CN113930592A

CN113930592A - Annealing device is used in tinned wire processing

Info

Publication number: CN113930592A
Application number: CN202111106167.2A
Authority: CN
Inventors: 游选波; 汪育民
Original assignee: Jiangxi Tengjiang Copper Co ltd
Current assignee: Jiangxi Tengjiang Copper Co ltd
Priority date: 2021-09-22
Filing date: 2021-09-22
Publication date: 2022-01-14

Abstract

The invention relates to an annealing device, in particular to an annealing device for processing a tinned copper wire. The utility model provides a can make the copper line be heated evenly, avoid influencing the annealing device for tinned wire processing of copper line quality. The utility model provides an annealing device is used in tinned wire processing, is equipped with the cartridge heater including frame, cartridge heater, first installation piece, first montant and diaphragm etc. upper portion in the frame, and the cartridge heater left end is located outside the frame, and both sides all are equipped with first installation piece around both ends about the cartridge heater, and the first installation piece outside all is equipped with first montant, and two portions all are equipped with the diaphragm about between two close first montants. The staff passes the heating cylinder with the copper line and heats, presss from both sides through the first fixed pulley of both sides, slowly gets into the cooling cylinder again and cools off, then pulls out from the discharge gate again, thereby reaches the purpose of annealing through processing such as intensification, heat preservation and cooling.

Description

Annealing device is used in tinned wire processing

Technical Field

The invention relates to an annealing device, in particular to an annealing device for processing a tinned copper wire.

Background

In order to soften the material of messenger's processing, change the plasticity and the toughness of material, it is convenient to carry out moulding to the material, can anneal processing to the material, annealing indicates after heating the material to the uniform temperature slowly, through the heat preservation of a certain time, then carry out a metal heat treatment process of slow cooling, at present, current annealing processing equipment is when annealing to the copper line, because the unable accurate control of temperature in the heating furnace, lead to the time inconsistent copper line before and after heating to be heated inhomogeneous, thereby influence the quality of copper line, lead to the performance difference of copper line.

Therefore, it is necessary to provide an annealing device for processing tinned copper wires, which can uniformly heat the copper wires and avoid affecting the quality of the copper wires.

Disclosure of Invention

In order to overcome the defects that the temperature in the heating furnace of the existing processing equipment cannot be accurately controlled, so that the copper wire is heated unevenly, and the quality of the copper wire is affected, the technical problems of the invention are as follows: the utility model provides a can make the copper line be heated evenly, avoid influencing the annealing device for tinned wire processing of copper line quality.

An annealing device for processing tinned wires comprises a frame, a heating cylinder, a first mounting block, a first vertical rod, a transverse plate, a first guide rail, a first slide block, a first spring, a transverse rod, a first fixed pulley, a cooling mechanism and a constant temperature mechanism, wherein the heating cylinder is arranged at the upper part in the frame, the left end of the heating cylinder is positioned outside the frame, the first mounting block is arranged at the front side and the rear side of the left end and the right end of the heating cylinder, the first vertical rod is arranged at the outer side of the first mounting block, the transverse plates are arranged at the upper part and the lower part between two adjacent first vertical rods, the first guide rail is arranged at the front side and the rear side between two adjacent transverse plates, the first slide blocks are arranged at the upper part and the lower part in the first guide rail in a sliding manner, the first spring is connected between the two adjacent first slide blocks, the transverse rod is arranged between the two corresponding front and rear first slide blocks, the first fixed pulley is rotatably arranged on the transverse rod, the cooling mechanism is arranged at the right side in the frame, a constant temperature mechanism is arranged between the cooling mechanism and the heating cylinder.

