the existing transformer framework only can improve the simple installation and fixation effect and cannot realize the function of intelligently balancing the heat in the transformer, the heat in the existing transformer framework can only be radiated through a simple vent, and the mode cannot dynamically and efficiently control the heat in the transformer, so that the operation efficiency of the transformer framework is reduced, and the transformer is damaged due to overhigh temperature.
In order to realize the purposes of intelligent detection, efficient heat balance, high operation efficiency and prolonged service life, the utility model provides the following technical scheme: the utility model provides a multi-functional transformer skeleton, includes the shell, the inside swing joint of shell has overheat protection mechanism, and overheat protection mechanism includes the mount, is used for the transmission subassembly that the inside heat of mount was collected, is used for collecting the refrigerated radiator unit of heat, and mount fixed connection is in the inside of shell, and transmission subassembly swing joint is in the inside of shell, and radiator unit swing joint is in the inside of shell.
Preferably, the transmission subassembly includes the copper pipe, copper pipe fixed connection is in the inside of mount, the board is accepted to the inside fixedly connected with of shell, the outside fixedly connected with motor one of accepting the board, the outside fixedly connected with commentaries on classics board of motor one, the outside fixedly connected with bull stick of commentaries on classics board, the outside fixedly connected with water-collecting plate of accepting the board, the inside sliding connection of water-collecting plate has the pressure plate, the outside fixedly connected with telescopic link of pressure plate, the outside fixedly connected with connecting rod of pressure plate, the outside fixedly connected with transmission board of connecting rod, the inboard fixedly connected with inlet tube of water-collecting plate, the inboard swing joint of inlet tube has the baffle, the outside fixedly connected with spring one of baffle.
Preferably, the heat dissipation assembly comprises a second motor, the second motor is fixedly connected to the outside of the bearing plate, the guide plate is fixedly connected to the outside of the second motor, the condensing pipe is fixedly connected to the outside of the bearing plate, the ventilation cover is fixedly connected to the inner side of the shell, and the surface of the shell is provided with a flow opening.
Preferably, the inside swing joint of shell has the detection mechanism to mount temperature perception, and detection mechanism includes the response shell, and response shell fixed connection is in the inside of shell, and collision piece sliding connection is in the inside of response shell, and the outside fixedly connected with spring two of collision piece, the inside fixedly connected with circular telegram contact of response shell.
Preferably, distilled water is added into the copper pipe, the two ends of the copper pipe are respectively and fixedly connected to the outside of the inlet pipe and the outside of the condenser pipe, the rotating rod is corresponding to the position of the transmission plate and is matched with the specification, the pressure plate is connected with the water collection plate in a sliding and sealing mode, the two ends of the telescopic rod are respectively and fixedly connected to the inside of the water collection plate and the outside of the pressure plate, the connecting rod is connected with the water collection plate in a sliding mode, the baffle is corresponding to the position of the inlet pipe and is matched with the specification, the two ends of the spring I are respectively and fixedly connected to the outside of the baffle and the inside of the inlet pipe, the guide plate is corresponding to the position of the condenser pipe and is matched with the specification, the two ends of the condenser pipe are respectively and fixedly connected to the outside of the water collection plate and the outside of the copper pipe, and the flow port is corresponding to the position of the guide plate and is matched with the specification.
Preferably, the position of response shell and mount is corresponding and the specification phase-match, and the position of impact piece and circular telegram contact is corresponding and the specification phase-match, and the both ends of spring two are fixed connection respectively in the inside of response shell and the outside of impact piece, and the enclosure space that forms between response shell, impact piece, the spring two is inside to be added with nitrogen gas.
Preferably, the first motor and the second motor are both electrically connected with the energized contact, the energized contact is triggered, the internal circuit of the energized contact is changed from an open circuit to a closed circuit, and then the first motor and the second motor are energized.
Advantageous effects
1. This multifunctional transformer skeleton absorbs the heat on transportation mount surface through the copper pipe, and the pressure plate slides simultaneously and makes the inside that the water-collecting plate was carried through the distilled water to the heat that the copper pipe absorbed, and then realizes transformer skeleton surface heat's high-efficient absorption, and the guide plate rotates simultaneously and drives the air and carry out the heat exchange with the condenser pipe, and then realizes transformer skeleton inside heat balance, guarantees that the transformer is in good running state all the time, improves the operating efficiency of transformer.
