CN117182237A

CN117182237A - Temperature control mechanism for heating plate brazing

Info

Publication number: CN117182237A
Application number: CN202311471135.1A
Authority: CN
Inventors: 莫任福; 於军
Original assignee: Tuolunsi Semiconductor Equipment Qidong Co ltd
Current assignee: Torrance Precision Manufacturing (Jiangsu) Co.,Ltd.
Priority date: 2023-11-07
Filing date: 2023-11-07
Publication date: 2023-12-08
Anticipated expiration: 2043-11-07
Also published as: CN117182237B

Abstract

The invention discloses a temperature control mechanism for brazing a heating disc, which comprises a shell, wherein an electric heating disc is arranged at the top of the shell, a first temperature probe is arranged in the electric heating disc, an electricity distribution ring and a lifting plate which can synchronously lift are arranged in the shell through electromagnetic temperature control components, a shaft sleeve is rotatably connected to the inner wall of the lifting plate, a rotary seat is fixedly arranged at the top end of the shaft sleeve, a group of guide grooves which are distributed in a circumferential array and are electrically connected with the electricity distribution ring are formed in the rotary seat, an electric heating seat is slidably connected to the inner wall of each guide groove, a snake-shaped electric heating wire is arranged on the top surface of the electric heating seat, a transmission ring is slidably connected to the peripheral side surface of the shaft sleeve, and a connecting rod is hinged between the opposite surfaces of each electric heating seat and the transmission ring. According to the invention, the singlechip controls the hot oil tank and the cold oil tank to quantitatively extract hot oil and quantitatively inject cold oil to the liquid in the oil cavity according to the data feedback of the first temperature probe and the second temperature probe, so that the feedback value of the first temperature probe is kept constant finally.

Description

Temperature control mechanism for heating plate brazing

Technical Field

The invention relates to the technical field of heating plates, in particular to a temperature control mechanism for brazing of a heating plate.

Background

In the existing semiconductor heater brazing temperature control structure, mainly aiming at the heater brazing parts, the temperature uniformity of heat transfer after welding is guaranteed to be an important index after welding is completed, meanwhile, the heat wire is located in the channel inside the heating disc because the channel inside the heating disc is rectangular in shape and the heating wire is circular in shape, and only quadrant dotted line contact is formed between the heating disc and the heating wire, so that certain gaps exist between the heating disc and the heating wire, the heat transfer is poor, the heat transfer effect is low, the energy consumption is high, the heat transfer of the heating disc is uneven, meanwhile, the interval distance between the channels inside the heating disc is large, and when heating is performed, certain time is required for temperature transfer, so that the temperature uniformity of the heat transfer is poor, and the temperature control effect is poor.

In the prior art, patent document with publication number CN116673558A discloses a semiconductor heater soldering temperature control structure, which comprises a base plate, a heating wire, a soldering lug, a cover plate and a driving component, wherein the heating wire is fixedly installed on the base plate, the base plate transfers heat to circulating flowing liquid through an arc-shaped closed channel and uniformly dispersedly transfers the temperature to the outer surface of a heating plate.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to provide a temperature control mechanism for brazing a heating disc, and a singlechip is used for controlling a hot oil tank and a cold oil tank to quantitatively extract hot oil and quantitatively inject the cold oil to liquid in an oil cavity according to data feedback of a first temperature probe and a second temperature probe, so that the feedback value of the first temperature probe is kept constant finally.

The invention provides a temperature control mechanism for brazing a heating disc, which adopts the following technical scheme: the electric heating device comprises a shell, the electrothermal disk is installed at the top of casing, the internally mounted of electrothermal disk has first temperature probe, but the electric distribution ring and the lifting plate of synchronous lift are installed through electromagnetic temperature control part to the inside of casing, the inner wall rotation of lifting plate is connected with the axle sleeve, the top fixed mounting of axle sleeve has the seat soon, a set of guide slot that is circumference array distribution and is connected with electric distribution ring electricity is offered to the inside of seat soon, every the equal sliding connection of inner wall of guide slot has the electric heating seat, the snakelike heating wire is installed to the top surface of electric heating seat, the week side sliding connection of axle sleeve has the driving ring, every all articulate between the opposite surfaces of electric heating seat and driving ring has the connecting rod, the reciprocating guide part of driving ring reciprocating motion is installed to the inner wall of casing, the axle sleeve is driven through reciprocating guide part, the fixed oil pocket of having seted up of inside of electric heating disk, the internally mounted through the even temperature part of axle sleeve drive, the cold and hot oil proportioning module of intercommunication is installed to the lower part of casing oil pocket.