Further, the cooling mechanism comprises a cooling cylinder, an air inlet cylinder, second vertical rods, mounting plates, second guide rails, second sliding blocks, second springs and second fixed pulleys, the air inlet cylinder is arranged in the middle of the right side in the rack and penetrates through the rack, the cooling cylinder is arranged on the left side of the air inlet cylinder, the two second vertical rods are arranged on the right side of the bottom in the rack, the mounting plates are arranged on the upper portion and the lower portion of the space between the two second vertical rods, the second guide rails are arranged on the front side and the rear side of the space between the upper mounting plate and the lower mounting plate, the second sliding blocks are arranged on the upper portion and the lower portion of the space in the second guide rails in a sliding mode, the second springs are connected between the two adjacent second sliding blocks, and the second fixed pulleys are arranged between the two corresponding front sliding blocks and the rear sliding blocks in a rotating mode.

Further, the constant temperature mechanism comprises a connecting pipe, first guide sleeves, first slide bars, a third spring, a stop block and a connecting plate, the connecting pipe is connected between the left side of the cooling cylinder and the right side of the bottom of the heating cylinder, the first guide sleeves are arranged on the front side and the rear side of the lower portion of the connecting pipe, the first slide bars are arranged in the first guide sleeves in a sliding mode, the third spring is wound between the first slide bars and the adjacent first guide sleeves in a winding mode, the stop block is arranged between the bottoms of the two first slide bars and connected with the connecting pipe in a sliding mode, and the connecting plate is arranged between the tops of the two first slide bars.

The mercury-free heating device further comprises a temperature measuring mechanism, wherein the temperature measuring mechanism comprises a hollow cylinder, a piston and a connecting rod, the hollow cylinder is arranged on the right side of the heating cylinder, mercury is filled in the hollow cylinder, the upper end of the hollow cylinder is located in the heating cylinder, the piston is arranged in the hollow cylinder in a sliding mode, the connecting rod is arranged at the bottom of the piston and is connected with the hollow cylinder in a sliding mode, and the bottom of the connecting rod is connected with the connecting plate.

Further explaining, the wind power generation device further comprises a blowing mechanism, the blowing mechanism comprises a shell, a rotating shaft, blades, a rotating disc, an installation rod, a second guide sleeve, a second sliding rod, a fourth spring and a strip-shaped rail, the shell is arranged in the middle of the right side of the rack, the right end of the air inlet cylinder is located in the shell, the rotating shaft is arranged at the center of the shell in a rotating mode, the blades are arranged on the left side of the rotating shaft and located in the shell, the rotating disc is arranged on the right side of the rotating shaft, the installation rod is arranged at the eccentric position of the rotating disc, the second guide sleeve is arranged on the lower portion of the right side of the rack, the second guide sleeve is located below the shell, the second sliding rod is arranged in the second guide sleeve in a sliding mode, the fourth spring is wound between the second sliding rod and the second guide sleeve, the strip-shaped rail is arranged at the top of the second sliding rod, and is connected with the installation rod in a sliding mode.

Further explaining, the device also comprises a pushing mechanism, the pushing mechanism comprises a speed reducing motor, a roller, a pushing block and a contact block, the speed reducing motor is arranged at the lower right part of the rack, the roller is arranged on an output shaft of the speed reducing motor, the pushing block is arranged on the front side of the roller, the contact block is arranged at the bottom of the second sliding rod, and the pushing block rotates to be in contact with the contact block.

Further explaining, the limiting mechanism comprises a second mounting block, a third sliding rod, a fifth spring and a limiting block, the second mounting block is arranged at the upper part of the right side of the shell, the third sliding rod is arranged on the right side of the second mounting block in a sliding mode, the fifth spring is connected between the third sliding rod and the second mounting block in a winding mode, the limiting block is arranged at the bottom of the third sliding rod, and the mounting rod rotates to be in contact with the limiting block.

Further explaining, a discharge hole is formed in the lower right part of the rack.

Compared with the prior art, the invention has the following advantages: 1. the staff passes the heating cylinder with the copper line and heats, presss from both sides through the first fixed pulley of both sides, slowly gets into the cooling cylinder again and cools off, then pulls out from the discharge gate again, thereby reaches the purpose of annealing through processing such as intensification, heat preservation and cooling.

