CN108067806B - Iron tip cleaner for soldering iron - Google Patents

Abstract

A tip cleaner for a soldering iron, which can be continuously used for a long time by preventing a flux residue peeled off from a tip of the soldering iron from being intensively accumulated on a certain portion. A soldering iron tip cleaner has a cleaner cartridge (10), a first nozzle hole (12), and a second nozzle hole (13), the cleaner cartridge (10) having insertion holes (32, 33) on an upper face for inserting a soldering iron tip (1a) of a soldering iron (1); the first nozzle hole (12) is opened in the cleaner case (10) and the solder slag adhered to the soldering iron tip (1a) of the soldering iron (1) is peeled off by the air injection; the second nozzle hole (13) is opened in the cleaner case (10), the falling direction of the brazing flux peeled from the iron tip (1a) is changed by the air injection, and the second nozzle hole (13) is formed by a horizontally elongated long hole and injects air in a horizontally elongated plane shape.

Description

Iron tip cleaner for soldering iron

Technical Field

The present invention relates to a tip cleaner for soldering iron, which removes solder slag adhering to a tip of a soldering iron by blowing air to clean the tip.

Background

Such a tip cleaner is known, for example, as disclosed in patent document 1. A known iron tip cleaner is configured such that an elongated cylindrical nozzle hole having a jet port at a distal end thereof is attached to a cleaner case having a box shape in such a posture that the jet port is located inside the cleaner case, and air is jetted from the jet port to an iron tip of a soldering iron inserted into the cleaner case so as to blow off and remove solder slag adhering to the iron tip. The tip cleaner is attached to an automatic soldering apparatus, and is used to periodically clean the tip of a soldering iron during a soldering operation.

When the tip of the soldering iron is cleaned, the solder slag blown off from the tip of the soldering iron by air is scattered in the cleaner case and adheres to the side wall, the bottom wall, and the like, but most of the solder slag intensively drops to a certain portion of the bottom wall of the cleaner case by the regular flow of air from the nozzle hole and the weight of the solder slag, and gradually accumulates in a columnar shape. The height of the column due to the deposition of the solder slag is so high that the column eventually comes into contact with the iron tip when the iron tip is cleaned, and the column adheres to the iron tip again. Therefore, the conventional iron tip cleaner must frequently discharge the accumulated solder slag in a short time, and is difficult to continuously use for a long time.

Prior art documents

Patent document

Patent document 1: japanese patent laid-open publication No. 2004-344920

Disclosure of Invention

Problems to be solved by the invention

The technical subject of the invention is to provide a soldering iron tip cleaner which can be continuously used for a long time by preventing the solder slag stripped from the soldering iron tip of the soldering iron from being intensively accumulated on a certain position.

Means for solving the problems

The iron tip cleaner of the present invention is characterized in that the iron tip cleaner has a cleaner cartridge having an insertion hole on an upper face for inserting an iron tip of an soldering iron; the first nozzle hole is opened in the cleaner case, and the solder slag adhered to the tip of the soldering iron is peeled off by the air injection; the second nozzle hole is opened in the cleaner case, and changes the dropping direction of the brazing flux peeled from the iron tip by air injection, and the second nozzle hole is formed of a horizontally elongated long hole and injects air in a horizontally elongated planar shape.

In the present invention, it is desirable that the second nozzle hole has a gradually tapered hole width, and that the second nozzle hole is disposed below the first nozzle hole.

According to a specific configuration of the present invention, a nozzle member is housed inside the cleaner cartridge, and the first nozzle hole and the second nozzle hole are provided in the nozzle member.

In this case, it is desirable that the injection angle of the air from the first nozzle hole and the second nozzle hole can be changed by changing the posture of the nozzle member.

According to another specific configuration of the present invention, the outer cap and the inner cap are provided in two layers on the upper surface of the cleaner case, and insertion holes for inserting the tip of the soldering iron are formed in the outer cap and the inner cap, respectively, and the opening area of the second insertion hole formed in the inner cap is smaller than the opening area of the first insertion hole formed in the outer cap.