As the preferred scheme, positive electrode groove and negative electrode groove have been seted up in proper order from top to bottom to the inner wall of cloth electric ring, every positive electrode guide rail and a negative electrode guide rail are all installed to the inner wall of guide slot, positive electrode guide rail and negative electrode guide rail's tail end all are connected with the guide bead, positive electrode guide rail's surface is through guide bead and positive electrode groove sliding connection, negative electrode guide rail's surface is through guide bead and negative electrode groove sliding connection, the positive and negative end of snakelike heating wire respectively with positive electrode guide rail and negative electrode guide rail sliding connection.

As a preferable scheme, the end face of the shell is fixedly provided with a singlechip, and the electric heating disc is made of metal.

As the preferred scheme, electromagnetic temperature control part is including being fixed in the electric magnetic ring of cloth electric ring bottom surface and setting up in electric magnetic ring below and with casing fixed connection's fixed magnetic ring respectively, the top surface fixed mounting of lifting plate is a set of circumference array distribution and with casing sliding connection's guide bar, the circumference side of guide bar and the position cover that corresponds lifting plate top are equipped with compression spring, the cross section of guide bar is T shape, lifting plate's top surface fixed mounting has a set of electromagnetism piece that is circumference array distribution, the inside of casing and the position that corresponds every electromagnetism piece all fixed mounting have fixed magnetic piece.

As a preferable scheme, the magnetism of the electromagnetic ring after being electrified is opposite to that of the fixed magnetic ring, and the magnetism of the electromagnetic block after being electrified is opposite to that of the fixed magnetic block.

As a preferred scheme, the reciprocating guide part respectively comprises a motor fixed in the shell and a vibration ring rotationally connected to the peripheral side surface of the transmission ring, a semiconductor gear and a transmission bevel gear are respectively and fixedly arranged at the output shaft end of the motor, a driven bevel gear meshed with the transmission bevel gear is fixedly arranged at the peripheral side surface of the shaft sleeve, a reciprocating toothed plate in transmission connection with the semiconductor gear is fixedly arranged at the bottom surface of the vibration ring, and a reset spring is arranged between the transmission ring and the opposite surface of the rotary seat.

As the preferred scheme, even temperature part is including rotating the vortex axle of connecting in the electrothermal disc inner wall, the inside position of week side and corresponding oil pocket of vortex axle is installed a set of stirring leaf that is circumference array and is distributed, stirring leaf is hollow structure, the week side and the axle sleeve transmission of vortex axle are connected and sliding fit, the axis position of vortex axle is fixed to be offered and is led the liquid runner, every the thru hole has all been offered to stirring leaf's inside, the surface of liquid runner is through thru hole and oil pocket intercommunication.

As a preferable scheme, the shaft sleeve is internally and fixedly provided with shaft grooves with two ends open and in sliding connection with the turbulence shaft, and the cross sections of the shaft grooves and the turbulence shaft are regular polygons.

As the preferred scheme, cold and hot oil proportioning module includes the branch liquid ring that rotates the intercommunication with the liquid guide channel respectively and is fixed in hot oil tank and the cold oil tank of casing both sides face respectively, the inside of hot oil tank and cold oil tank is all filled with the conduction oil, the lower part of hot oil tank and cold oil tank all communicates there is the pump body, two the other end of pump body all communicates with branch liquid ring is fixed through the pipeline, filter core and electromagnetic oil valve have been built-in respectively to the inside of pipeline, second temperature probe, level gauge and fluid replacement pipe are all installed to the inside of hot oil tank and cold oil tank, the inside of hot oil tank is built-in to have a set of electric stick, the internally mounted of cold oil tank has the semiconductor refrigerator, the port of first temperature probe, second temperature probe all is connected with monolithic electricity, the agitator is all installed to the inside of hot oil tank and cold oil tank.