2. This multi-functional transformer skeleton, through the heat that the dynamic perception transformer skeleton of response shell produced, the heat makes the inside nitrogen gas inflation of response shell promote the collision piece and slides simultaneously, and then realizes the radiating time of accurate control transformer skeleton, and then realizes the inside heat of intellectual detection system transformer skeleton, improves transformer practicality and life.
Drawings
FIG. 1 is a schematic view of the present invention with a partial cross-sectional view of the inside thereof;
FIG. 2 is a schematic view of the connecting structure of the overheat protection mechanism according to the present invention;
FIG. 3 is a schematic view of the structure of FIG. 2 at A according to the present invention;
FIG. 4 is a schematic view of the structure of FIG. 2 at B in accordance with the present invention;
FIG. 5 is a schematic view of the structure of FIG. 2 at C in accordance with the present invention;
FIG. 6 is a schematic view of the structure of FIG. 2 of the present invention at D;
FIG. 7 is a schematic view of the connection structure of the detecting mechanism of the present invention.
In the figure: 1. a housing; 2. an overheat protection mechanism; 21. a fixed mount; 22. a transfer assembly; 221. a copper pipe; 222. a bearing plate; 223. a first motor; 224. rotating the plate; 225. a rotating rod; 226. a water collection plate; 227. A pressure plate; 228. a telescopic rod; 229. a connecting rod; 2210. a transfer plate; 2211. an inlet pipe; 2212. A baffle plate; 2213. a first spring; 23. a heat dissipating component; 231. a second motor; 232. a baffle; 233. A condenser tube; 234. a ventilation hood; 235. a flow port; 3. a detection mechanism; 301. an induction housing; 302. a collision mass; 303. a second spring; 304. and energizing the contacts.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The first embodiment is as follows:
referring to fig. 1-6, a multifunctional transformer bobbin includes a housing 1, an overheat protection mechanism 2 movably connected inside the housing 1, the overheat protection mechanism 2 including a fixing frame 21, a transmission component 22 for collecting heat inside the fixing frame 21, and a heat dissipation component 23 for collecting heat and cooling, the fixing frame 21 being fixedly connected inside the housing 1, the transmission component 22 being movably connected inside the housing 1, and the heat dissipation component 23 being movably connected inside the housing 1.
The transmission assembly 22 comprises a copper pipe 221, the copper pipe 221 is fixedly connected inside the fixing frame 21, the inner portion of the housing 1 is fixedly connected with a bearing plate 222, the outer portion of the bearing plate 222 is fixedly connected with a first motor 223, the outer portion of the first motor 223 is fixedly connected with a rotating plate 224, the outer portion of the rotating plate 224 is fixedly connected with a rotating rod 225, the outer portion of the bearing plate 222 is fixedly connected with a water collecting plate 226, the inner portion of the water collecting plate 226 is slidably connected with a pressure plate 227, the outer portion of the pressure plate 227 is fixedly connected with an expansion rod 228, the outer portion of the pressure plate 227 is fixedly connected with a connecting rod 229, the outer portion of the connecting rod 229 is fixedly connected with a transmission plate 2210, the inner side of the water collecting plate 226 is fixedly connected with a water inlet pipe, the inner side of the water inlet pipe is movably connected with a baffle 2212, and the outer portion of the baffle 2212 is fixedly connected with a first spring 2213.
The heat dissipation assembly 23 comprises a second motor 231, the second motor 231 is fixedly connected to the outside of the bearing plate 222, a guide plate 232 is fixedly connected to the outside of the second motor 231, a condensation pipe 233 is fixedly connected to the outside of the bearing plate 222, a ventilation cover 234 is fixedly connected to the inner side of the housing 1, and a flow opening 235 is formed in the surface of the housing 1.
Distilled water is added in the copper pipe 221, two ends of the copper pipe 221 are respectively fixedly connected to the outside of the inlet pipe 2211 and the outside of the condensation pipe 233, the rotating rod 225 corresponds to the position of the transfer plate 2210 and is matched with the specification, the pressure plate 227 is connected with the water collecting plate 226 in a sliding and sealing manner, two ends of the telescopic rod 228 are respectively fixedly connected to the inside of the water collecting plate 226 and the outside of the pressure plate 227, the connecting rod 229 is connected with the water collecting plate 226 in a sliding manner, the baffle 2212 corresponds to the position of the inlet pipe 2211 and is matched with the specification, two ends of the first spring 2213 are respectively fixedly connected to the outside of the baffle 2212 and the inside of the inlet pipe 2211, the guide plate 232 corresponds to the position of the condensation pipe 233 and is matched with the specification, the ventilation cover 234 corresponds to the position of the condensation pipe 233 and is matched with the specification, two ends of the condensation pipe 233 are respectively fixedly connected to the outside of the water collecting plate 226 and the copper pipe 221, and the flow port 235 corresponds to the position of the guide plate 232 and is matched with the specification.