In this case, it is desirable that the first insertion hole is formed in a first mask attached to the outer cover and the second insertion hole is formed in a second mask attached to the inner cover, each of the masks having flexibility and elasticity to such an extent that it is deformable when a soldering iron tip of a soldering iron is brought into contact therewith.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the present invention, in addition to the first nozzle hole for peeling off the solder slag adhering to the tip of the soldering iron by the air ejection, the second nozzle hole for changing the dropping direction of the solder slag peeled off from the tip of the soldering iron by the air ejection is provided, and the air is ejected from the second nozzle hole in a shape spreading out in a planar shape, whereby the solder slag peeled off from the tip of the soldering iron can be prevented from being intensively accumulated at a fixed portion of the bottom of the drawer, and as a result, the tip cleaner can be continuously used for a long period of time.

Drawings

FIG. 1 is a side view of a solder tip cleaner in accordance with the present invention.

FIG. 2 is a top view of the solder tip cleaner.

FIG. 3 is a front view of the solder tip cleaner.

Fig. 4 is a partial side view showing a state where the outer cover and the inner cover of the iron tip cleaner are removed and the drawer is pulled out halfway.

Fig. 5 is a top view of the outer lid.

Fig. 6 is a side view of the outer lid.

Fig. 7 is a top view of the inner lid.

Fig. 8 is a side view of the inner lid.

Fig. 9 is a side view showing the nozzle member and the support arm, and is a view showing the nozzle member partially cut away.

Fig. 10 is a front view of fig. 9 viewed from the left side, and is a view of the cover in a state of being detached.

Fig. 11 is a top view of fig. 11.

Fig. 12 is a side view of a main part showing a state where the nozzle member is horizontally mounted.

Fig. 13 is a side view of a main part showing a state in which the nozzle member is mounted in a forward tilted posture.

Fig. 14 is a side view showing an example of a state where a tip of the soldering iron is cleaned.

Fig. 15 is a side view showing another example of a state where a tip of the soldering iron is cleaned.

Detailed Description

In order to implement the mode of the invention

Fig. 1 to 3 are views showing an embodiment of a tip cleaner according to the present invention. As shown in fig. 14 and 15, the iron tip cleaner is a cleaner for cleaning the iron tip 1a of the soldering iron 1 to which the solder slag is attached by spraying air, and has a cleaner case 10 having an air blowing region inside; a nozzle member 11 disposed inside the cleaner case 10; and a first nozzle hole 12 and a second nozzle hole 13 that open at the upper and lower end positions of the front end surface of the nozzle member 11.

The first nozzle hole 12 is a nozzle hole for separating the solder dross adhering to the tip 1a of the soldering iron 1 by spraying air, and the second nozzle hole 13 is a nozzle hole for scattering the solder dross separated from the tip 1a by spraying air and dropping the same onto one portion without concentration.

The cleaner case 10 is a box-shaped member in a rectangular parallelepiped shape elongated in the front-rear direction, and includes an outer case 14; an inner box 15 housed in the outer box 14 in a nested manner; and a drawer 16 which is freely inserted into and withdrawn from the front side of the outer box 14.

The outer box 14 is a container-shaped outer box main body 17 with an upper surface and a front surface partially opened; the inner box 15 is composed of an inner box body 19 having an コ shape as viewed from above with its top, bottom and front surfaces open, and a flat inner lid 20 openably and closably attached to the top surface of the inner box body 19.

The drawer 16 is a member for storing and carrying out the solder dross peeled off from the tip 1a of the soldering iron 1, and covers the front surfaces of the inner case 15 and the outer case 14, and functions as the bottom of the inner case 15. As can also be seen from fig. 4, in addition to the handle 16b being attached to the front wall 16a of the drawer 16, a port plate 21 is attached to the upper end portion of the front wall 16a, and the nozzle member 11 is supported by the port plate 21 via a support arm 22. Further, an exhaust port 23 is formed in the front wall 16a of the drawer 16, one end of a suction tube 24 is connected to the exhaust port 23, and the other end of the suction tube 24 is connected to the atmosphere via a suction mechanism not shown.

The outer lid 18 and the inner lid 20 are made of a magnetic material such as an iron plate, and are formed as follows.

First, as is clear from fig. 5 and 6, the magnet mounting frame 27 is fixed to the lower surface of the top plate 18a, and the magnets 28 are respectively mounted on the 2 frame sides 27a and 27b of the magnet mounting frame 27 connected in the L-shape via the holding frame 29, for the outer cover 18.

