CN112185675A - Pouring device for dry-type transformer - Google Patents

Abstract

The invention discloses a pouring device for a dry-type transformer, which comprises a machine body and is characterized in that: the dry-type transformer epoxy resin gel filling machine is characterized in that a blanking space is arranged in the machine body, a blanking mechanism is arranged in the blanking space and used for conveying epoxy resin pouring of the dry-type transformer, a pouring space is arranged on the lower side of the blanking space, a compensation mechanism is arranged in the pouring space and used for filling material shortage caused by resin curing shrinkage in a gel process of epoxy resin, a conduction space is arranged on the right side of the pouring space, and an induction mechanism is arranged in the conduction space and used for detecting the amount of the epoxy resin.

Description

Pouring device for dry-type transformer

Technical Field

The invention belongs to the related field of transformer selection, and particularly relates to a pouring device for a dry-type transformer.

Background

The transformer is a static electrical equipment for transforming alternating voltage and current to transmit alternating current energy, and realizes the transmission of the electric energy according to the principle of electromagnetic induction, wherein the transformer can be classified into the following types according to insulating media: oil immersed transformers, dry transformers, gas insulated transformers;

at present, epoxy resin is basically used for pouring the dry-type transformer, but the epoxy resin is cured and shrunk in a gelling process so as to cause material shortage, and thus the pouring defect occurs.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a pouring device for a dry-type transformer.

The purpose of the invention can be realized by the following technical scheme: the utility model provides a be used for dry-type transformer pouring device, includes the organism, its characterized in that: the dry-type transformer epoxy resin gel filling machine is characterized in that a blanking space is arranged in the machine body, a blanking mechanism is arranged in the blanking space and used for transmission of epoxy resin pouring of a dry-type transformer, a pouring space is arranged on the lower side of the blanking space, a compensation mechanism is arranged in the pouring space and used for filling material shortage caused by curing and shrinking of resin in a gel process, a conduction space is arranged on the right side of the pouring space, an induction mechanism is arranged in the conduction space and used for detecting the amount of the epoxy resin.

Preferably, the blanking mechanism comprises a power motor fixedly arranged on the upper side wall of the blanking space, the output end of the power motor is fixedly connected with a power screw, a blanking slider is sleeved on the power screw and extends downwards to penetrate through the lower side wall of the blanking space to enter the pouring space, a slider cavity is arranged in the blanking slider, a blanking disc is fixedly connected to the lower side wall of the blanking space, the blanking disc is connected with the blanking slider in a sliding manner, a disc cavity is arranged in the blanking disc and is communicated with the slider cavity, a rectangular block is fixedly connected to the right side wall of the blanking space, a rectangular cavity is arranged in the rectangular block, the lower side wall of the rectangular cavity is communicated with the disc cavity, a first slide way is communicated with the right side wall of the rectangular cavity, and a storage box body is fixedly connected to the upper end face of the machine body, deposit and be provided with in the box and deposit the chamber, it is used for depositing epoxy to deposit the chamber, it has the discharge gate to deposit chamber left side wall intercommunication, the discharge gate with first slide is linked together.

And in an initial state, the disc cavity is communicated with the slider cavity, and when pouring is needed, the epoxy resin in the storage cavity enters the rectangular cavity through the discharge hole, enters the disc cavity and finally enters the slider cavity to prepare for pouring.