2. When the temperature of the heating cylinder is too high, the stop block is opened by a worker, so that cold air in the cooling cylinder enters the heating cylinder through the connecting pipe to be cooled, and the interior of the heating cylinder is in a constant temperature state.

3. The mercury in the hollow cylinder expands due to the overhigh temperature of the heating cylinder, the piston slides downwards along with the mercury, and then the stop block is opened automatically, so that the mercury can be cooled automatically when the temperature in the heating cylinder is overhigh.

4. The output shaft of gear motor rotates and drives the roller and rotate, and then carries out the rolling to the copper line after the annealing, simultaneously, also can make the blade rotate and blow in the air inlet section of thick bamboo with cold wind.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present invention.

Fig. 2 is a schematic perspective view of a second embodiment of the present invention.

Fig. 3 is a third perspective view of the present invention.

FIG. 4 is a schematic view of a first partial body structure according to the present invention.

FIG. 5 is a schematic view of a second partial body structure according to the present invention.

Fig. 6 is a schematic perspective view of the cooling mechanism of the present invention.

Fig. 7 is an enlarged perspective view of part a of the present invention.

Fig. 8 is a schematic perspective view of the thermostatic mechanism of the present invention.

FIG. 9 is a schematic perspective view of a temperature measuring mechanism according to the present invention.

Fig. 10 is a schematic perspective view of the blowing mechanism of the present invention.

Fig. 11 is a schematic perspective view of a part of the blowing mechanism of the present invention.

Fig. 12 is an enlarged perspective view of part B of the present invention.

Fig. 13 is a schematic perspective view of the pushing mechanism of the present invention.

Fig. 14 is a partial perspective view of the pushing mechanism of the present invention.

Fig. 15 is a schematic perspective view of the spacing mechanism of the present invention.

Wherein the figures include the following reference numerals: 1. frame, 2, heating cylinder, 3, first mounting block, 4, first vertical rod, 5, transverse plate, 6, first guide rail, 7, first slider, 8, first spring, 9, transverse rod, 10, first fixed pulley, 11, cooling mechanism, 111, cooling cylinder, 112, air inlet cylinder, 113, second vertical rod, 114, mounting plate, 115, second guide rail, 116, second slider, 117, second spring, 118, second fixed pulley, 12, thermostatic mechanism, 121, connecting pipe, 122, first guide sleeve, 123, first sliding rod, 124, third spring, 125, stopper, 126, connecting plate, 13, temperature measuring mechanism, 131, hollow cylinder, 132, piston, 133, connecting rod, 14, blowing mechanism, 141, housing, 142, rotating shaft, 143, blade, 144, rotating disc, 145, mounting rod, 146, second guide sleeve, 147, second sliding rod, 148, fourth spring, 149, bar-shaped rail, 15, blowing mechanism, 141, housing, 142, rotating shaft, 143, blade, 144, rotating disc, mounting rod, 146, second guide sleeve, 147, second sliding rod, 149, bar-shaped rail, and bar-shaped rail, The device comprises a pushing mechanism, 151, a speed reducing motor, 152, a roller, 153, a pushing block, 154, a contact block, 16, a limiting mechanism, 161, a second mounting block, 162, a third sliding rod, 163, a fifth spring, 164 and a limiting block.

Detailed Description

It is to be noted that, in the case of the different described embodiments, identical components are provided with the same reference numerals or the same component names, wherein the disclosure contained in the entire description can be transferred to identical components having the same reference numerals or the same component names in a meaningful manner. The positional references selected in the description, such as upper, lower, lateral, etc., refer also to the directly described and illustrated figures and are to be read into the new position in the sense of a change in position.

