CN211367676U - Annealing cooling device of copper-clad aluminum wire - Google Patents

Abstract

The utility model relates to an annealing cooling device of copper clad aluminum wire, it includes open-top's cooler bin, the top of cooler bin is fixed with two first fixed blocks, first fixed block sets up, two along the direction of motion of copper clad aluminum wire a plurality of first through-holes have all been seted up to one side of first fixed block, the inside second fixed block that is provided with of cooler bin, the second through-hole has been seted up to one side of second fixed block, the second fixed block with first fixed block parallels, wear to be equipped with the water level control subassembly on the cooler bin. The utility model relates to a copper clad aluminum wire annealing cooling arrangement's technical field. The utility model discloses have the inside water level of automatically regulated cooler bin, can rapid cooling, guarantee the annealing effect of product, further improve the internal stress of copper clad aluminum wire, reduce the effect of company's recruitment cost.

Description

Annealing cooling device of copper-clad aluminum wire

Technical Field

The utility model belongs to the technical field of the technique of copper clad aluminum wire annealing cooling arrangement and specifically relates to an annealing cooling device of copper clad aluminum wire is related to.

Background

The copper-clad aluminum wire is an electric wire which takes an aluminum core wire as a main body and is plated with a copper layer with a certain proportion on the outer surface, and can be used as a conductor for a coaxial cable and a conductor for an electric wire and a cable in electric equipment. The aluminum wire has small specific gravity, but the welding performance is not good, so the copper-clad aluminum wire can utilize the advantage of small specific gravity of aluminum and improve the welding performance by wrapping a copper layer outside the aluminum wire. The method is suitable for the industries of electric power and electric appliances, and the category grade is international and domestic.

The copper-clad aluminum wire is cooled, the water level in the cooling box has certain requirements, and when the water level is too high, more water is brought out of the cooling box by the copper-clad aluminum wire, so that hydrology is not easy to remove. When the water level is too low, the part of the copper-clad aluminum wire immersed in the water is less, the cooling time is short, and the cooling result is influenced. The water is added by adopting an artificial mode generally in the prior art.

SUMMERY OF THE UTILITY MODEL

According to the deficiency that prior art exists, the utility model aims at providing an annealing cooling device of copper clad aluminum wire has the inside water level of automatically regulated cooler bin, reduces the effect of company's recruitment cost.

The above technical purpose of the present invention can be achieved by the following technical solutions:

the annealing and cooling device for the copper-clad aluminum wire comprises a cooling box with an opening at the top, wherein two first fixed blocks are fixed at the top of the cooling box, the first fixed blocks are arranged along the movement direction of the copper-clad aluminum wire, a plurality of first through holes are formed in one side of each of the two first fixed blocks, a second fixed block is arranged in the cooling box, a second through hole is formed in one side of the second fixed block, the second fixed block is parallel to the first fixed block, and a water level adjusting assembly is arranged on the cooling box in a penetrating manner;

the water level adjusting assembly comprises a first water tank, a first guide rod, a floating plate and a baffle plate, wherein a third through hole is formed in one side of the cooling box, the first water tank is fixed to one side of the cooling box where the third through hole is located, the distance from the third through hole to the bottom of the inner wall of the cooling box is 1.3-1.5 times that from the second fixed block to the bottom of the inner wall of the cooling box, the first water tank is close to the lower half portion of one side of the cooling box, a fourth through hole is formed in the lower half portion of the one side of the first water tank, the fourth through hole is coincided with the third through hole, one end of the first guide rod is fixed to the bottom of the inner wall of the cooling box, the floating plate is sleeved on the outer peripheral surface of the first guide rod in a sliding mode, the baffle plate is fixed to one side, close to the third through.

Through adopting above-mentioned technical scheme, when the inside water level of cooler bin descends, the kickboard changes along with water level altitude variation, and the kickboard drives the shielding plate motion, and in the shielding plate motion process, the third through-hole shows gradually, and inside water of first water tank flows into the cooler bin through fourth through-hole and third through-hole, makes the inside water level altitude of cooler bin rise, and along with water level altitude variation, the kicking block upward movement, the kicking block drives the shielding plate upward movement, and the shielding plate shelters from the third through-hole gradually. When the baffle plate completely shields the third through hole, water in the first water tank cannot flow into the cooling tank any more, so that the device has the purpose of automatically adjusting the water level in the cooling tank.

The present invention may be further configured in a preferred embodiment as: two first fixed plates of cooler bin inner wall one side fixedly connected with, two first fixed plate along the width direction of cooler bin is arranged, two first spout has all been seted up to the relative one side of first fixed plate, first spout along the direction of height setting of cooler bin, the both ends of kickboard all extend to inside the first spout, just the kickboard with first spout looks adaptation.