Example two:
referring to fig. 1 and 7, a multifunctional transformer bobbin includes a housing 1, an overheat protection mechanism 2 is movably connected inside the housing 1, the overheat protection mechanism 2 includes a fixing frame 21, a transmission component 22 for collecting heat inside the fixing frame 21, and a heat dissipation component 23 for collecting heat and cooling, the fixing frame 21 is fixedly connected inside the housing 1, the transmission component 22 is movably connected inside the housing 1, and the heat dissipation component 23 is movably connected inside the housing 1.
The inside swing joint of shell 1 has detection mechanism 3 to the temperature perception of mount 21, and detection mechanism 3 is including responding to shell 301, responds to shell 301 fixed connection in the inside of shell 1, and impact block 302 sliding connection is in the inside of responding to shell 301, and the outside fixedly connected with spring two 303 of impact block 302 responds to the inside fixedly connected with circular telegram contact 304 of shell 301.
The sensing shell 301 corresponds to the fixing frame 21 in position and is matched with the fixing frame 21 in specification, the impact block 302 corresponds to the energized contact 304 in position and is matched with the energized contact in specification, two ends of the second spring 303 are fixedly connected to the inside of the sensing shell 301 and the outside of the impact block 302 respectively, and nitrogen is added into a closed space formed among the sensing shell 301, the impact block 302 and the second spring 303.
Example three:
referring to fig. 1-7, a multifunctional transformer framework includes a housing 1, an overheat protection mechanism 2 is movably connected inside the housing 1, the overheat protection mechanism 2 includes a fixing frame 21, a transmission component 22 for collecting heat inside the fixing frame 21, and a heat dissipation component 23 for collecting heat and cooling, the fixing frame 21 is fixedly connected inside the housing 1, the transmission component 22 is movably connected inside the housing 1, and the heat dissipation component 23 is movably connected inside the housing 1.
The transmission assembly 22 comprises a copper pipe 221, the copper pipe 221 is fixedly connected inside the fixing frame 21, the inner portion of the housing 1 is fixedly connected with a bearing plate 222, the outer portion of the bearing plate 222 is fixedly connected with a first motor 223, the outer portion of the first motor 223 is fixedly connected with a rotating plate 224, the outer portion of the rotating plate 224 is fixedly connected with a rotating rod 225, the outer portion of the bearing plate 222 is fixedly connected with a water collecting plate 226, the inner portion of the water collecting plate 226 is slidably connected with a pressure plate 227, the outer portion of the pressure plate 227 is fixedly connected with an expansion rod 228, the outer portion of the pressure plate 227 is fixedly connected with a connecting rod 229, the outer portion of the connecting rod 229 is fixedly connected with a transmission plate 2210, the inner side of the water collecting plate 226 is fixedly connected with a water inlet pipe, the inner side of the water inlet pipe is movably connected with a baffle 2212, and the outer portion of the baffle 2212 is fixedly connected with a first spring 2213.
The heat dissipation assembly 23 comprises a second motor 231, the second motor 231 is fixedly connected to the outside of the bearing plate 222, a guide plate 232 is fixedly connected to the outside of the second motor 231, a condensation pipe 233 is fixedly connected to the outside of the bearing plate 222, a ventilation cover 234 is fixedly connected to the inner side of the housing 1, and a flow opening 235 is formed in the surface of the housing 1.
The inside swing joint of shell 1 has detection mechanism 3 to the temperature perception of mount 21, and detection mechanism 3 is including responding to shell 301, responds to shell 301 fixed connection in the inside of shell 1, and impact block 302 sliding connection is in the inside of responding to shell 301, and the outside fixedly connected with spring two 303 of impact block 302 responds to the inside fixedly connected with circular telegram contact 304 of shell 301.