Example 1

An annealing device for processing tinned wires is disclosed, as shown in figures 1-8, and comprises a frame 1, a heating cylinder 2, a first mounting block 3, first vertical rods 4, transverse plates 5, first guide rails 6, first slide blocks 7, first springs 8, transverse rods 9, first fixed pulleys 10, a cooling mechanism 11 and a constant temperature mechanism 12, wherein a discharge port is formed in the lower right portion of the frame 1 for facilitating output of annealed copper wires, the heating cylinder 2 is arranged at the upper inner portion of the frame 1 and used for heating the copper wires, the left end of the heating cylinder 2 is positioned outside the frame 1, the first mounting blocks 3 are fixedly connected to the front side and the rear side of the left end and the right end of the heating cylinder 2 through bolts, the first vertical rods 4 are welded to the outer side of the first mounting blocks 3, the transverse plates 5 are arranged at the upper portion and the lower portion between the two adjacent first vertical rods 4, the first guide rails 6 are welded to the front side and the rear side of the two adjacent transverse plates 5, the first slide blocks 7 are arranged at the upper portion and the lower portion in the first guide rails 6, all be connected with first spring 8 between two close first sliders 7, all weld between two corresponding first sliders 7 around and have horizontal pole 9, and equal rotary type is equipped with first fixed pulley 10 on the horizontal pole 9, and first fixed pulley 10 is used for leading the copper line, and the right side is equipped with cooling body 11 in the frame 1, is equipped with constant temperature mechanism 12 between cooling body 11 and the cartridge heater 2.

When the device is used, a worker pushes the first sliding block 7 to slide in the first guide rail 6 in a back direction, the first spring 8 deforms, the first sliding block 7 slides in the back direction and drives the first fixed pulleys 10 to move in the back direction through the cross rod 9 and open, then the worker enables one end of a copper wire to be annealed to penetrate through the two first fixed pulleys 10 on the left side and then penetrate through the heating cylinder 2 and then penetrate through the two first fixed pulleys 10 on the right side, and then the copper wire penetrates through the cooling mechanism 11 and extends out of the discharge port of the rack 1, after the annealing is completed, the worker loosens the first sliding block 7, under the reset action of the first spring 8, the first sliding block 7 drives the first fixed pulleys 10 to move in the opposite direction through the cross rod 9 to clamp the copper wire, so that the copper wire can keep a stretched straight state in the moving process, then the worker connects an external blowing device to the cooling mechanism 11, and then slowly pulls the copper wire outwards from the discharge port, make the copper line heat through cartridge heater 2, the copper line slowly passes through the first fixed pulley 10 on right side after the heating, realizes the heat preservation of a definite time and handles, cools off in reentrant cooling body 11 to reach the purpose of annealing, at the in-process of processing, constant temperature mechanism 12 can make cartridge heater 2 keep certain temperature, and after the cooling was accomplished, the copper line through annealing process was discharged from the discharge gate, and the staff rolled up it and was collected.

The cooling mechanism 11 comprises a cooling cylinder 111, an air inlet cylinder 112, a second vertical rod 113, a mounting plate 114, a second guide rail 115, a second sliding block 116, a second spring 117 and a second fixed pulley 118, the middle part of right side is equipped with an air inlet section of thick bamboo 112 in the frame 1, an air inlet section of thick bamboo 112 is used for transmitting cold wind, an air inlet section of thick bamboo 112 passes frame 1, the welding of an air inlet section of thick bamboo 112 left side has cooling cylinder 111, cooling cylinder 111 is used for cooling the copper line, the welding of bottom right side has two second montants 113 in the frame 1, two upper and lower portions all are equipped with mounting panel 114 between two second montants 113, both sides all have welded second guide rail 115 around between two upper and lower mounting panels 114, two upper and lower portions all slidingtype are equipped with second slider 116 in the second guide rail 115, all be connected with second spring 117 between two close second sliders 116, equal rotary type is equipped with second fixed pulley 118 around between two corresponding second sliders 116, second fixed pulley 118 is used for leading to the copper line.