Preferably, the sensing mechanism comprises two pressed sliding columns which are slidably connected and installed on the lower side wall of the pouring space, the two pressed sliding columns are bilaterally and symmetrically distributed around the central line of the pouring space, the upper end surfaces of the two pressed sliding columns are fixedly connected with pressed sliding plates which are slidably connected with the left and right side walls of the pouring space, the pressed sliding plates slide up and down relative to the right side wall of the pouring space, each pressed sliding column is respectively sleeved with a pressed spring, one end of each pressed spring is fixedly connected with the lower side wall of the pouring space, the other end of each pressed sliding plate is fixedly connected with the lower end surface of each pressed sliding plate, the right end surface of each pressed sliding plate is fixedly connected with a linkage sliding plate, the linkage sliding plate extends rightwards to penetrate through the right side wall of the pouring space to enter the conduction space, and the rear side wall of the conduction space, the second rotating shaft is sleeved with a first swing arm, the first swing arm is fixedly connected with the second rotating shaft, the left end face of the first swing arm is fixedly connected with a left abutting block, the left abutting block abuts against the linkage sliding plate, the right end face of the first swing arm is fixedly connected with a right abutting block, a reset spring is connected between the lower end face of the right abutting block and the lower side wall of the conduction space, the upper side of the conduction space is provided with a driven space, the lower side wall of the driven space is slidably connected with a penetrating slide bar, the penetrating slide bar extends downwards to penetrate through the lower side wall of the driven space to enter the conduction space, the lower end face of the penetrating slide bar abuts against the right abutting block, the rear side wall of the driven space is rotatably connected with a first rotating shaft, the first rotating shaft is sleeved with a second swing arm, the second swing arm is fixedly connected with the first rotating shaft, and the right end face of the second swing, the lower end face of the induction butt block is abutted against the upper end face of the driven space, a sliding column opening which penetrates through the upper portion and the lower portion is arranged in the second swing arm, an induction sliding rod is fixedly connected to the upper side wall of the driven space, an induction sliding block is sleeved on the induction sliding rod and is in sliding connection with the induction sliding rod, the induction sliding block extends leftwards to penetrate through the left side wall of the driven space to enter the pouring space, a hinged sliding column is fixedly connected to the right end of the induction sliding block, the hinged sliding column is in sliding connection with the sliding column opening, an induction spring is connected between the upper end face of the induction sliding block and the upper side wall of the driven space, a resin inductor is fixedly connected to the lower end face of the induction sliding block and is electrically connected with an induction motor, the left side wall of the pouring space is communicated with a second space with an opening leftwards, and, sliding connection has the sealed slide in the second slide, sealed slide up end fixedly connected with dials the piece, it runs through to dial the piece left side organism left end face, dial the piece up end with be connected with pressure spring between the lateral wall on the second slide.

In an initial state, the induction spring is in a stretched state, the pressure spring is in a compressed state, when pouring is needed, the poking block is poked to slide upwards to compress the pressure spring, a transformer die is placed in the pouring space and is positioned on the upper end face of the pressure sliding plate, so that the pressure sliding plate is pressed to slide downwards, the pressure spring is compressed, the linkage sliding plate is driven to slide downwards, the left abutting block is driven to move downwards, the right abutting block is driven to move upwards, the reset spring is stretched, the penetrating sliding rod is driven to slide upwards, the induction abutting block is driven to move upwards, the induction sliding block is driven to slide downwards, the induction sliding block is driven to abut against the upper end face of the transformer die, the induction spring is stretched, and the resin inductor is driven to slide downwards, and the pressure spring is flush with the opening surface of the pouring space of the transformer, and the pressure spring is reset at the moment to push the sealing sliding plate to seal the pouring space.

Preferably, the compensation mechanism comprises a pouring box body fixedly installed on the lower end face of the blanking sliding block, the pouring box body is connected with the inner wall of the pouring space in a sliding manner, a first space is arranged in the pouring box body, the upper side wall of the first space is communicated with the lower side wall of the sliding block cavity, a driving space is arranged on the lower side of the first space, an induction motor is fixedly connected with the upper side wall of the driving space, a driving rotating shaft is fixedly connected with the output end of the induction motor, a driving rotating disc is sleeved on the driving rotating shaft and fixedly connected with the driving rotating shaft, two driving hinge blocks are fixedly connected with the lower end face of the driving rotating disc, the two driving hinge blocks are symmetrically distributed left and right about the central line of the driving rotating disc, and ventilation channels which penetrate through the left and right sides of the driving hinge blocks are respectively arranged, each air flow passage is respectively provided with an arc flow passage in the direction close to the drive hinging block, the two arc flow passages are respectively communicated with the left side wall and the right side wall of the first space, the lower side wall of each arc flow passage is respectively and fixedly connected with a special nozzle used for discharging epoxy resin, the left side wall and the right side wall of the drive space are respectively communicated with a blocking slide groove, the two blocking slide grooves are bilaterally symmetrical relative to the drive hinging block, each blocking slide groove is respectively communicated with the corresponding air flow passage and the arc flow passage, a blocking slide plate is respectively and slidably connected in each blocking slide groove, each blocking slide plate is respectively provided with a first opening and a second opening which are vertically penetrated, each first opening is respectively communicated with the corresponding air flow passage, and each second opening is respectively communicated with the corresponding arc flow passage, every separate and keep off the slide with correspond be connected with the drive connecting rod between the articulated piece of drive, drive connecting rod one end with the articulated piece of drive is articulated, the other end with separate and keep off the slide articulated.

