CN115233223A - Hot-blast auxiliary assembly of super indium of bushing pipe - Google Patents

Abstract

The invention relates to the field of ultrasonic indium coating, in particular to a liner tube ultra-indium hot air auxiliary device. The invention provides a liner tube ultra-indium hot air auxiliary device which is provided with a fixing mechanism for fixing a liner tube in a mode that a tube section is exposed for indium coating operation, and a hot air heating device for introducing hot air into an inner cavity of the liner tube to heat the liner tube. This hot-blast auxiliary assembly of super indium of bushing pipe can heat and put into its inside bushing pipe and can keep warm to the bushing pipe, and the in-process production personnel of its heating bushing pipe can directly carry out super indium operation to the bushing pipe, and super indium process is comparatively saved time, and production efficiency is higher.

Description

Hot-blast auxiliary assembly of super indium of bushing pipe

Technical Field

The invention relates to the field of ultrasonic indium coating, in particular to a liner tube ultra-indium hot air auxiliary device.

Background

Common liner tubes are made of stainless steel, and manufacturers bind multiple sections of target tubes on the outer surface of the liner tubes to prepare the rotary target material. Before the binding operation is implemented, production personnel need to implement the ultra-indium operation on the outer surface of the lining pipe. The indium operation of surpassing, the ultrasonic wave is scribbled the indium operation promptly, specifically is that the producer heats the bushing pipe to preset temperature after, uses the ultrasonic wave to scribble the indium equipment and at bushing pipe surface coating metal indium to make the bushing pipe surface form the indium layer, the indium layer can let the target pipe bind to on the bushing pipe better. In order to heat the liner tube, there is a box type heating apparatus provided with a heating wire surrounding the liner tube, the heating wire heating the liner tube put into the apparatus. After the liner tube is heated to a temperature higher than the preset temperature, a manufacturer takes the liner tube out of the box type heating device, and then ultrasonic indium coating is carried out on the outer surface of the liner tube by using the ultrasonic indium coating device, so that metal indium is coated on the outer surface of the liner tube to form an indium layer. The bushing pipe is constantly cooling because of carrying out the heat exchange with the air after being taken out, and if the producer can not in time accomplish the super indium operation of whole piece bushing pipe surface before the bushing pipe temperature drops to preset temperature, then need carry the bushing pipe into box firing equipment again and heat, and this can lead to that whole super indium process is comparatively consuming time, and production efficiency is lower.

Disclosure of Invention

The technical problem to be solved by the invention is to provide the liner tube super-indium hot air auxiliary equipment which can heat a liner tube placed in the liner tube and can preserve heat of the liner tube, and production personnel can directly carry out super-indium operation on the liner tube in the liner tube heating process, so that the super-indium process is time-saving, and the production efficiency is high.

In order to solve the problems, the invention provides an auxiliary device for ultra-indium hot air of a liner tube, which is provided with a fixing mechanism for fixing the liner tube in a way that a tube section is exposed for indium coating operation, and a hot air heating device for introducing hot air into an inner cavity of the liner tube to heat the liner tube.

The hot air heating device comprises a hot air blower capable of blowing hot air, the hot air blower is connected with an air supply hose communicated with the inner cavity of the liner tube, and the hot air is blown to the inner cavity of the liner tube through the air supply hose to be heated.

The hot air blower is also connected with a return air hose communicated with the inner cavity of the liner tube, the return air hose and the air supply hose are respectively connected with two ends of the liner tube to realize the communication with the inner cavity of the liner tube, and hot air blown out by the hot air blower is blown to the inner cavity of the liner tube through the air supply hose to be heated and then flows back to the hot air blower through the return air hose.

The fixing mechanism comprises a first clamping piece and a second clamping piece which are arranged oppositely, and the two clamping pieces are relatively close to two ends of the clamping liner tube.

Wherein, be equipped with the guide rail, first holder specifically establishes on this guide rail, moves along the guide rail and is close to the second holder, realizes that two holders are close to relatively.

The guide rail is specifically an electric linear guide rail.