On the other hand, as shown in fig. 7 and 8, the inner lid 20 has a rectangular plate shape smaller in diameter than the outer lid 18, and is attracted by the magnet 28 of the outer lid 18 to be integrated with the outer lid 18, and in this state, when the outer lid 18 is attached to the outer box 14, the inner lid 20 covers the upper surface of the inner box 15, and when the outer lid 18 is detached from the outer box 14, the inner lid 20 is also detached from the inner box 15.

In addition, the outer lid 18 and the inner lid 20 are formed with elongated positioning projections 30 projecting downward from a portion of the magnet mounting frame 27 of the outer lid 18, and are formed with slit-shaped positioning holes 31 in the inner lid 20 so as to be fitted into each other for positioning when the two are integrated.

When the inner lid 20 is detached from the outer lid 18, the inner lid 20 may be pulled away from the outer lid 18 with a force stronger than the attracting force of the magnet 28.

As is also apparent from fig. 12 and 13, the outer cover 18 and the inner cover 20 are formed with a first insertion hole 32 having a large opening area and a second insertion hole 33 having a small opening area in such a shape and arrangement that the tip 1a of the soldering iron 1 in the inclined posture can be inserted into the cleaner box 10 together with the solder supply pin 2. The first insertion hole 32 and the second insertion hole 33 having different opening areas are provided in the outer cover 18 and the inner cover 20 in two stages in the vertical direction in order to prevent the solder slag blown off from the iron tip 1a by the air jet from being blown out to the outside as much as possible.

The first insertion hole 32 formed in the outer lid 18 has an elongated circular soldering iron insertion portion 32a as seen in fig. 5; and a needle insertion portion 32b having a uniform hole width extending in the longitudinal direction of the outer cap 18 from one end of the soldering iron insertion portion 32a in the longitudinal direction, wherein the hole width D1 in the short axis direction of the soldering iron insertion portion 32a is larger than the hole width D2 of the needle insertion portion 32 b.

On the other hand, the second insertion hole 33 formed in the inner lid 20 has a soldering iron insertion portion 33a having a long hole shape as seen in fig. 7; and a needle insertion portion 33b extending from one end of the soldering iron insertion portion 33a in the longitudinal direction of the inner lid 20, the needle insertion portion 33b being divided into narrow width portions 33c having a uniform hole width; and a wide width portion 33d having an elongated hole shape. Hole width D3 in the minor axis direction of soldering iron insertion portion 33a is larger than hole width D4 of narrow width portion 33c and hole width D5 of wide width portion 33D in needle insertion portion 33b, and hole width D4 of narrow width portion 33c is smaller than hole width D5 of wide width portion 33D.

Further, the hole width D3 of the soldering iron insertion portion 33a in the second insertion hole 33 is smaller than the hole width D1 of the soldering iron insertion portion 32a in the first insertion hole 32, and the hole widths D4 and D5 of the pin insertion portion 33b in the second insertion hole 33 are smaller than the hole width D2 of the pin insertion portion 32b in the first insertion hole 32.

The first insertion hole 32 and the second insertion hole 33 are formed in masks 34 and 35 attached to the outer cover 18 and the inner cover 20, respectively.

That is, in the outer cover 18, as shown in fig. 5 and 6, a rectangular window hole 18b is formed in the top plate 18a, a first mask 34 is fixed to the lower surface of the top plate 18a by a screw 36 so as to cover the window hole 18b, and a first insertion hole 32 is formed in the first mask 34.

In the inner lid 20, as shown in fig. 7 and 8, a rectangular window hole 20a is formed in the inner lid 20, a second mask 35 is attached by a plurality of screws 37 so as to cover the window hole 20a, and a second insertion hole 33 is formed in the second mask 35.

The first mask 34 and the second mask 35 are made of a material having heat resistance, flexibility, and elasticity such that they can be deformed when the soldering iron tip 1a and the solder feeding pin 2 come into contact with each other. Examples of such a material include silicone resin. Thus, even if the tip 1a and the solder supply tip 2 contact the masks 34 and 35, the tip 1a and the solder supply tip 2 are prevented from being damaged.