In an initial state, the first opening is communicated with the ventilation runner, the arc runner is communicated with the second opening, when a transformer mold is placed, epoxy resin is added into the storage cavity at the moment, so that the epoxy resin enters the slide block cavity and enters the first space to be poured through the special nozzle, when the epoxy resin reaches the mold outlet and contacts the resin inductor, the induction motor is started to drive the driving rotating shaft to rotate, so that the driving rotating disc is driven to rotate, the driving connecting rod is driven to move towards the direction close to the driving rotating shaft, so that the blocking sliding plate is driven to slide towards the direction close to the driving rotating shaft, so that the first opening is disconnected from the ventilation runner, the arc runner is disconnected from the second opening, and the power motor is started at the moment, thereby drive the power lead screw rotates, thereby drives the unloading slider down slides, thereby drives the pouring box body down slides, thereby extrudees epoxy compaction in the air in the pouring space with the mould, thereby because the shrink of resin solidification can arouse scarce material and lead to the pouring defect in the gel in-process, when scarce material appears, the epoxy liquid level descends, makes the resin inductor disconnection response, thereby makes induction motor reversal will the runner of ventilating with the arc runner is opened, continues to supply epoxy, opens after the pouring is accomplished at last the closed slide takes out the mould, so can not only avoid because the shrink of resin solidification can arouse scarce material and lead to the pouring defect in the gel in-process, can also improve the pouring quality, has improved the security performance of transformer greatly.

In conclusion, the beneficial effects of the invention are as follows: the invention can effectively pour the transformer, can avoid the pouring defect caused by material shortage due to resin curing shrinkage in the gelling process, can also improve the pouring quality, greatly improves the safety performance of the transformer, and simultaneously prolongs the service life of the transformer.

Drawings

Fig. 1 is a cross-sectional view of the overall structure of the pouring device of the dry type transformer.

Fig. 2 is a partially enlarged schematic view of the invention at a in fig. 1.

Fig. 3 is a partially enlarged schematic view of the invention at B in fig. 1.

Fig. 4 is an enlarged partial schematic view of the invention at C in fig. 1.

Fig. 5 is an enlarged partial schematic view of the invention at D in fig. 1.

Fig. 6 is an enlarged partial schematic view at E of fig. 1 of the present invention.

In the figure, a machine body 10; a storage case 11; a storage chamber 12; a discharge port 13; a first slideway 14; a blanking space 15; a power motor 16; a power screw 17; a slider cavity 18; a blanking slide block 19; a blanking disc 20; a disc chamber 21; a casting space 22; the first space 23; pouring the box body 24; a second slideway 25; a pressure spring 26; a dial block 27; a closure slide 28; the second space 29; a pressure slide 30; a compression spring 31; a pressurized spool 32; a conductive space 33; a first swing arm 34; a right abutment block 35; penetrates through the sliding rod 36; an induction abutment block 37; the driven space 38; a second swing arm 39; a rectangular block 40; a rectangular cavity 41; a ventilation flow passage 42; a blocking chute 43; a baffle slide plate 44; a first opening 45; an arcuate flow passage 46; a second opening 47; a dedicated nozzle 48; an induction motor 49; a drive space 50; a driving shaft 51; a drive dial 52; driving the articulation block 53; the drive link 54; an induction slide 55; an induction spring 56; an induction slider 57; a resin inductor 58; a hinge strut 59; a spool opening 60; a first rotating shaft 61; a linking slide plate 62; a left abutment block 63; a second shaft 64.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1, a pouring device for a dry-type transformer includes a machine body 10, and is characterized in that: be provided with unloading space 15 in the organism 10, be equipped with unloading mechanism in the unloading space 15, unloading mechanism is used for the transmission of dry-type transformer epoxy pouring, unloading space 15 downside is provided with pouring space 22, be equipped with compensating mechanism in the pouring space 22, compensating mechanism is used for filling the epoxy and the lack material that produces at gel in-process resin solidification shrink, pouring space 22 right side is provided with conduction space 33, be equipped with induction mechanism in the conduction space 33, induction mechanism is used for detecting how much of epoxy volume.