Wherein the first and second clamps clamp the liner ends in a manner that allows the liner to rotate about its axis.

The first clamping piece and the second clamping piece are specifically rotary flanges, and the inner rings of the two rotary flanges axially clamp two ends of the liner tube, so that the liner tube can still rotate around the axis of the liner tube relative to the outer ring of the rotary flange in a clamped state.

The auxiliary equipment is as described above, specifically, inner ring inner holes of the two rotary flanges are respectively aligned with and communicated with two ends of the liner tube inner cavity, the return air hose and the air supply hose are respectively connected with the two rotary flanges, and the inner ring inner holes of the two rotary flanges are communicated with the liner tube inner cavity.

The device comprises a metal indium recovery groove arranged below the liner tube.

Has the advantages that: the production personnel put into the hot-blast auxiliary assembly's of super indium fixed in the fixed establishment of bushing pipe with waiting to treat the bushing pipe of super indium earlier to make hot air heater switch on the bushing pipe inner chamber, then rethread hot air heater lets in hot-blast toward the bushing pipe inner chamber, the bushing pipe is heated to preset temperature from this, afterwards, hot air heater can keep letting in hot-blast toward the bushing pipe inner chamber, make the bushing pipe temperature keep at preset temperature, in this process, the section of being heated of bushing pipe exposes all the time, production personnel can hand ultrasonic wave and scribble indium equipment and directly carry out the ultrasonic wave and scribble indium operation to bushing pipe section surface. Because hot air heating device keeps letting in hot-blast mode heat preservation bushing pipe, consequently the producer need not to carry the bushing pipe into box heating equipment again and heat again like prior art, so this super indium hot-blast auxiliary assembly of bushing pipe surpasses the indium process comparatively saves time, and production efficiency is higher.

Drawings

FIG. 1 is a schematic diagram of a structure of a liner tube ultra-indium hot air auxiliary device.

FIG. 2 is a schematic diagram of the liner tube after being installed in the liner tube super indium hot air auxiliary device.

FIG. 3 is a schematic block diagram of another view of the liner tube after installation in the liner tube super indium hot air assist apparatus.

Fig. 4 isbase:Sub>A sectional view taken alongbase:Sub>A-base:Sub>A in fig. 2.

Fig. 5 is a sectional view taken along the direction B-B in fig. 2.

Description of the symbols:

1-lining pipe ultra-indium hot air auxiliary equipment; 11-a frame; 2-an electric box; 21-air supply hose; 22-return air hose; 3-a fixing mechanism; 31-a fixed mounting frame; 311-front vent; 32-front sealing end; 321-a first vent; 33-front rotary flange; 331-a front rotary flange outer ring; 332-front rotating flange inner ring; 333-inner hole of inner ring of front rotary flange; 34-a mobile mounting frame; 341-rear vent hole; 35-rear rotating flange; 351-rear rotating the flange outer ring; 352-rear rotating flange inner ring; 353-rotating an inner hole of the inner ring of the flange at the back; 36-rear sealing the end; 361-a second vent; 4-electric linear guide rail; 5-a liner tube; 6-metal indium recovery tank.

Detailed Description

The invention is described in further detail below with reference to specific embodiments.

In order to perform the ultra-indium operation on the liner tube, in the embodiment, the liner tube to be subjected to ultra-indium operation is fixed to the auxiliary device 1 for liner tube ultra-indium hot air as shown in fig. 1, and after the auxiliary device is fixed, as shown in fig. 2, the auxiliary device 1 for liner tube ultra-indium hot air can heat the liner tube 5 fixed thereon, and a manufacturer can directly perform the ultra-indium operation on the outer surface of the heated tube section of the liner tube 5. The liner tube ultra-indium hot air auxiliary equipment 1 comprises a rack 11, an electric box 2 is installed at the front part of the rack 11, a hot air blower (not shown in the figure) capable of blowing hot air and a control circuit board (not shown in the figure) with a preset control program are installed inside the electric box 2, and the hot air blower is electrically connected with and controlled by the control circuit board.