Distilled water is added in the copper pipe 221, two ends of the copper pipe 221 are respectively fixedly connected to the outside of the inlet pipe 2211 and the outside of the condensation pipe 233, the rotating rod 225 corresponds to the position of the transfer plate 2210 and is matched with the specification, the pressure plate 227 is connected with the water collecting plate 226 in a sliding and sealing manner, two ends of the telescopic rod 228 are respectively fixedly connected to the inside of the water collecting plate 226 and the outside of the pressure plate 227, the connecting rod 229 is connected with the water collecting plate 226 in a sliding manner, the baffle 2212 corresponds to the position of the inlet pipe 2211 and is matched with the specification, two ends of the first spring 2213 are respectively fixedly connected to the outside of the baffle 2212 and the inside of the inlet pipe 2211, the guide plate 232 corresponds to the position of the condensation pipe 233 and is matched with the specification, the ventilation cover 234 corresponds to the position of the condensation pipe 233 and is matched with the specification, two ends of the condensation pipe 233 are respectively fixedly connected to the outside of the water collecting plate 226 and the copper pipe 221, and the flow port 235 corresponds to the position of the guide plate 232 and is matched with the specification.
The position of the induction shell 301 corresponds to that of the fixed frame 21, the specification of the induction shell is matched, the position of the impact block 302 corresponds to that of the electrified contact 304, the specification of the impact block is matched, two ends of the second spring 303 are fixedly connected to the inside of the induction shell 301 and the outside of the impact block 302 respectively, and nitrogen is added into a closed space formed among the induction shell 301, the impact block 302 and the second spring 303.
The first motor 223 and the second motor 231 are both electrically connected with the energized contact 304, the energized contact 304 is triggered, the internal circuit is changed from open circuit to closed circuit, and then the first motor 223 and the second motor 231 are electrified.
When the device is started, the fixing frame 21 generates heat and transfers the heat to the surface of the induction shell 301, the heat causes nitrogen inside the induction shell 301 to expand and push the collision block 302 to slide inside the induction shell 301, the collision block 302 slides and causes the spring II 303 to extend, the collision block 302 slides until being in contact with the energized contact 304, then the motor I223 and the motor II 231 are energized, the motor I223 is energized to operate and drive the rotating plate 224 to rotate, the rotating plate 224 rotates and drives the rotating rod 225 to rotate, the rotating rod 225 rotates and drives the transmission plate 2210 to move, the transmission plate 2210 moves and drives the connecting rod 229 to slide outside the water collection plate 226, the connecting rod 229 slides and drives the pressure plate 227 to slide inside the water collection plate 226, when the pressure plate 227 slides along the direction of the transmission plate 2210, the pressure plate 227 slides and causes the telescopic rod 228 to contract, the pressure plate 227 slides and causes negative pressure to generate inside the water collection plate 226, so that distilled water carrying heat of the fixing frame 21 inside the copper pipe 221 pushes the baffle 2212 to move and causes the inlet pipe 2211 to open, distilled water enters the inside of the water collecting plate 226, when the pressure plate 227 slides along the direction of the inlet pipe 2211, the pressure plate 227 slides to enable the inside of the water collecting plate 226 to generate positive pressure, so that the baffle 2212 inside the inlet pipe 2211 closes the inlet pipe 2211 under the action of the restoring force of the first spring 2213, meanwhile, distilled water inside the water collecting plate 226 enters the internal circulation of the condensation pipe 233 and then returns to the inside of the copper pipe 221 again, meanwhile, the second motor 231 operates to drive the guide plate 232 to rotate, the guide plate 232 rotates to enable air inside the shell 1 to be discharged out of the shell 1 through the flow port 235, meanwhile, air outside the shell 1 with reduced pressure inside the shell 1 is blown to the surface of the condensation pipe 233 through the ventilation cover 234 under the action of air pressure, and the heat on the surface of the condensation pipe 233 is reduced through sequential circulation.
When the heat in the fixing frame 21 is continuously reduced, the nitrogen inside the induction shell 301 contracts, the impact block 302 slides under the action of the restoring force of the second spring 303 until the impact block is separated from the energized contact 304, and the first motor 223 and the second motor 231 stop energizing.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.
Claims (7)
1. A multi-functional transformer skeleton, includes shell (1), its characterized in that: the internal connection of shell (1) has overheat protection mechanism (2), and overheat protection mechanism (2) are including mount (21), be used for the inside heat collection's of mount (21) transmission component (22), be used for collecting the refrigerated radiator unit (23) of heat, and the inside at shell (1) is connected in mount (21), and transmission component (22) are connected in the inside of shell (1), and radiator unit (23) are connected in the inside of shell (1).