Referring to fig. 1 and 2, the blanking mechanism includes a power motor 16 fixedly mounted on an upper side wall of the blanking space 15, an output end of the power motor 16 is fixedly connected with a power screw 17, the power screw 17 is sleeved with a blanking slider 19, the blanking slider 19 extends downwards to penetrate through a lower side wall of the blanking space 15 to enter the casting space 22, a slider cavity 18 is formed in the blanking slider 19, a blanking disc 20 is fixedly connected to the lower side wall of the blanking space 15, the blanking disc 20 is slidably connected with the blanking slider 19, a disc cavity 21 is formed in the blanking disc 20, the disc cavity 21 is communicated with the slider cavity 18, a rectangular block 40 is fixedly connected to a right side wall of the blanking space 15, a rectangular cavity 41 is formed in the rectangular block 40, a lower side wall of the rectangular cavity 41 is communicated with the disc cavity 21, and a first slide 14 is communicated with the right side wall of the rectangular cavity 41, organism 10 up end fixedly connected with deposits box 11, it deposits chamber 12 to be provided with in the box 11 to deposit, it is used for depositing epoxy to deposit chamber 12, it has discharge gate 13 to deposit chamber 12 left side wall intercommunication, discharge gate 13 with first slide 14 is linked together.

In an initial state, the disk cavity 21 is communicated with the slider cavity 18, and when pouring is needed, the epoxy resin in the storage cavity 12 enters the rectangular cavity 41 through the discharge port 13, enters the disk cavity 21, and finally enters the slider cavity 18 to be poured.

Referring to fig. 1, 5 and 6, the sensing mechanism includes two pressure-receiving sliding columns 32 slidably connected to the lower sidewall of the casting space 22, the two pressure-receiving sliding columns 32 are symmetrically distributed about the center line of the casting space 22, pressure-receiving sliding plates 30 are fixedly connected to the upper end surfaces of the two pressure-receiving sliding columns 32, the pressure-receiving sliding plates 30 are slidably connected to the left and right sidewalls of the casting space 22, the pressure-receiving sliding plates 30 slide up and down relative to the right sidewall of the casting space 22, each pressure-receiving sliding column 32 is sleeved with a pressure-receiving spring 31, one end of each pressure-receiving spring 31 is fixedly connected to the lower sidewall of the casting space 22, the other end of each pressure-receiving spring is fixedly connected to the lower end surface of the pressure-receiving sliding plate 30, the right end surface of the pressure-receiving sliding plate 30 is fixedly connected to an interlocking sliding plate 62, the interlocking sliding plate 62 extends right to penetrate through the right sidewall of, the rear side wall of the conduction space 33 is rotatably connected with a second rotating shaft 64, the second rotating shaft 64 is sleeved with a first swing arm 34, the first swing arm 34 is fixedly connected with the second rotating shaft 64, the left end face of the first swing arm 34 is fixedly connected with a left abutting block 63, the left abutting block 63 is abutted against the linkage sliding plate 62, the right end face of the first swing arm 34 is fixedly connected with a right abutting block 35, a reset spring 65 is connected between the lower end face of the right abutting block 35 and the lower side wall of the conduction space 33, the upper side of the conduction space 33 is provided with a driven space 38, the lower side wall of the driven space 38 is slidably connected with a through slide bar 36, the through slide bar 36 extends downwards to penetrate through the lower side wall of the driven space 38 to enter the conduction space 33, the lower end face of the through slide bar 36 is abutted against the right abutting block 35, and the rear side wall of the driven space, the second swing arm 39 is sleeved on the first rotating shaft 61, the second swing arm 39 is fixedly connected with the first rotating shaft 61, the right end face of the second swing arm 39 is fixedly connected with the induction abutting block 37, the lower end face of the induction abutting block 37 abuts against the upper end face of the driven space 38, a sliding column opening 60 which penetrates through the second swing arm 39 from front to back is arranged in the second swing arm 39, an induction sliding rod 55 is fixedly connected with the upper side wall of the driven space 38, an induction sliding block 57 is sleeved on the induction sliding rod 55, the induction sliding block 57 is in sliding connection with the induction sliding rod 55, the induction sliding block 57 extends leftwards to penetrate through the left side wall of the driven space 38 to enter the pouring space 22, a hinged sliding column 59 is fixedly connected with the right end of the induction sliding block 57, the hinged sliding column 59 is in sliding connection with the sliding column opening 60, and an induction spring 56 is connected between the upper end face of the induction, end face fixedly connected with resin inductor 58 under response slider 57, resin inductor 58 with induction motor 49 electricity links, pouring space 22 left side wall intercommunication has opening second space 29 to the left, side wall intercommunication has second slide 25 on the second space 29, sliding connection has closed slide 28 in the second slide 25, closed slide 28 up end fixedly connected with dials movable block 27, dial movable block 27 and extend to the left and run through organism 10 left end face, dial movable block 27 up end with be connected with pressure spring 26 between the side wall on the second slide 25.