When the device is used, a worker penetrates a copper wire through the air inlet cylinder 112, then the second sliding block 116 is pushed to slide in the second guide rail 115 in a back-to-back mode, the second spring 117 deforms, the second sliding block 116 slides in the back-to-back mode to drive the second fixed pulley 118 to move in the back-to-back mode and open, then the worker penetrates the copper wire between the two second fixed pulleys 118 and extends out of the discharge port, after the copper wire is threaded, the worker loosens the second sliding block 116, under the reset effect of the second spring 117, the second sliding block 116 drives the second fixed pulley 118 to move in the opposite direction to clamp the copper wire, after the copper wire is threaded, the worker externally connects a blowing device to the air inlet cylinder 112, when the heated copper wire passes through the cooling cylinder 111, cold air is blown into the air inlet cylinder 112 through externally connected blowing equipment, the copper wire enters the cooling cylinder 111 to cool the copper wire, and therefore the heated copper wire can be cooled.

The thermostatic mechanism 12 comprises a connecting pipe 121, a first guide sleeve 122, a first slide bar 123, a third spring 124, a stop block 125 and a connecting plate 126, the connecting pipe 121 is connected between the left side of the cooling cylinder 111 and the right side of the bottom of the heating cylinder 2, the connecting pipe 121 is used for conveying cold air, the first guide sleeve 122 is welded on the front side and the rear side of the lower portion of the connecting pipe 121, the first slide bar 123 is arranged in the first guide sleeve 122 in a sliding mode, the third spring 124 is wound between the first slide bar 123 and the first guide sleeve 122 which is close to the first guide sleeve 123, the stop block 125 is welded between the bottoms of the two first slide bars 123, the stop block 125 is connected with the connecting pipe 121 in a sliding mode, and the connecting plate 126 is welded between the tops of the two first slide bars 123.

When the device is used, when the temperature in the heating cylinder 2 is too high, a worker pushes the connecting plate 126 to move downwards, the connecting plate 126 moves downwards to drive the first sliding rod 123 to slide downwards in the first guide sleeve 122, the third spring 124 deforms, the first sliding rod 123 slides downwards to drive the stop block 125 to slide downwards and no longer block the connecting pipe 121, at this time, cold air in the cooling cylinder 111 enters the heating cylinder 2 through the connecting pipe 121, so that the temperature in the heating cylinder 2 is reduced, when the temperature in the heating cylinder 2 is reduced to a proper temperature, the worker loosens the connecting plate 126, and under the reset action of the third spring 124, the first sliding rod 123 drives the stop block 125 to slide upwards to block the connecting pipe 121, so that the heating cylinder 2 can keep a certain temperature, and the influence on the processing quality of copper wires is avoided.

Example 2

On the basis of embodiment 1, as shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14 and fig. 15, the temperature measuring device 13 further comprises a temperature measuring mechanism 13, the temperature measuring mechanism 13 comprises a hollow cylinder 131, a piston 132 and a connecting rod 133, the hollow cylinder 131 is welded on the right side of the heating cylinder 2, mercury is filled in the hollow cylinder 131, the temperature in the heating cylinder 2 is detected through the mercury in the hollow cylinder 131, the upper end of the hollow cylinder 131 is located in the heating cylinder 2, the piston 132 is arranged in the hollow cylinder 131 in a sliding manner, the connecting rod 133 is welded at the bottom of the piston 132, the connecting rod 133 is connected with the hollow cylinder 131 in a sliding manner, and the bottom of the connecting rod 133 is connected with the connecting plate 126.

When the device is used, when the temperature in the heating cylinder 2 is too high, the mercury in the hollow cylinder 131 expands, so that the extrusion piston 132 slides downwards, the piston 132 slides downwards to drive the connecting plate 126 to move downwards through the connecting rod 133, the connecting pipe 121 is not blocked by the stopper 125 due to downward sliding, the heating cylinder 2 is cooled, after the temperature in the heating cylinder 2 drops, the mercury in the hollow cylinder 131 contracts, the piston 132 drives the connecting rod 133 to move upwards, the connecting pipe 121 is blocked by the stopper 125 due to upward sliding, and therefore the temperature can be automatically cooled when the temperature in the heating cylinder 2 is too high.