Referring to fig. 2 and 4, a fixed mounting frame 31 mounted at the top of the rack 11 is arranged above the electric box 2, a front ventilation hole 311 penetrating through the middle of the fixed mounting frame 31 from front to back is formed in the middle of the fixed mounting frame 31, and a front sealing end 32 and a front rotating flange 33 are respectively arranged in front of and behind the front ventilation hole 311. The front sealing end 32 is bolted to the front end face of the fixed mounting frame 31 and is provided with a first vent hole 321 which is aligned with the front vent hole 311 and penetrates forwards and backwards. The front rotary flange 33 is connected with the rear end face of the fixed mounting frame 31 through a self outer ring 331 through bolts, an inner hole 333 of the self inner ring 332 is aligned with the front vent hole 311, and the inner ring 332 can rotate relative to the outer ring 331. The hot air blower is connected with an air supply hose 21, the beginning end of the air supply hose 21 is connected with the hot air blower in a sealing way, and the tail end of the air supply hose passes through the front box wall of the electric box 2 and is connected to a front sealing end 32 in a sealing way as shown in figure 3. The hot air blown by the hot air blower reaches the first vent hole 321 of the front sealing end 32 through the air supply hose 21, and then is blown backwards from the front rotating flange 33 after sequentially passing through the front vent hole 311 of the fixed mounting frame 31 and the inner hole 333 of the inner ring 332 of the front rotating flange 33.

Referring to fig. 1 and 2, two electric linear guides 4 transversely arranged in front and at back are arranged at the top of the frame 11 behind the fixed mounting frame 31, and the two electric linear guides 4 are arranged at left and right intervals and are parallel to each other. The two electric linear guide rails 4 are respectively and electrically connected with a control circuit board in the box 2, and a device arranged on the electric linear guide rails can be driven to move back and forth along the guide rails 4 under the control of the control circuit board. The two electric linear guides 4 are provided with a movable mounting rack 34 aligned with the fixed mounting rack 31, and the movable mounting rack 34 can move close to or away from the fixed mounting rack 31 along the electric linear guides 4 under the control of the control circuit board. Referring to fig. 2 and 5, the middle of the movable mounting frame 34 is provided with a rear vent hole 341 penetrating front and back, and a rear rotary flange 35 and a rear sealing end 36 are respectively arranged in front of and behind the rear vent hole 341. The rear rotating flange 35 is connected with the front end face of the movable mounting frame 34 through an outer ring 351 of the rear rotating flange 35 in a bolt mode, the rear rotating flange 33 is arranged oppositely, an inner hole 353 of an inner ring 352 of the rear rotating flange is aligned with the rear vent hole 341, and the inner ring 352 can rotate relative to the outer ring 351. The rear sealing end 36 is bolted to the rear end face of the movable mounting frame 34 and is provided with a second vent hole 361 which is aligned with the rear vent hole 341 and penetrates forward and backward. The air heater is also connected with a return air hose 22, the tail end of the return air hose 22 is connected with the air heater in a sealing mode, and the initial end of the return air hose passes through the rear box wall of the electric box 2 and is connected to a rear sealing end 36 in a sealing mode. Air can flow back into the air heater from the front of the rear rotating flange 35 through the inner hole 353 of the inner ring 352 of the rear rotating flange 35, the rear vent hole 341 of the movable mounting bracket 34, the second vent hole 361 of the rear sealing end 36 and the return air hose 22 in sequence.