2. The multifunctional transformer skeleton of claim 1, wherein: the transmission assembly (22) comprises a copper pipe (221), the copper pipe (221) is fixedly connected inside the fixing frame (21), the inside of the shell (1) is fixedly connected with a bearing plate (222), the outside of the bearing plate (222) is fixedly connected with a motor I (223), the outside of the motor I (223) is fixedly connected with a rotating plate (224), the outside of the rotating plate (224) is fixedly connected with a rotating rod (225), the outside of the bearing plate (222) is fixedly connected with a water collecting plate (226), the inside of the water collecting plate (226) is slidably connected with a pressure plate (227), the outside of the pressure plate (227) is fixedly connected with a telescopic rod (228), the outside of the pressure plate (227) is fixedly connected with a connecting rod (229), the outside of the connecting rod (229) is fixedly connected with a transmission plate (2210), the inside of the water collecting plate (226) is fixedly connected with a water inlet pipe, and the inside of the water inlet pipe is movably connected with a baffle plate (2212), a first spring (2213) is fixedly connected to the outer part of the baffle (2212).
3. The multifunctional transformer skeleton of claim 2, wherein: the heat dissipation assembly (23) comprises a second motor (231), the second motor (231) is fixedly connected to the outside of the bearing plate (222), a guide plate (232) is fixedly connected to the outside of the second motor (231), a condensation pipe (233) is fixedly connected to the outside of the bearing plate (222), a ventilation cover (234) is fixedly connected to the inner side of the shell (1), and a flow opening (235) is formed in the surface of the shell (1).
4. The multifunctional transformer skeleton of claim 1, wherein: the inside swing joint of shell (1) has detection mechanism (3), and detection mechanism (3) are including responding to shell (301), respond to shell (301) fixed connection in the inside of shell (1), and collision piece (302) sliding connection is in the inside of responding to shell (301), and the outside fixedly connected with spring two (303) of collision piece (302), the inside fixedly connected with circular telegram contact (304) of responding to shell (301).
5. The multifunctional transformer skeleton of claim 3, wherein: distilled water is added in the copper pipe (221), two ends of the copper pipe (221) are respectively and fixedly connected to the outside of the inlet pipe (2211) and the outside of the condensing pipe (233), the rotating rod (225) corresponds to the position of the transfer plate (2210) and is matched with the pressure plate (227), the pressure plate (227) is in sliding sealing connection with the water collecting plate (226), two ends of the telescopic rod (228) are respectively and fixedly connected to the inside of the water collecting plate (226) and the outside of the pressure plate (227), the connecting rod (229) is in sliding connection with the water collecting plate (226), the baffle (2212) corresponds to the position of the inlet pipe (2211) and is matched with the specification, two ends of the spring I (2213) are respectively and fixedly connected to the outside of the baffle (2212) and the inside of the inlet pipe (2211), the guide plate (232) corresponds to the position of the condensing pipe (233) and is matched with the specification, the ventilation cover (234) corresponds to the position of the condensing pipe (233) and is matched with the specification, two ends of the condensation pipe (233) are respectively and fixedly connected with the outside of the water collecting plate (226) and the outside of the copper pipe (221), and the position of the flow opening (235) corresponds to that of the guide plate (232) and the specification is matched.
6. The multifunctional transformer skeleton of claim 4, wherein: the induction shell (301) corresponds to the fixed frame (21) in position and is matched with the fixed frame in specification, the collision block (302) corresponds to the power-on contact (304) in position and is matched with the power-on contact in specification, two ends of the second spring (303) are fixedly connected to the inside of the induction shell (301) and the outside of the collision block (302) respectively, and nitrogen is added into a closed space formed among the induction shell (301), the collision block (302) and the second spring (303).
7. The multifunctional transformer skeleton of claim 3, wherein: the first motor (223) and the second motor (231) are both electrically connected with the electrifying contact (304), the electrifying contact (304) is triggered, the internal circuit of the electrifying contact is changed from open circuit to open circuit, and then the first motor (223) and the second motor (231) are electrified.
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CN202122195378.XU CN216719685U (en) | 2021-09-11 | 2021-09-11 | Multifunctional transformer framework |
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CN202122195378.XU CN216719685U (en) | 2021-09-11 | 2021-09-11 | Multifunctional transformer framework |
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CN216719685U true CN216719685U (en) | 2022-06-10 |
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