Also comprises a blowing mechanism 14, the blowing mechanism 14 comprises a shell 141, a rotating shaft 142, blades 143 and a turntable 144, the air conditioner comprises a mounting rod 145, a second guide sleeve 146, a second slide rod 147, a fourth spring 148 and a strip-shaped rail 149, wherein a shell 141 is welded in the middle of the right side of the rack 1, the right end of the air inlet drum 112 is located in the shell 141, a rotating shaft 142 is rotatably arranged at the center of the shell 141, blades 143 are arranged on the left side of the rotating shaft 142 and used for blowing cold air into the air inlet drum 112, the blades 143 are located in the shell 141, a rotating disc 144 is arranged on the right side of the rotating shaft 142, the mounting rod 145 is welded at the eccentric position of the rotating disc 144, a second guide sleeve 146 is welded at the lower portion of the right side of the rack 1, the second guide sleeve 146 is located below the shell 141, a second slide rod 147 is slidably arranged in the second guide sleeve 146, the fourth spring 148 is wound between the second slide rod 147 and the second guide sleeve 146, the strip-shaped rail 149 is welded at the top of the second slide rod 147, and the mounting rod 145 is slidably connected.

The device is characterized by further comprising a pushing mechanism 15, wherein the pushing mechanism 15 comprises a speed reducing motor 151, a roller 152, a pushing block 153 and a contact block 154, the speed reducing motor 151 is arranged at the lower right portion of the rack 1, the speed reducing motor 151 is used for providing power for the device, the roller 152 is connected to an output shaft of the speed reducing motor 151, the pushing block 153 is arranged on the front side of the roller 152, the contact block 154 is welded to the bottom of the second sliding rod 147, and the pushing block 153 rotates to be in contact with the contact block 154.

The limiting mechanism 16 comprises a second mounting block 161, a third sliding rod 162, a fifth spring 163 and a limiting block 164, the second mounting block 161 is welded to the upper portion of the right side of the shell 141, the third sliding rod 162 is arranged on the right side of the second mounting block 161 in a sliding mode, the fifth spring 163 is connected between the third sliding rod 162 and the second mounting block 161 in a winding mode, the limiting block 164 is welded to the bottom of the third sliding rod 162, the limiting block 164 is used for limiting the mounting rod 145, and the mounting rod 145 rotates to be in contact with the limiting block 164.

When the device is used, a worker sleeves a bobbin for winding a copper wire on a roller 152, then winds one end of the copper wire on the bobbin, after the completion, the worker starts a speed reducing motor 151, an output shaft of the speed reducing motor 151 rotates to drive the roller 152 to rotate, further, the copper wire is wound up through the bobbin, the roller 152 rotates and simultaneously drives a pushing block 153 to rotate, when the pushing block 153 rotates to be in contact with a contact block 154, the pushing block 153 rotates to extrude the contact block 154 to move upwards, the contact block 154 moves upwards to move a second sliding rod 147 to slide upwards, a fourth spring 148 deforms, the second sliding rod 147 slides upwards to drive a strip-shaped rail 149 to move upwards, the strip-shaped rail 149 moves upwards to drive a mounting rod 145 to rotate, the mounting rod 145 rotates to drive a rotary disc 144 to rotate, the rotary disc 144 rotates to drive blades 143 to rotate through a rotary shaft 142, the blades 143 blow cold air into an air inlet cylinder 112, and cool the copper wire in a cooling cylinder 111, when the mounting rod 145 rotates to contact with the limiting block 164, the mounting rod 145 rotates to press the limiting block 164 to move upwards, the limiting block 164 moves upwards to drive the third sliding rod 162 to slide upwards, the fifth spring 163 deforms, after the mounting rod 145 rotates to be separated from the limiting block 164, under the reset action of the fifth spring 163, the third sliding rod 162 drives the limiting block 164 to move downwards to reset, at this time, the mounting rod 145 is located at the rear side of the limiting block 164, after the pushing block 153 rotates to be separated from the contact block 154, under the reset action of the fourth spring 148, the second sliding rod 147 drives the bar-shaped rail 149 to move downwards, the bar-shaped rail 149 moves downwards to drive the mounting rod 145 to continue rotating, at this time, under the action of the limiting block 164, the mounting rod 145 does not rotate reversely to reset, the mounting rod 145 continues to rotate so that the blades 143 continue to rotate to blow air, and after the pushing block 153 rotates again to be in contact with the contact block 154, repeating above-mentioned action makes blade 143 constantly rotate and blows in cold wind into air inlet section of thick bamboo 112, and after the equipment usage was accomplished, the staff closed gear motor 151, so, can stimulate the copper line automatically and outwards remove, simultaneously, also can cool off the copper line after the heating automatically, no longer need staff external device to operate.