Compared with the prior art, the invention provides a temperature control mechanism for brazing of a heating disc, which has the following beneficial effects:

1. according to the invention, after the snake-shaped heating wire works with set power, the first temperature probe and the second temperature probe feed back the monitored data to the singlechip in real time, the singlechip controls the hot oil tank and the cold oil tank to quantitatively extract hot oil and quantitatively inject the cold oil into the liquid in the oil cavity according to the data feedback of the first temperature probe, and then finally the feedback value of the first temperature probe is kept constant, so that the accurate temperature control of the electric heating disc is realized, and during the temperature control, the singlechip can intelligently adjust the distance difference between the snake-shaped heating wire and the electric heating disc according to the feedback of the first temperature probe, and then the heating efficiency of the electric heating disc and the temperature control precision of the electric heating disc are adjusted through the accurate control of the heated distance difference.

2. According to the invention, through the arrangement of the semiconductor gear, the vibration ring, the reset spring and the reciprocating toothed plate, after the motor outputs the rotating speed, the vibration ring and the transmission ring can synchronously reciprocate in a set stroke, and through the reciprocating movement of the vibration ring, the positions of the rotary seat and the electric heating seat in the rotary seat can be reciprocally changed in the circumferential rotation process, and through the reciprocal change of the positions of the electric heating seat, the heating position of the snake-shaped heating wire relative to the electric heating disc is reciprocally changed, so that uniform heating of the electric heating disc is finally realized, and the temperature uniformity and the temperature control precision of the electric heating disc are improved.

Drawings

FIG. 1 is a schematic diagram of a temperature control mechanism for brazing a heating plate according to the present invention;

FIG. 2 is a schematic cross-sectional view of FIG. 1 according to the present invention;

FIG. 3 is a schematic view of a partial enlarged structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic view of a partially enlarged structure of the present invention at B in FIG. 2;

FIG. 5 is a schematic view of the structure of the stirring blade and the through hole of the invention;

FIG. 6 is a schematic view of the hot and cold oil tanks of the present invention;

FIG. 7 is a schematic view of the structure of the stirring blade and the turbulence shaft of the present invention;

FIG. 8 is a schematic view of the structure of the power distribution ring of the present invention;

fig. 9 is a schematic view of the structure of the lifting plate and serpentine heating wire of the present invention;

FIG. 10 is a schematic view of a partially enlarged structure of FIG. 9C according to the present invention;

fig. 11 is a schematic view of the structure of the driving ring and the vibrating ring of the present invention.

In the figure: 1. a housing; 2. an electric heating plate; 3. a first temperature probe; 4. an electricity distribution ring; 5. a lifting plate; 6. a shaft sleeve; 7. a rotary seat; 8. a guide groove; 9. an electric heating seat; 10. serpentine electric heating wire; 11. a drive ring; 12. a connecting rod; 13. a positive electrode groove; 14. a negative electrode groove; 15. guiding the beads; 16. a single chip microcomputer; 17. an electromagnetic ring; 18. a fixed magnetic ring; 19. a guide rod; 20. a compression spring; 21. an electromagnetic block; 22. a fixed magnetic block; 23. a motor; 24. vibrating the ring; 25. a semiconductor gear; 26. a reciprocating toothed plate; 27. a return spring; 28. a disturbance flow shaft; 29. stirring the leaves; 30. a through hole; 31. a liquid separating ring; 32. a hot oil tank; 33. a cold oil tank; 34. a pump body; 35. a second temperature probe; 36. a liquid level gauge; 37. an electric heating rod; 38. a semiconductor refrigerator; 39. a stirrer; 40. a filter element.