As is clear from fig. 4 and 9 to 11, the nozzle member 11 is a block-shaped member having a hexagonal shape when viewed from above and below, and the tip portion 11a is tapered, and inside the nozzle member 11, a first air chamber 41 and a second air chamber 42 are formed coaxially in the upper and lower directions, each of which is formed of a circular hole having an axis directed in the upper and lower directions, an open upper end portion of the first air chamber 41 is closed by a flat first cover plate 43 fixed to an upper end surface of the nozzle member 11 by a screw 43a, and an open lower end portion of the second air chamber 42 is closed by a flat second cover plate 44 fixed to a lower end surface of the nozzle member 11 by a screw 44 a. Therefore, the upper end surface and the lower end surface of the nozzle member 11 are flat surfaces except the heads of the screws 43a and 44 a.

Further, a slit-shaped first nozzle hole 12 formed of a horizontally elongated long hole is formed between the first cover plate 43 and the upper end surface of the nozzle member 11, and the first nozzle hole 12 communicates with the upper end portion of the first air chamber 41, and a first air introduction port 45 opened in the back surface of the nozzle member 11 communicates with the lower end portion of the first air chamber 41. Further, a second nozzle hole 13 in the form of a slit formed by a horizontally elongated long hole is formed between the second cover plate 44 and the lower end surface of the nozzle member 11, and the second nozzle hole 13 communicates with the lower end portion of the second air chamber 42, and a second air introduction port 46 opened in the back surface of the nozzle member 11 communicates with the upper end portion of the second air chamber 42.

As is clear from fig. 11, the first nozzle holes 12 have a substantially uniform hole width over the entire length from the hole rear end portion leading to the first air chamber 41 to the hole tip end portion opened to the outside, the second nozzle holes 13 have a hole width gradually increasing from the hole rear end portion leading to the second air chamber 42 to the hole tip end portion opened to the outside, and the hole width at the hole tip end portion of the second nozzle holes 13 is larger than the hole width at the hole tip end portion of the first nozzle holes 12.

The support arm 22 for supporting the nozzle member 11 is an L-shaped member as viewed from above, and has a rectangular plate-shaped base plate portion 50 detachably attached to the port plate 21 by a screw 52; and a support plate 51 having an elongated rectangular plate shape fixed to one of the left and right side ends of the base plate 50 by screws 51a and extending inward of the cleaner case 10. as can be seen from fig. 12 and 13, the nozzle member 11 is attached to the tip end of the support plate 51 by 2 attachment screws 53 and 2 pairs of screw insertion holes 54a and 54b formed in the support plate 51 so that the attachment posture can be changed, and the air ejection angle can be changed by changing the attachment posture.

That is, as shown in fig. 9 and 12, when 2 mounting screws 53 and 53 are inserted into the first screw insertion holes 54a and the nozzle member 11 is attached to the support plate portion 51, the nozzle member 11 is oriented horizontally and air is ejected horizontally from the first nozzle hole 12 and the second nozzle hole 13, and when 2 mounting screws 53 and 53 are inserted into the second screw insertion holes 54b and the nozzle member 11 is attached to the support plate portion 51, as shown in fig. 13, the nozzle member 11 is slightly tilted forward and air is ejected obliquely downward from the first nozzle hole 12 and the second nozzle hole 13. The reason for changing the mounting posture of the nozzle member 11 in this way is to accurately direct the first nozzle hole 12 toward the soldering iron tip 1a in accordance with the inclination angle of the soldering iron 1 mounted on the soldering apparatus.

One end and the other end of a first air introduction pipe 56 made of a synthetic resin hose are connected to the first air introduction port 45 of the nozzle member 11 and the outlet of the first air relay hole 55 formed in the base plate 50 via joints 57a and 57b, respectively, and similarly, one end and the other end of a second air introduction pipe 59 made of a synthetic resin hose are connected to the second air introduction port 46 of the nozzle member 11 and the outlet of the second air relay hole 58 formed in the base plate 50 via joints 60a and 60b, respectively.

Further, plug-in type joints 61 are respectively attached to the inlet of the first air relay hole 55 and the inlet of the second air relay hole 58 in the substrate portion 50, and when the substrate portion 50 is attached to the port plate 21, the joints 61, 61 are respectively inserted and connected to the outlet portion 62a of the first port 62 and the outlet portion 63a of the second port 63 formed in the port plate 21 via O-rings 64.