The technical principle of the embodiment of the present invention is described above in conjunction with the specific embodiments. The description is only intended to explain the principles of embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive step, and these embodiments will fall within the scope of the present invention.

Claims

1. The utility model provides an annealing device is used in tinned wire processing which characterized by: comprises a frame (1), a heating cylinder (2), first mounting blocks (3), first vertical rods (4), transverse plates (5), first guide rails (6), first sliding blocks (7), first springs (8), transverse rods (9), first fixed pulleys (10), a cooling mechanism (11) and a constant temperature mechanism (12), wherein the heating cylinder (2) is arranged at the upper part in the frame (1), the left end of the heating cylinder (2) is positioned outside the frame (1), the first mounting blocks (3) are arranged at the front side and the rear side of the left end and the right end of the heating cylinder (2), the first vertical rods (4) are arranged at the outer side of each first mounting block (3), the transverse plates (5) are arranged at the upper part and the lower part between the two adjacent first vertical rods (4), the first guide rails (6) are arranged at the front side and the rear side between the two adjacent transverse plates (5), the first sliding blocks (7) are arranged at the upper part and the lower part in the first guide rails (6) in a sliding manner, and the first springs (8) are connected between the two adjacent first sliding blocks (7), all be equipped with horizontal pole (9) between two corresponding first slider (7) in front and back, equal rotary type is equipped with first fixed pulley (10) on horizontal pole (9), and the right side is equipped with cooling body (11) in frame (1), is equipped with constant temperature mechanism (12) between cooling body (11) and heating cylinder (2).

2. The annealing device for processing the tinned copper wire according to claim 1, which is characterized in that: the cooling mechanism (11) comprises a cooling cylinder (111), an air inlet cylinder (112), a second vertical rod (113), a mounting plate (114), a second guide rail (115), a second sliding block (116), a second spring (117) and a second fixed pulley (118), the air inlet cylinder (112) is arranged in the middle of the right side in the rack (1), the air inlet cylinder (112) penetrates through the rack (1), the cooling cylinder (111) is arranged on the left side of the air inlet cylinder (112), two second vertical rods (113) are arranged on the right side of the bottom in the rack (1), mounting plates (114) are arranged on the upper portion and the lower portion of the two second vertical rods (113), second guide rails (115) are arranged on the front side and the rear side of the two upper and lower mounting plates (114), second sliding blocks (116) are arranged on the upper portion and the lower portion of the second guide rails (115) in an all sliding mode, second springs (117) are connected between the two adjacent second sliding blocks (116), and second fixed pulleys (118) are arranged between the two front and rear corresponding second sliding blocks (116) in an all rotating mode.