In an initial state, the sensing spring 56 is in a stretched state, the pressure spring 26 is in a compressed state, when pouring is required, the toggle block 27 is toggled to slide upwards, so as to compress the pressure spring 26, a transformer mold is placed in the pouring space 22 and located on the upper end face of the pressure slide plate 30, so as to press the pressure slide plate 30 to slide downwards, so as to compress the pressure spring 31, so as to drive the linkage slide plate 62 to slide downwards, so as to drive the left abutting block 63 to move downwards, so as to drive the right abutting block 35 to move upwards, so as to stretch the return spring 65, so as to drive the through slide rod 36 to slide upwards, so as to drive the sensing abutting block 37 to move upwards, so as to drive the sensing slide block 57 to slide downwards, so as to abut against the upper end face of the transformer mold, so as to stretch the sensing spring 56, thereby driving the resin inductor 58 to slide downwards and be flush with the opening surface of the pouring space of the transformer, at the moment, the pressure spring 26 is reset, and the sealing slide plate 28 is pushed to seal the pouring space 22.

With reference to fig. 1, fig. 3 and fig. 4, the compensation mechanism includes a pouring box 24 fixedly mounted on the lower end surface of the blanking slider 19, the pouring box 24 is connected with the inner wall of the pouring space 22 in a sliding manner, a first space 23 is provided in the pouring box 24, the upper side wall of the first space 23 is communicated with the lower side wall of the slider cavity 18, a driving space 50 is provided on the lower side of the first space 23, an induction motor 49 is fixedly connected to the upper side wall of the driving space 50, an output end of the induction motor 49 is fixedly connected with a driving rotating shaft 51, a driving turntable 52 is sleeved on the driving rotating shaft 51, the driving turntable 52 is fixedly connected with the driving rotating shaft 51, two driving hinge blocks 53 are fixedly connected to the lower end surface of the driving turntable 52, and the two driving hinge blocks 53 are symmetrically distributed about the central line of the driving turntable, the left side and the right side of the driving hinge block 53 are respectively provided with a ventilation runner 42 which penetrates through up and down by taking the central line of the pouring box body 24 as a symmetrical center, each ventilation runner 42 is respectively provided with an arc runner 46 in the direction close to the driving hinge block 53, the two arc runners 46 are respectively communicated with the left side wall and the right side wall of the first space 23, the lower side wall of each arc runner 46 is respectively and fixedly connected with a special nozzle 48, the special nozzle 48 is used for discharging epoxy resin, the left side wall and the right side wall of the driving space 50 are respectively communicated with a blocking chute 43, the two blocking chutes 43 are bilaterally symmetrical relative to the driving hinge block 53, each blocking chute 43 is respectively communicated with the corresponding ventilation runner 42 and the arc runner 46, each blocking chute 43 is respectively and slidably connected with a blocking slide plate 44, and each blocking slide plate 44 is respectively provided with a first opening 45 and a second opening 47 which penetrate through up and down, each first opening 45 is respectively communicated with the corresponding ventilation flow passage 42, each second opening 47 is respectively communicated with the corresponding arc-shaped flow passage 46, a driving connecting rod 54 is connected between each blocking sliding plate 44 and the corresponding driving hinging block 53, one end of each driving connecting rod 54 is hinged with the driving hinging block 53, and the other end of each driving connecting rod 54 is hinged with the blocking sliding plate 44.