Detailed Description

The invention is further illustrated and described below in conjunction with the specific embodiments and the accompanying drawings:

referring to fig. 1-11, the present invention: a temperature control mechanism for heating plate brazing adopts the following technical scheme: the electric heating device comprises a shell 1, wherein an electric heating disc 2 is arranged at the top of the shell 1, a first temperature probe 3 is arranged in the electric heating disc 2, a singlechip 16 is fixedly arranged on the end surface of the shell 1, and the electric heating disc 2 is made of metal;

an electricity distribution ring 4 and a lifting plate 5 which can synchronously lift are arranged in the shell 1 through an electromagnetic temperature control component;

the electromagnetic temperature control component comprises an electromagnetic ring 17 fixed on the bottom surface of the electricity distribution ring 4 and a fixed magnetic ring 18 arranged below the electromagnetic ring 17 and fixedly connected with the shell 1;

the magnetism of the electromagnetic ring 17 after being electrified is opposite to that of the fixed magnetic ring 18;

the magnetism of the electromagnetic ring 17 is opposite to that of the fixed magnetic ring 18 after the electromagnetic ring 17 is electrified, so that the position of the electromagnetic ring 17 in the shell 1 is controlled by the principle of magnetic repulsion;

the top surface of the lifting plate 5 is fixedly provided with a group of guide rods 19 which are distributed in a circumferential array and are in sliding connection with the shell 1, the circumferential side surface of the guide rods 19 is sleeved with compression springs 20 corresponding to the positions above the lifting plate 5, the cross section of the guide rods 19 is T-shaped, the top surface of the lifting plate 5 is fixedly provided with a group of electromagnetic blocks 21 which are distributed in a circumferential array, and the inside of the shell 1 is fixedly provided with fixed magnetic blocks 22 corresponding to the positions of each electromagnetic block 21;

the magnetism of the electromagnetic block 21 after being electrified is opposite to that of the fixed magnetic block 22;

the magnetism of the electromagnetic block 21 and the magnetism of the fixed magnetic block 22 are opposite, so that the position of the lifting plate 5 in the shell 1 is controlled by the principle of magnetic attraction and repulsion;

the inner wall of the lifting plate 5 is rotationally connected with a shaft sleeve 6, the top end of the shaft sleeve 6 is fixedly provided with a rotary seat 7, and a group of guide grooves 8 which are distributed in a circumferential array and are electrically connected with the electricity distribution ring 4 are formed in the rotary seat 7;

the inner wall of the electricity distribution ring 4 is provided with a positive electrode groove 13 and a negative electrode groove 14 from top to bottom in sequence;

the inner wall of each guide groove 8 is provided with an anode guide rail and a cathode guide rail, the tail ends of the anode guide rail and the cathode guide rail are connected with guide beads 15, the surface of the anode guide rail is in sliding connection with the anode groove 13 through the guide beads 15, and the surface of the cathode guide rail is in sliding connection with the cathode groove 14 through the guide beads 15;

the inner wall of each guide groove 8 is connected with an electric heating seat 9 in a sliding way, and the top surface of the electric heating seat 9 is provided with a snake-shaped electric heating wire 10;

the positive end and the negative end of the snake-shaped heating wire 10 are respectively connected with the positive guide rail and the negative guide rail in a sliding way;

the peripheral side surface of the shaft sleeve 6 is connected with a transmission ring 11 in a sliding manner, a connecting rod 12 is hinged between each electric heating seat 9 and the opposite surface of the transmission ring 11, a reciprocating guide part for driving the transmission ring 11 to reciprocate is arranged on the inner wall of the shell 1, and the shaft sleeve 6 is driven by the reciprocating guide part;

the reciprocating guide part comprises a motor 23 fixed in the shell 1 and a vibration ring 24 rotatably connected to the peripheral side surface of the transmission ring 11, a semi-conductor gear 25 and transmission bevel teeth are respectively fixedly arranged at the output shaft end of the motor 23, and driven bevel teeth meshed with the transmission bevel teeth are fixedly arranged at the peripheral side surface of the shaft sleeve 6;

the bottom surface of the vibration ring 24 is fixedly provided with a reciprocating toothed plate 26 in transmission connection with a semiconductor gear 25, and a return spring 27 is arranged between the opposite surfaces of the driving ring 11 and the rotary seat 7.