Through adopting above-mentioned technical scheme, first fixed plate and first spout have further guaranteed that the kickboard is at the in-process of up-and-down motion, and the motion position of kickboard can not change, and then has ensured that the shielding plate contacts with cooling box inner wall one side always.

The present invention may be further configured in a preferred embodiment as: the first guide rod is far away from one end of the bottom of the inner wall of the cooling box is welded with a limiting plate, and the limiting plate is located inside the cooling box.

Through adopting above-mentioned technical scheme, the limiting plate avoids kickboard and first guide arm to break away from the contact.

The present invention may be further configured in a preferred embodiment as: an observation hole is formed in one side, far away from the cooling box, of the first water tank, and a transparent observation plate is fixedly arranged in the observation hole.

Through adopting above-mentioned technical scheme, operating personnel can observe the inside water level of first water tank through the observation hole, in time to adding water to first water tank is inside.

The present invention may be further configured in a preferred embodiment as: one side of the floating plate close to the bottom of the inner wall of the cooling box is fixedly connected with a spring, the other end of the spring is fixed with the bottom of the inner wall of the cooling box, and the spring is wound on the outer peripheral surface of the first guide rod.

Through adopting above-mentioned technical scheme, the spring guarantees that when the inside water level of cooler bin descends, the kickboard is timely along with the water level change and change.

The present invention may be further configured in a preferred embodiment as: the cooling box is characterized in that fixed blocks are fixed on two sides of the inner wall of the cooling box, threaded holes are formed in the tops of the fixed blocks, two fifth through holes are formed in the top of the second fixed block, and the positions and the shapes of the fifth through holes correspond to those of the threaded holes.

Through adopting above-mentioned technical scheme, the second fixed block of being convenient for operating personnel installation and dismantlement.

The present invention may be further configured in a preferred embodiment as: the lower half part of one side of the cooling box is provided with a water outlet pipe, the interior of the water outlet pipe is communicated with the interior of the cooling box, and a valve is arranged on the water outlet pipe.

Through adopting above-mentioned technical scheme, operating personnel comes in time to clear up the inside water of cooler bin through control flap. The inside of the cooling box is cleaned conveniently by operators.

To sum up, the utility model discloses a following at least one useful technological effect:

1. through cooler bin, first fixed block, second fixed block, first water tank, first guide arm, kickboard and shielding plate etc. can realize device self water level control, reduce the purpose of company's recruitment cost.

2. The first fixing plate, the floating plate, the first guide rod and the like prevent the movement track of the floating plate from deviating.

Drawings

Fig. 1 is a schematic view of the overall structure of the present embodiment.

Fig. 2 is a schematic view of the half-section structure of fig. 1.

Fig. 3 is a schematic half-sectional view of the second fixing block and the fixing block in fig. 1.

In the figure, 1, a cooling tank; 11. a first fixed block; 12. a first through hole; 2. a second fixed block; 21. a second through hole; 3. a water level adjustment assembly; 31. a first water tank; 32. a first guide bar; 33. a floating plate; 34. a shielding plate; 4. a third through hole; 311. a fourth via hole; 5. a first fixing plate; 51. a first chute; 321. a limiting plate; 312. an observation hole; 313. a transparent viewing plate; 6. a spring; 7. a fixed block; 71. a threaded hole; 72. a fifth through hole; 8. a water outlet pipe; 9. and (4) a valve.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example (b):

referring to fig. 1, the utility model discloses an annealing cooling device of copper clad aluminum wire, including open-top's cooler bin 1. Cooling water is placed in the cooling box 1, and the copper clad aluminum wire is cooled in the cooling box 1. In order to determine the moving path of the copper-clad aluminum wire. Two first fixing blocks 11 are fixed at the top of the cooling box 1, the two fixing blocks 7 are arranged along the moving direction of the copper-clad aluminum wire, and the direction of the first fixing blocks 11 is perpendicular to the moving direction of the copper-clad aluminum wire. In addition, a second fixed block 2 is movably arranged in the cooling box 1, and the second fixed block 2 is parallel to the first fixed block 11. Second through-hole 21 has been seted up to one side of second fixed block 2, and five second through-holes 21 have all been seted up to one side of two first fixed blocks 11. The second through hole 21 corresponds in position to the first through hole 12. The copper-clad aluminum wire passes through the first through hole 12 and the second through hole 21.

Referring to fig. 3, in order to facilitate the operator to disassemble and assemble the second fixing block 2, the fixing blocks 7 are welded on both sides of the inner wall of the cooling box 1 (see fig. 1), the top of each fixing block 7 is provided with a threaded hole 71, the top of the second fixing block 2 is provided with a fifth through hole 72, and the position and the shape of the fifth through hole 72 correspond to those of the threaded hole 71. An operator can fix the second fixing block 2 to the fixing block 7 by only using bolts to pass through the fifth through holes 72 and the threaded holes 71.