In an initial state, the first opening 45 is communicated with the ventilation flow passage 42, the arc-shaped flow passage 46 is communicated with the second opening 47, when the transformer mold is placed, epoxy resin is added into the storage cavity 12 at this time, so that epoxy resin enters the slider cavity 18 and enters the first space 23 to be poured through the special nozzle 48, when the epoxy resin reaches the mold opening and contacts the resin inductor 58, the induction motor 49 is started to drive the driving rotating shaft 51 to rotate, so as to drive the driving rotating disc 52 to rotate, so as to drive the driving connecting rod 54 to move towards the driving rotating shaft 51, so as to drive the blocking slide plate 44 to slide towards the driving rotating shaft 51, so that the first opening 45 is disconnected from the ventilation flow passage 42, so that the arc-shaped flow passage 46 is disconnected from the second opening 47, at the moment, the power motor 16 is started, so that the power screw 17 is driven to rotate, the blanking slide block 19 is driven to slide downwards, thereby causing the casting box 24 to slide downward, thereby pressing the air in the casting space 22 to compact the epoxy resin in the mold, since the resin curing shrinkage during the gelling process causes a shortage of material, which leads to a casting defect, when the shortage occurs, the epoxy resin level drops, so that the resin sensor 58 is de-sensed, so that the induction motor 49 rotates reversely, the ventilation runner 42 and the arc runner 46 are opened, the epoxy resin is continuously replenished, finally the closed sliding plate 28 is opened after the pouring is finished, the mould is taken out, therefore, the defect of casting caused by material shortage due to resin curing shrinkage in the gel process can be avoided, the casting quality can be improved, and the safety performance of the transformer is greatly improved.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. A pouring device for a dry-type transformer comprises a machine body (10), and is characterized in that: be provided with unloading space (15) in organism (10), be equipped with unloading mechanism in unloading space (15), unloading mechanism is used for the transmission of dry-type transformer epoxy pouring, unloading space (15) downside is provided with pouring space (22), be equipped with compensating mechanism in pouring space (22), compensating mechanism is used for filling the epoxy and solidifies the scarce material that the shrink and produce at gel in-process resin, pouring space (22) right side is provided with conduction space (33), be equipped with response mechanism in conduction space (33), response mechanism is used for detecting how much of epoxy volume.

2. A pouring device for dry-type transformer according to claim 1, characterized in that: the blanking mechanism comprises a power motor (16) fixedly installed on the upper side wall of the blanking space (15), the output end of the power motor (16) is fixedly connected with a power lead screw (17), a blanking sliding block (19) is sleeved on the power lead screw (17), the blanking sliding block (19) extends downwards to penetrate through the lower side wall of the blanking space (15) to enter the pouring space (22), a sliding block cavity (18) is formed in the blanking sliding block (19), a blanking disc (20) is fixedly connected to the lower side wall of the blanking space (15), the blanking disc (20) is in sliding connection with the blanking sliding block (19), a disc cavity (21) is formed in the blanking disc (20), the disc cavity (21) is communicated with the sliding block cavity (18), a rectangular block (40) is fixedly connected to the right side wall of the blanking space (15), and a rectangular cavity (41) is formed in the rectangular block (40), rectangle chamber (41) lower lateral wall with disc chamber (21) are linked together, rectangle chamber (41) right side wall intercommunication has first slide (14), organism (10) up end fixedly connected with deposits box (11), it deposits chamber (12) to be provided with in box (11) to deposit, it is used for depositing epoxy to deposit chamber (12), it has discharge gate (13) to deposit chamber (12) left side wall intercommunication, discharge gate (13) with first slide (14) are linked together.