Through the arrangement of the semi-conductive gear 25, the vibration ring 24, the reset spring 27 and the reciprocating toothed plate 26, after the motor 23 outputs the rotating speed, the vibration ring 24 and the transmission ring 11 can synchronously reciprocate in a set stroke, and through the reciprocating movement of the vibration ring 24, the positions of the rotary seat 7 and the electric heating seat 9 in the rotary seat 7 can be reciprocally changed in the circumferential rotation process, and through the reciprocal change of the positions of the electric heating seat 9, the heating position of the snake-shaped electric heating wire 10 on the electric heating disc 2 is reciprocally changed, so that uniform heating of the electric heating disc 2 is finally realized;

an oil cavity is fixedly formed in the electric heating disc 2, and a temperature homogenizing component driven by a shaft sleeve 6 is arranged in the oil cavity;

the temperature-homogenizing component comprises a turbulent flow shaft 28 rotatably connected to the inner wall of the electric heating plate 2, a group of stirring blades 29 distributed in a circumferential array are arranged on the peripheral side surface of the turbulent flow shaft 28 and correspond to the position inside the oil cavity, the stirring blades 29 are of a hollow structure, and the peripheral side surface of the turbulent flow shaft 28 is in transmission connection with the shaft sleeve 6 and is in sliding fit;

the shaft sleeve 6 is internally fixedly provided with a shaft groove with two open ends and in sliding connection with the turbulence shaft 28, and the cross sections of the shaft groove and the turbulence shaft 28 are regular polygons;

the shaft sleeve 6 can continuously and effectively drive the turbulent flow shaft 28 when the shaft sleeve 6 is lifted by the arrangement of the shaft groove and the regular polygon cross section of the turbulent flow shaft 28;

the axial position of the flow disturbing shaft 28 is fixedly provided with a liquid guiding channel, the inside of each stirring blade 29 is provided with a through hole 30, and the surface of the liquid guiding channel is communicated with the oil cavity through the through holes 30

The lower part of the shell 1 is provided with a cold and hot oil proportioning module which is communicated with the oil cavity.

The cold and hot oil proportioning module comprises a liquid separating ring 31 which is rotationally communicated with a liquid guide channel, and a hot oil tank 32 and a cold oil tank 33 which are respectively fixed on two side surfaces of the shell 1, wherein the interiors of the hot oil tank 32 and the cold oil tank 33 are filled with heat-conducting oil, the lower parts of the hot oil tank 32 and the cold oil tank 33 are respectively communicated with a pump body 34, the other ends of the two pump bodies 34 are fixedly communicated with the liquid separating ring 31 through pipelines, a filter element 40 and an electromagnetic oil valve are respectively arranged in the pipelines, a second temperature probe 35, a liquid level meter 36 and a liquid supplementing pipe are respectively arranged in the interiors of the hot oil tank 32 and the cold oil tank 33, a group of electric heating rods 37 are arranged in the interiors of the hot oil tank 32, a semiconductor refrigerator 38 is arranged in the interiors of the cold oil tank 33, and the ports of the first temperature probe 3 and the second temperature probe 35 are electrically connected with the singlechip 16;

the hot oil tank 32 and the cold oil tank 33 are each internally provided with a stirrer 39;

when the electric heating plate 2 works, the temperature inside the hot oil tank 32 is maintained to be set high temperature by the arrangement of the electric heating rods 37;

when the electric heating plate 2 is in operation, the temperature inside the cold oil tank 33 is maintained at a set low temperature by the arrangement of the semiconductor refrigerator 38;

the semiconductor refrigerator 38 is a common component in the art and will not be described here.