Referring to fig. 2, the water level inside the cooling tank 1 is self-regulated. A water level adjusting assembly 3 (see fig. 1) is inserted into the cooling tank 1. The water level regulating assembly 3 includes a first water tank 31, a first guide rod 32, a floating plate 33, and a shielding plate 34. Third through hole 4 has been seted up to one side of cooler bin 1, and the welding of first water tank 31 is in one side of cooler bin 1, and fourth through-hole 311 has been seted up to one side that first water tank 31 and cooler bin 1 laminated mutually, and fourth through-hole 311 and the laminating of third through hole 4 mutually. The distance from the third through hole 4 to the bottom of the inner wall of the cooling box 1 is 1.3-1.5 times, preferably 1.3 times, the distance from the second fixing block 2 to the bottom of the inner wall of the cooling box 1. Therefore, a section of the copper-clad aluminum wire in the cooling box 1 is completely positioned in the cooling box 1. One end of the first guide rod 32 is welded at the bottom of the inner wall of the cooling box 1, the floating plate 33 is slidably sleeved on the outer peripheral surface of the first guide rod 32, and the shielding plate 34 is connected with the floating plate 33 through screws. One side of the shielding plate 34 is attached to the side wall of the third through hole 4. The floating plate 33 changes along with the change of the water level inside the cooling box 1, when the water level inside the cooling box 1 decreases, the height of the floating plate 33 inside the cooling box 1 also decreases, the floating plate 33 drives the shielding plate 34 to move, and the shielding plate 34 moves. The third through hole 4 is gradually exposed, and the water in the first water tank 31 flows into the cooling tank 1 through the fourth through hole 311 and the third through hole 4, so as to supplement the cooling water to the inside of the cooling tank 1 in time. As the water inside the first water tank 31 enters the cooling tank 1, the water level inside the cooling tank 1 rises, and the floating plate 33 rises accordingly. The floating plate 33 moves the shielding plate 34. The third through hole 4 is blocked by the blocking plate 34. At this time, the water inside the first water tank 31 does not flow into the inside of the cooling tank 1 any more.

Referring to fig. 2, in order to ensure that the floating plate 33 does not deviate in the moving track during the moving process. Two first fixing plates 5 are welded inside the cooling box 1, the two first fixing plates 5 are arranged along the width direction of the cooling box 1, first sliding grooves 51 are formed in opposite sides of the two first fixing plates 5, and the linear direction of the first sliding grooves 51 is parallel to the linear direction of the first guide rods 32. Both ends of the floating plate 33 extend into the first sliding groove 51, and the floating plate 33 is adapted to the width of the first sliding groove 51.

Referring to fig. 2, in order to prevent the floating plate 33 from coming out of contact with the first guide bar 32, a limit plate 321 is welded to an end of the first guide bar 32 away from the bottom of the inner wall of the cooling box 1.

Referring to fig. 1, in order to observe the amount of water in the first water tank 31, water is added to the first water tank 31 in time. An observation hole 312 is formed in one side of the first water tank 31, which is far away from the cooling tank 1, a transparent observation plate 313 is fixedly connected to glue inside the observation hole 312, and the transparent observation plate 313 can be transparent glass.

Referring to fig. 1, in order to increase the sensitivity of the floating plate 33, when the water level inside the cooling tank 1 is lowered, the floating plate 33 moves along with the water level in time. The outer peripheral surface of the first guide rod 32 is wound with a spring 6, one end of the spring 6 is fixed with the floating plate 33, and the other end of the spring 6 is fixed with the bottom of the inner wall of the cooling box 1. It is particularly noted that the spring 6 has a greater length than the first guide bar 32, and the elastic restoring force of the spring 6 is less than the buoyancy to which the floating plate 33 is subjected.

Referring to fig. 1, water inside the cooling tank 1 is drained quickly and promptly. A water outlet pipe 8 is arranged on one side of the cooling box 1, and the interior of the water outlet pipe 8 is communicated with the interior of the cooling box 1. In order to control whether the interior of the water outlet pipe 8 is smooth or not, a valve 9 is arranged on the water outlet pipe 8.

The implementation principle of the above embodiment is as follows: and the copper-clad aluminum wire passes through a through hole in the first fixing block 11 on the left side of the cooling box 1, a second shell of the second fixing block 2 in the cooling box 1 and a first through hole 12 in the first fixing block 11 on the right side of the cooling box 1 at one time.