3. A pouring device for dry-type transformer according to claim 1, characterized in that: response mechanism includes that sliding connection installs two pressurized traveller (32) of lateral wall under pouring space (22), two pressurized traveller (32) about pouring space (22) central line is bilateral symmetry and distributes, two pressurized traveller (32) up end fixedly connected with pressurized slide (30), pressurized slide (30) with lateral wall sliding connection about pouring space (22), pressurized slide (30) for pouring space (22) right side wall slides from top to bottom, every be equipped with pressurized spring (31) on pressurized traveller (32) respectively, pressurized spring (31) one end with pouring space (22) lower lateral wall fixed connection, the other end with pressurized slide (30) lower extreme face fixed connection, pressurized slide (30) right-hand member face fixedly connected with interlock slide (62), interlock slide (62) extend right and run through pouring space (22) right side wall gets into conduct empty entering The conduction space (33) rear side wall is connected with a second rotating shaft (64) in a rotating mode, a first swing arm (34) is sleeved on the second rotating shaft (64), the first swing arm (34) is fixedly connected with the second rotating shaft (64), a left abutting block (63) is fixedly connected with the left end face of the first swing arm (34), the left abutting block (63) is abutted to the linkage sliding plate (62), a right abutting block (35) is fixedly connected with the right end face of the first swing arm (34), a reset spring (65) is connected between the lower end face of the right abutting block (35) and the lower side wall of the conduction space (33), a driven space (38) is arranged on the upper side of the conduction space (33), a through slide rod (36) is slidably connected with the lower side wall of the driven space (38), the through slide rod (36) extends downwards to penetrate the lower side wall of the driven space (38) to enter the conduction space (33), run through under slide bar (36) terminal surface with right butt joint piece (35) butt, driven space (38) rear side wall rotates and is connected with first pivot (61), the cover is equipped with second swing arm (39) on first pivot (61), second swing arm (39) with first pivot (61) fixed connection, second swing arm (39) right-hand member face fixedly connected with response butt joint piece (37), response butt joint piece (37) lower terminal surface with driven space (38) up end butt, be provided with fore-and-aft sliding column opening (60) that runs through in second swing arm (39), side wall fixedly connected with response slide bar (55) on driven space (38), the cover is equipped with response slider (57) on response slide bar (55), response slider (57) with response slide bar (55) sliding connection, response slider (57) extend to left and run through driven space (38) left side wall get into pouring space (22), the induction sliding block (57) right end fixedly connected with hinge sliding column (59), hinge sliding column (59) with sliding column opening (60) sliding connection, induction sliding block (57) up end with be connected with induction spring (56) between the lateral wall on driven space (38), terminal surface fixedly connected with resin inductor (58) under induction sliding block (57), resin inductor (58) with induction motor (49) electricity is even, pouring space (22) left side wall intercommunication has opening second space (29) to the left, lateral wall intercommunication has second slide (25) on second space (29), sliding connection has closed slide (28) in second slide (25), closed slide (28) up end fixedly connected with dials piece (27), dial piece (27) extend to the left and run through organism (10) left end face, and a pressure spring (26) is connected between the upper end surface of the toggle block (27) and the upper side wall of the second slide way (25).

4. A pouring device for dry-type transformer according to claim 2, characterized in that: compensating mechanism includes fixed mounting in pouring box (24) of terminal surface under unloading slider (19), pouring box (24) with pouring space (22) inner wall sliding connection, be provided with first space (23) in pouring box (24), lateral wall on first space (23) with slider chamber (18) lower lateral wall communicates, first space (23) downside is provided with drive space (50), lateral wall fixedly connected with induction motor (49) on drive space (50), induction motor (49) output end fixedly connected with drive pivot (51), the cover is equipped with drive carousel (52) on drive pivot (51), drive carousel (52) with drive pivot (51) fixed connection, two drive articulated piece (53) of terminal surface fixedly connected with under drive carousel (52), two drive articulated piece (53) about drive carousel (52) central line is bilateral symmetry and distributes, the left side and the right side of the driving hinging block (53) are respectively provided with an air flow channel (42) which penetrates through from top to bottom by taking the central line of the pouring box body (24) as a symmetrical center, each air flow channel (42) is respectively provided with an arc flow channel (46) in the direction close to the driving hinging block (53), the two arc flow channels (46) are respectively communicated with the left side wall and the right side wall of the first space (23), the lower side wall of each arc flow channel (46) is respectively and fixedly connected with a special nozzle (48), the special nozzle (48) is used for discharging epoxy resin, the left side wall and the right side wall of the driving space (50) are respectively communicated with a blocking sliding groove (43), the two blocking sliding grooves (43) are bilaterally symmetrical relative to the driving hinging block (53), and each blocking sliding groove (43) is respectively communicated with the corresponding air flow channel (42) and the arc, every separate and keep off in the spout (43) sliding connection respectively and keep off slide (44), every separate and keep off slide (44) in be provided with first opening (45) and second opening (47) that run through from top to bottom respectively, every first opening (45) respectively with correspond the runner (42) of ventilating is linked together, every second opening (47) respectively with correspond arc runner (46) are linked together, every separate and keep off slide (44) and correspond be connected with drive connecting rod (54) between drive articulated piece (53), drive connecting rod (54) one end with drive articulated piece (53) are articulated, the other end with separate and keep off slide (44) articulated.

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