When the liner 5 needs to be subjected to the ultra-indium operation, a manufacturer needs to install the liner 5 to be subjected to ultra-indium operation into the liner tube ultra-indium hot air auxiliary device 1, specifically, the manufacturer firstly sleeves the rear end of the liner 5 to be subjected to ultra-indium operation onto the inner ring 352 of the rear rotary flange 35, then controls the two electric linear guide rails 4 through the control circuit board in the electronic box 2 to drive the moving mounting rack 34 installed thereon to move forward close to the front rotary flange 33 together with the rear rotary flange 35, the liner 5, the rear sealing end 36 and the return air hose 22 hermetically connected to the rear sealing end 36 until the front end of the liner 5 is sleeved onto the inner ring 332 of the front rotary flange 33, as shown in fig. 2, the two ends of the liner 5 are axially clamped together by the inner ring 332 of the front rotary flange 33 and the inner ring 352 of the rear rotary flange 35, the axes of the front rotary flange 33, the rear rotary flange 35 and the liner 5 coincide, and the liner 5 is installed into the liner tube ultra-indium hot air auxiliary device 1. The front rotary flange 33, the fixed mounting frame 31, the rear rotary flange 35 and the movable mounting frame 34 together form a fixing mechanism 3 for clamping and fixing the liner 5.

Referring to fig. 4 and 5, after the liner 5 is installed, the front and rear ends of its inner cavity are respectively connected to the inner hole 333 of the inner ring 332 of the front rotating flange 33 and the inner hole 353 of the inner ring 352 of the rear rotating flange 35. Referring to fig. 2 and 4, a manufacturer controls the air heater to blow out hot air through the control circuit board in the electronic box 2, the hot air from the air heater sequentially passes through the air supply hose 21, the first vent hole 321 of the front sealing end 32, the front vent hole 311 of the fixed mounting frame 31, and the inner hole 333 of the inner ring 332 of the front rotating flange 33, enters the liner tube 5 from the front end of the inner cavity of the liner tube 5, and heats the liner tube 5, and then, referring to fig. 2 and 5, the hot air leaves from the rear end of the inner cavity of the liner tube 5, sequentially passes through the inner hole 353 of the inner ring 352 of the rear rotating flange 35, the rear vent hole 341 of the movable mounting frame 34, the second vent hole 361 of the rear sealing end 36, and the return air hose 22, and then is heated again by the air heater, and circulates until the liner tube 5 is heated to a preset temperature. The hot air blower, the air supply hose 21 and the return air hose 22 together constitute a hot air heating device for heating the liner pipe 5.

To reduce hot air leakage from the junction between liner tube 5 and forward rotating flange 33 and the junction between liner tube 5 and rear rotating flange 35, the manufacturer may seal the junction with a high temperature resistant sealing tape (not shown) wrapped around the junction. Then, the production personnel can leave the electric box 2, hold the ultrasonic indium coating device (not shown in the figure), and directly perform the ultrasonic indium coating operation on the outer surface of the liner tube 5 heated to the preset temperature, without taking the liner tube 5 after the heating completion out of the heating device as in the prior art to perform the ultra indium operation. In addition, in the ultra-indium process, the hot air blower keeps or intermittently introduces hot air into the inner cavity of the liner tube 5 so as to keep the temperature of the liner tube 5, and production personnel do not need to carry the liner tube into the box-type heating equipment again for heating like the prior art, so that the whole ultra-indium process of the embodiment is time-saving and has higher production efficiency. Referring to fig. 1, an indium metal recovery tank 6 with an upward notch is mounted below a liner tube 5 on a frame 11 and receives indium metal falling in a super indium process.

Referring to fig. 4 and 5, since the front end and the rear end of the liner tube 5 are axially clamped by the inner rings 332, 352 of the front rotating flange 33 and the rear rotating flange 35 together, and the inner rings 332, 352 of the two rotating flanges 33, 35 can rotate relative to the outer rings 331, 351, the liner tube 5 can still rotate around its own axis by means of the inner rings 332, 352 of the two rotating flanges 33, 35 after being clamped, and a manufacturer can manually dial the liner tube 5 when performing an ultrasonic indium coating operation on the outer surface of the liner tube 5 so as to coat indium on the outer surface of the liner tube 5 facing each direction. In other embodiments, a driving motor (not shown in the drawings) may be provided for the inner ring 332 of the front rotating flange 33 or the inner ring 352 of the rear rotating flange 35, the driving motor is electrically connected to a control circuit board in the box 2, and the control circuit board may control the driving motor to rotate the inner ring 332 of the front rotating flange 33 or the inner ring 352 of the rear rotating flange 35 around the axis during the heating process of the liner tube 5 so as to drive the liner tube 5 to rotate around the axis, thereby avoiding the trouble of manually dialing the liner tube 5 by a manufacturer. In addition, the liner tube 5 can be heated more uniformly while rotating in the heating stage.