The working principle of the invention is as follows: in operation of the invention, the electric heating plate 2 is used for electrically heating metal devices to be soldered, before the electric heating plate 2 works, the interiors of the hot oil tank 32 and the cold oil tank 33 are filled with quantitative oil, the temperature in the hot oil tank 32 is kept at a set high temperature through the arrangement of the electric heating rod 37, the temperature in the cold oil tank 33 is kept at a set low temperature through the arrangement of the semiconductor refrigerator 38, in an initial mode, sufficient heat conduction cold oil is injected into the oil cavity, after the heat conduction cold oil is injected, the two electromagnetic oil valves are automatically closed, when the electric heating plate 2 heats, the serpentine heating wire 10 heats the electric heating plate 2 with set power, when the serpentine heating wire 10 works, the vibrating ring 24, the reset spring 27 and the reciprocating toothed plate 26 are arranged through the arrangement of the semiconductor gear 25, the vibrating ring 24 and the reciprocating toothed plate 26, so that after the motor 23 outputs rotating speed, the vibrating ring 24 and the driving ring 11 can synchronously reciprocate in a set stroke, through the reciprocating movement of the vibration ring 24, the positions of the rotary seat 7 and the electric heating seat 9 in the rotary seat 7 can be reciprocally changed in the circumferential rotation process, the heating position of the snake-shaped heating wire 10 relative to the electric heating disc 2 is reciprocally changed through the reciprocally changed positions of the electric heating seat 9, then the uniform heating of the electric heating disc 2 is finally realized, after the snake-shaped heating wire 10 works with set power, the monitored data are fed back to the singlechip 16 in real time by the first temperature probe 3 and the second temperature probe 35, the singlechip 16 quantitatively extracts hot oil and quantitatively injects cold oil to liquid in the oil cavity by the hot oil tank 32 and the cold oil tank 33 according to the data feedback of the first temperature probe 3, and then the feedback value of the first temperature probe 3 is kept constant finally, thereby realizing the accurate temperature control of the electric heating plate 2, during the temperature control, the singlechip 16 can intelligently adjust the distance difference between the snakelike heating wire 10 and the electric heating plate 2 according to the feedback of the first temperature probe 3, and then adjust the heating efficiency of the electric heating plate 2 and the temperature control precision of the electric heating plate 2.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention.

Claims

1. The utility model provides a heating dish is brazed with temperature control mechanism, includes casing (1), its characterized in that: an electric heating disc (2) is installed at the top of casing (1), first temperature probe (3) is installed to the internally mounted of electric heating disc (2), but electric distribution ring (4) and lifting plate (5) of synchronous lift are installed through electromagnetic temperature control part to the inside of casing (1), the inner wall rotation of lifting plate (5) is connected with axle sleeve (6), the top fixed mounting of axle sleeve (6) has spiral seat (7), the guide slot (8) that a set of circumference array distributed and is connected with electric distribution ring (4) electricity have been seted up to the inside of spiral seat (7), every equal sliding connection of inner wall of guide slot (8) has electric heating seat (9), serpentine heating wire (10) are installed to the top surface of electric heating seat (9), all articulate between the opposite surfaces of axle sleeve (6) have connecting rod (12), reciprocal guide part of drive transmission ring (11) reciprocal motion is installed to the inner wall of casing (1), reciprocal guide part through the guide slot (6) is installed to the inside of guide slot (8), the inside is installed through reciprocal oil cavity (6) reciprocal oil chamber (1, the equal proportion is seted up to the inside of cooling oil chamber (1).

2. A temperature control mechanism for brazing a heating plate as recited in claim 1, wherein: the inner wall of cloth electric ring (4) has offered anodal groove (13) and negative pole groove (14) from top to bottom in proper order, every positive guide rail and a negative pole guide rail are all installed to the inner wall of guide slot (8), positive guide rail and negative pole guide rail's tail end all are connected with guide bead (15), guide bead (15) and anodal groove (13) sliding connection are passed through on positive guide rail's surface, guide bead (15) and negative pole groove (14) sliding connection are passed through on negative guide rail's surface, the positive and negative end of snakelike heating wire (10) respectively with positive guide rail and negative pole guide rail sliding connection.