Further, a first pipe joint 67 is attached to the inlet of the first port 62, a first air supply pipe 68 is connected thereto, a second pipe joint 69 is attached to the inlet of the second port 63, a second air supply pipe 70 is connected thereto, and these first air supply pipe 68 and second air supply pipe 70 are gathered into 1 at a confluence joint 71, and are connected to a common air source through an air pipe connected to the confluence joint 71.

Further, a flow rate adjusting valve having a variable orifice is built in the first pipe joint 67, and the flow rate of air can be adjusted by adjusting the opening area of the variable orifice by rotating the operating element 67 a.

A cover 73 covering the first air introduction pipe 56 and the second air introduction pipe 59 is attached to the base plate portion 50 and the support plate portion 51 of the support arm 22 by screws 74. This cover 73 is a member in which an upper panel 73a, a bottom panel 73b, a front panel 73c, and 1 side panel 73d are integrally connected, and the nozzle member 11 protrudes forward (toward the rear wall 15a of the inner box 15) from an opening 73e formed at the side end portion of the front panel 73 c. When the cover 73 is attached to the support arm 22 as shown by the chain line in fig. 11, a support box 75 having a rectangular box shape is formed, and the first air introduction pipe 56 and the second air introduction pipe 59 are accommodated in the support box 75, and the nozzle member 11 is supported by the tip end portion of the support box 75.

With this configuration, the solder slag peeled off and scattered from the tip 1a can be prevented from adhering to the air introduction tubes 56 and 59, the joints 57a, 57b, 60a, and 60b, and the like.

When the tip cleaner having the above configuration is attached to the soldering apparatus, the mounting posture of the nozzle member 11 is adjusted by the 2 mounting screws 53, 2 pairs of screw insertion holes 54a, 54b, and 54b in accordance with the inclination angle of the soldering iron 1 mounted on the soldering apparatus, as shown in fig. 12 and 13.

Next, when the iron tip 1a is cleaned by the iron tip cleaner, the soldering iron 1 and the solder supply pin 2 are inserted into the cleaner case 10 through the first insertion hole 32 and the second insertion hole 33 while maintaining the inclined posture. At this time, since the entire nozzle member 11 is accommodated in the cleaner case 10 and the first nozzle hole 12 is formed at the front upper end position of the nozzle member 11, even when the inclination angle of the soldering iron 1, the position of the solder feeding pin 2, and the like are variously different, the soldering iron 1 is accommodated in the cleaner case 10 without causing the soldering iron 1 to compete with the nozzle member 11, and the tip 1a of the soldering iron 1 is brought close to the first nozzle hole 12.

In a state where the iron tip 1a is located immediately before the first nozzle hole 12, air is ejected from the first nozzle hole 12 and the second nozzle hole 13, and at the same time, the suction mechanism is also activated, so that the inside of the cleaner cartridge 10 is exhausted from the suction tube 24.

By doing so, the solder dross adhering to the soldering iron tip 1a is reliably blown off by the air jetted from the first nozzle hole 12, which is long in the lateral direction, in a linear shape, not in a dot shape, in the width direction of the soldering iron tip 1a, and falls into the drawer 16. Further, in the middle of the fall, the air ejected from the second nozzle hole 13 having a wide tip in a horizontally long and wide flat shape (air curtain shape) is dispersed while changing the fall direction, and is prevented from intensively falling only to a part of the bottom of the drawer 16. As a result, since the columnar accumulation of the brazing slag on a part of the bottom of the drawer 16 is prevented, the trouble that the columnar accumulation of the brazing slag is attached again by contacting the iron tip 1a is eliminated, the frequency of discharging the brazing slag accumulated in the drawer 16 is reduced, and the iron tip cleaner can be continuously used for a long time.

Further, since the first insertion hole 32 and the second insertion hole 33 are provided in the outer cover 18 and the inner cover 20 in two layers, and the opening area of the second insertion hole 33 of the inner cover 20 is formed small, the solder slag blown off from the soldering iron tip 1a is almost shielded by the inner cover 20, and hardly flies out to the outside of the cleaner case 10.

However, when the flying-out of the brazing material slag can be prevented only by one of the first insertion hole 32 and the second insertion hole 33, either one of the insertion holes may be omitted.