In this embodiment, the forward and rear swivel flanges 33, 35 act as clamps that grip the liner 5, both clamps gripping both liner ends in a manner that allows the liner to rotate about its axis. In other embodiments, the clamping members may be front and rear bearings instead of the front and rear rotating flanges 33 and 35, the front and rear bearings are respectively inserted into the front ventilation holes 311 of the fixed mounting frame 31 and the rear ventilation holes 341 of the movable mounting frame 34, and both ends of the liner tube 5 are respectively inserted into the inner holes of the front and rear bearings and are clamped by the front and rear bearings in a manner of being capable of rotating around its axis.

The above description is only the embodiments of the present invention, and the scope of protection is not limited thereto. The insubstantial changes or substitutions will now be made by those skilled in the art based on the teachings of the present invention, which fall within the scope of the claims.

Claims (10)

1. The utility model provides a bushing pipe surpasses hot-blast auxiliary assembly of indium, characterized by is equipped with fixed establishment and makes the bushing pipe fix with the mode that the section of pipe exposes for carrying out the indium operation, still is equipped with hot-blast heating device and lets in hot-blast heating to the bushing pipe inner chamber.

2. The hot-blast auxiliary equipment of super indium of bushing pipe of claim 1, characterized by, hot air heating device includes the air heater that can blow out hot-blast, and the air heater connects the air supply hose who switches on the inner chamber of bushing pipe, and hot-blast blows to the inner chamber of bushing pipe through the air supply hose and heats.

3. The liner tube ultra-indium hot air auxiliary device as claimed in claim 2, wherein the hot air blower is further connected with a return air hose communicated with the inner cavity of the liner tube, the return air hose and the air supply hose are respectively connected with two ends of the liner tube to realize communication with the inner cavity of the liner tube, and hot air blown out by the hot air blower is blown into the inner cavity of the liner tube through the air supply hose to be heated and then flows back into the hot air blower through the return air hose.

4. The auxiliary equipment for liner pipe ultra-indium hot air as claimed in any one of claims 1 to 3, wherein the fixing mechanism comprises a first clamping member and a second clamping member which are oppositely arranged, and the two clamping members are relatively close to the two ends of the clamping liner pipe.

5. The liner tube ultra-indium hot air auxiliary device as claimed in claim 4, wherein a guide rail is provided, and the first clamping member is provided on the guide rail and moved along the guide rail to be close to the second clamping member, so that the two clamping members are relatively close to each other.

6. The liner tube ultra-indium hot air auxiliary device as claimed in claim 5, wherein the guide rail is a motor-driven linear guide rail.

7. The auxiliary hot blast apparatus for supplying ultra-indium to a lining pipe as claimed in claim 4 wherein the first and second clamps are adapted to clamp the ends of the lining pipe in a manner which allows the pipe to rotate about its axis.

8. The liner tube ultra-indium hot air auxiliary device as claimed in claim 7, wherein the first clamping member and the second clamping member are rotary flanges, and inner rings of the two rotary flanges axially clamp two ends of the liner tube, so that the liner tube can still rotate around its axis relative to an outer ring of the rotary flange in a clamped state.

9. The liner tube ultra-indium hot air auxiliary device as claimed in claim 8, which is characterized in that the auxiliary device is as claimed in claim 3, specifically, inner ring inner holes of the two rotating flanges are respectively aligned with and communicated with two ends of the liner tube inner cavity, the return air hose and the air supply hose are respectively connected with the two rotating flanges, and the liner tube inner cavity is communicated with the inner ring inner holes of the two rotating flanges.

10. The liner tube ultra-indium hot air auxiliary device as claimed in claim 1, comprising a metal indium recovery groove arranged below the liner tube.

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