Next, the operator inputs cooling water into the cooling tank 1, and as the amount of cooling water increases, the water level in the cooling tank 1 starts to change, and the floating plate 33 also moves upward along the linear direction of the first guide rod 32. The floating plate 33 drives the shielding plate 34 to move, and when the shielding plate 34 completely shields the third through hole 4 and the second fixing block 2 is located inside the cooling water, the water is stopped from being added into the cooling tank 1.

When the cooling box 1 is operated for a period of time, the water level inside the cooling box 1 is lowered, and the floating plate 33 drives the shielding plate 34 to move downward along the linear direction of the first guide rod 32. At this time, the third through hole 4 is gradually exposed, and the water in the inner wall of the first water tank 31 flows into the cooling tank 1 through the fourth through hole 311 and the third through hole 4.

Further, as the water in the first water tank 31 enters the cooling tank 1, the water level in the cooling tank 1 rises, the floating plate 33 drives the shielding plate 34 to move upward, the shielding plate 34 gradually covers the third through hole 4, and at this time, the water in the first water tank 31 cannot flow into the cooling tank 1. By this, the device completes the operation of self-adjusting the water level.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (7)

1. The utility model provides an annealing cooling device of copper clad aluminum wire, includes open-top's cooler bin (1), the top of cooler bin (1) is fixed with two first fixed blocks (11), first fixed block (11) set up along the direction of motion of copper clad aluminum wire, two a plurality of first through-holes (12) have all been seted up to one side of first fixed block (11), cooler bin (1) inside is provided with second fixed block (2), second through-hole (21) have been seted up to one side of second fixed block (2), second fixed block (2) with first fixed block (11) parallel, its characterized in that: a water level adjusting component (3) penetrates through the cooling box (1);

the water level adjusting assembly (3) comprises a first water tank (31), a first guide rod (32), a floating plate (33) and a baffle plate (34), a third through hole (4) is formed in one side of the cooling tank (1), the first water tank (31) and one side of the cooling tank (1) where the third through hole (4) is located are fixed, the distance from the third through hole (4) to the bottom of the inner wall of the cooling tank (1) is 1.3-1.5 times of the distance from the second fixing block (2) to the bottom of the inner wall of the cooling tank (1), a fourth through hole (311) is formed in one side, close to the cooling tank (1), of the first water tank (31), the fourth through hole (311) is overlapped with the third through hole (4), one end of the first guide rod (32) is fixed to the bottom of the inner wall of the cooling tank (1), and the floating plate (33) is sleeved on the outer peripheral face of the first guide rod (32) in a sliding mode, the baffle (34) is fixed with one side, close to the third through hole (4), of the floating plate (33), and the baffle (34) is attached to the side wall where the third through hole (4) is located.

2. The annealing cooling device for copper-clad aluminum wires according to claim 1, characterized in that: two first fixed plates (5), two of cooler bin (1) inner wall one side fixedly connected with first fixed plate (5) are along the width direction of cooler bin (1) is arranged, two first spout (51) have all been seted up to the relative one side of first fixed plate (5), first spout (51) are along the direction of height setting of cooler bin (1), the both ends of kickboard (33) all extend to inside first spout (51), just kickboard (33) with first spout (51) looks adaptation.

3. The annealing cooling device for copper-clad aluminum wires according to claim 1, characterized in that: one end of the first guide rod (32) far away from the bottom of the inner wall of the cooling box (1) is welded with a limiting plate (321), and the limiting plate (321) is located inside the cooling box (1).

4. The annealing cooling device for copper-clad aluminum wires according to claim 1, characterized in that: an observation hole (312) is formed in one side, far away from the cooling box (1), of the first water tank (31), and a transparent observation plate (313) is fixedly arranged inside the observation hole (312).

5. The annealing cooling device for copper-clad aluminum wires according to claim 1, characterized in that: one side, close to the bottom of the inner wall of the cooling box (1), of the floating plate (33) is fixedly connected with a spring (6), the other end of the spring (6) is fixed to the bottom of the inner wall of the cooling box (1), and the spring (6) is wound on the outer peripheral surface of the first guide rod (32).

6. The annealing cooling device for copper-clad aluminum wires according to claim 1, characterized in that: both sides of the inner wall of the cooling box (1) are fixed with fixing blocks (7), threaded holes (71) are formed in the tops of the fixing blocks (7), two fifth through holes (72) are formed in the top of the second fixing block (2), and the positions and the shapes of the fifth through holes (72) correspond to those of the threaded holes (71).

7. The annealing cooling device for copper-clad aluminum wires according to claim 1, characterized in that: the lower half part of one side of the cooling box (1) is provided with a water outlet pipe (8), the interior of the water outlet pipe (8) is communicated with the interior of the cooling box (1), and a valve (9) is arranged on the water outlet pipe (8).

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