Further, after the air from the first nozzle hole 12 is blown off from the iron tip 1a, a part of the brazing filler metal slag whose flying direction is changed to the horizontal direction by the air from the second nozzle hole 13 adheres to the inner wall surface of the inner case 15 and grows in a columnar shape, but if the amount of adhesion increases and the column becomes long, the column is broken by its weight and falls into the drawer 16, and therefore, such a problem that the column of the brazing filler metal slag comes into contact with the iron tip 1a is hard to occur.

It is desirable that the inner surfaces of the inner case 15 and the drawer 16 are coated with a fluorine resin or coated with a fluorine-containing plating layer so that the adhered brazing filler metal slag is easily peeled off and cleaning and maintenance are also easy.

When the brazing slag is accumulated in the drawer 16, as shown in fig. 4, the drawer 16 is pulled out with the outer lid 18 and the inner lid 20 removed, and the brazing slag inside is disposed of. In this case, by preparing a plurality of drawers 16 having the same configuration and using them while replacing them, the stop time of the soldering apparatus at the time of disposal of the solder slag can be shortened, and the operation rate can be improved.

In the illustrated embodiment, both the first nozzle hole 12 and the second nozzle hole 13 are provided in 1 nozzle member 11, but 2 nozzle members may be provided inside the cleaner cartridge 10, the first nozzle hole 12 may be provided in one first nozzle member, and the second nozzle hole 13 may be provided in the other second nozzle member.

Further, the first air inlet 45 and the second air inlet 46 of the nozzle member 11 and the first air relay hole 55 and the second air relay hole 58 of the substrate portion 50 of the support arm 22 are connected by the first air inlet pipe 56 and the second air inlet pipe 59, but the support arm 22 may be formed by a columnar member, and 2 flow path holes instead of the first air inlet pipe 56 and the second air inlet pipe 59 may be formed inside this member, thereby removing the first air inlet pipe 56 and the second air inlet pipe 59.

Further, the second nozzle hole 13 may be a nozzle hole having a plurality of small holes formed in a horizontal direction.

Description of the symbols

1: soldering iron; 1 a: a soldering iron tip; 10: a cleaner case; 11: a nozzle member; 12: a first nozzle hole; 13: a second nozzle hole; 18: an outer cover; 20: an inner cover; 32: a first insertion hole; 33: a second insertion hole; 34: a first mask; 35: a second mask; 41: a first air chamber; 42: a second air chamber; 45: a first air introduction port; 46: a second air introduction port.

Claims (7)

1. A tip cleaner for a soldering iron, which cleans a tip of the soldering iron by peeling off solder slag adhering to the tip by air injection,

the iron tip cleaner has a cleaner cartridge having an insertion hole on an upper face for inserting an iron tip of a soldering iron; the first nozzle hole is opened in the cleaner case, and the solder slag adhered to the tip of the soldering iron is peeled off by the air injection; the second nozzle hole is opened in the cleaner case, the falling direction of the brazing flux peeled from the iron tip is changed by the air injection,

the second nozzle hole is formed of a horizontally elongated long hole, and ejects air in a horizontally elongated plane.

2. A tip cleaner for a soldering iron according to claim 1, wherein the second nozzle hole has a hole width gradually increasing from a hole rear end portion to a hole front end portion which is an end portion opened to the outside.

3. A soldering iron tip cleaner according to claim 1 or 2 wherein the second nozzle hole is disposed below the first nozzle hole.

4. A tip cleaner for a soldering iron according to claim 1 or 2, wherein a nozzle member is accommodated in an interior of the cleaner case, and the nozzle member is provided with a first nozzle hole and a second nozzle hole.

5. A tip cleaner for a soldering iron according to claim 4, wherein the angle of air from the first nozzle hole and the second nozzle hole is changed by changing the posture of the nozzle member.

6. A tip cleaner for a soldering iron according to claim 1 or 2, wherein an outer cover and an inner cover are provided in a double layer on an upper surface of the cleaner case, and insertion holes for inserting a tip of the soldering iron are formed in the outer cover and the inner cover, respectively, and an opening area of the second insertion hole formed in the inner cover is smaller than an opening area of the first insertion hole formed in the outer cover.

7. A tip cleaner for a soldering iron according to claim 6 wherein the first insertion hole is formed in a first mask attached to the outer cover and the second insertion hole is formed in a second mask attached to the inner cover, each of the masks having a degree of flexibility and resiliency which is deformable upon contact by a tip of the soldering iron.

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