3. The annealing device for processing the tinned copper wire according to claim 2, which is characterized in that: the constant temperature mechanism (12) comprises a connecting pipe (121), a first guide sleeve (122), a first sliding rod (123), a third spring (124), a stop block (125) and a connecting plate (126), the connecting pipe (121) is connected between the left side of the cooling cylinder (111) and the right side of the bottom of the heating cylinder (2), the first guide sleeve (122) is arranged on the front side and the rear side of the lower portion of the connecting pipe (121), the first sliding rod (123) is arranged in the first guide sleeve (122) in a sliding mode, the third spring (124) is wound between the first sliding rod (123) and the first guide sleeve (122) which is close to the first guide sleeve (123), the stop block (125) is arranged between the bottoms of the two first sliding rods (123), the stop block (125) is connected with the connecting pipe (121) in a sliding mode, and the connecting plate (126) is arranged between the tops of the two first sliding rods (123).

4. The annealing device for processing the tinned copper wire according to claim 3, which is characterized in that: the temperature measuring device is characterized by further comprising a temperature measuring mechanism (13), wherein the temperature measuring mechanism (13) comprises a hollow cylinder (131), a piston (132) and a connecting rod (133), the right side of the heating cylinder (2) is provided with the hollow cylinder (131), mercury is filled in the hollow cylinder (131), the upper end of the hollow cylinder (131) is located in the heating cylinder (2), the hollow cylinder (131) is internally provided with the piston (132) in a sliding mode, the bottom of the piston (132) is provided with the connecting rod (133), the connecting rod (133) is connected with the hollow cylinder (131) in a sliding mode, and the bottom of the connecting rod (133) is connected with the connecting plate (126).

5. The annealing device for processing the tinned copper wire according to claim 4, which is characterized in that: the air blowing device is characterized by further comprising an air blowing mechanism (14), wherein the air blowing mechanism (14) comprises a shell (141), a rotating shaft (142), blades (143), a rotary disc (144), a mounting rod (145), a second guide sleeve (146), a second sliding rod (147), a fourth spring (148) and a strip-shaped rail (149), the shell (141) is arranged in the middle of the right side of the rack (1), the right end of the air inlet cylinder (112) is located in the shell (141), the rotating shaft (142) is rotatably arranged at the center of the shell (141), the blades (143) are arranged on the left side of the rotating shaft (142), the blades (143) are located in the shell (141), the rotary disc (144) is arranged on the right side of the rotating shaft (142), the mounting rod (145) is arranged at an eccentric position of the rotary disc (144), the second guide sleeve (146) is arranged on the lower portion of the right side of the rack (1), the second guide sleeve (146) is located below the shell (141), the second sliding-type second sliding rod (147) is arranged in the second guide sleeve (146), a fourth spring (148) is wound between the second sliding rod (147) and the second guide sleeve (146), a strip-shaped rail (149) is arranged at the top of the second sliding rod (147), and the strip-shaped rail (149) is connected with the mounting rod (145) in a sliding manner.

6. The annealing device for processing the tinned copper wire according to claim 5, which is characterized in that: the automatic pushing device is characterized by further comprising a pushing mechanism (15), wherein the pushing mechanism (15) comprises a speed reducing motor (151), a roller (152), a pushing block (153) and a contact block (154), the speed reducing motor (151) is arranged on the lower right portion of the rack (1), the roller (152) is arranged on an output shaft of the speed reducing motor (151), the pushing block (153) is arranged on the front side of the roller (152), the contact block (154) is arranged at the bottom of the second sliding rod (147), and the pushing block (153) rotates to be in contact with the contact block (154).

7. The annealing device for processing the tinned copper wire according to claim 6, which is characterized in that: still including stop gear (16), stop gear (16) are including second installation piece (161), third slide bar (162), fifth spring (163) and stopper (164), shell (141) right side upper portion is equipped with second installation piece (161), second installation piece (161) right side slidingtype is equipped with third slide bar (162), it has fifth spring (163) to wind between third slide bar (162) and second installation piece (161), third slide bar (162) bottom is equipped with stopper (164), installation pole (145) rotate with stopper (164) contact.

8. The annealing device for processing the tinned copper wire according to claim 7, which is characterized in that: the right lower part of the frame (1) is provided with a discharge hole.