3. A temperature control mechanism for brazing a heating plate as recited in claim 1, wherein: the end face of the shell (1) is fixedly provided with a singlechip (16), and the electric heating disc (2) is made of metal.

4. A temperature control mechanism for brazing a heating plate as recited in claim 1, wherein: the electromagnetic temperature control component comprises an electromagnetic ring (17) fixed on the bottom surface of the electricity distribution ring (4) and a fixed magnetic ring (18) arranged below the electromagnetic ring (17) and fixedly connected with the shell (1), a group of guide rods (19) which are distributed in a circumferential array and are slidably connected with the shell (1) are fixedly arranged on the top surface of the lifting plate (5), compression springs (20) are sleeved on the peripheral side surfaces of the guide rods (19) and correspond to the positions above the lifting plate (5), the cross section of the guide rods (19) is T-shaped, a group of electromagnetic blocks (21) which are distributed in a circumferential array are fixedly arranged on the top surface of the lifting plate (5), and fixed magnetic blocks (22) are fixedly arranged in the shell (1) and correspond to the positions of each electromagnetic block (21).

5. A temperature control mechanism for brazing a heating plate as recited in claim 4, wherein: the magnetism of the electromagnetic ring (17) after being electrified is opposite to that of the fixed magnetic ring (18), and the magnetism of the electromagnetic block (21) after being electrified is opposite to that of the fixed magnetic block (22).

6. A temperature control mechanism for brazing a heating plate as recited in claim 1, wherein: the reciprocating guide part comprises a motor (23) fixed in the shell (1) and a vibrating ring (24) rotationally connected to the peripheral side face of the transmission ring (11), a semiconductor gear (25) and a transmission bevel gear are fixedly installed at the output shaft end of the motor (23), driven bevel gears meshed with the transmission bevel gears are fixedly installed on the peripheral side face of the shaft sleeve (6), a reciprocating toothed plate (26) in transmission connection with the semiconductor gear (25) is fixedly installed on the bottom face of the vibrating ring (24), and a reset spring (27) is installed between the opposite surfaces of the transmission ring (11) and the rotary seat (7).

7. A temperature control mechanism for brazing a heating plate as recited in claim 1, wherein: the even temperature part is including rotating vortex axle (28) of being connected in electrothermal disc (2) inner wall, vortex axle (28) week side and correspond the inside position of oil pocket and install a set of stirring leaf (29) that are circumference array distribution, stirring leaf (29) are hollow structure, the week side and the axle sleeve (6) transmission of vortex axle (28) are connected and sliding fit, the liquid guide runner has been seted up to the axis position fixing of vortex axle (28), every through hole (30) have all been seted up to stirring leaf (29) inside, liquid guide runner's surface is through hole (30) and oil pocket intercommunication.

8. A temperature control mechanism for brazing a heating plate as recited in claim 7, wherein: the inside of axle sleeve (6) is fixed to be offered both ends opening and with vortex axle (28) sliding connection's axle groove, the cross section of axle groove and vortex axle (28) is regular polygon.

9. A temperature control mechanism for brazing a heating plate as recited in claim 8, wherein: the utility model provides a cold and hot oil proportioning module is including separating liquid ring (31) with conduction fluid channel rotation intercommunication respectively and be fixed in hot oil tank (32) and cold oil tank (33) of casing (1) both sides face respectively, the inside of hot oil tank (32) and cold oil tank (33) is all filled with the conduction oil, the lower part of hot oil tank (32) and cold oil tank (33) all communicates there is pump body (34), two the other end of pump body (34) all communicates with the separation liquid ring (31) is fixed through the pipeline, filter core (40) and electromagnetic oil valve have been built-in respectively to the inside of pipeline, second temperature probe (35), level gauge (36) and fluid replacement pipe are all installed to the inside of hot oil tank (32), the inside embedment of hot oil tank (32) has a set of electric heater rod (37), the internally mounted of cold oil tank (33) has semiconductor refrigerator (38), the port of first temperature probe (3), second temperature probe (35) all is connected with singlechip (16) electricity, the inside of hot oil tank (32) and cold oil tank (33) is installed with cold oil tank (39).