KR100855027B1 - Soldering iron - Google Patents

Abstract

A soldering iron is provided to electrically insulate the heater part by coating a thermal conductive adhesive on a heater part formed in a heater inserting part of an iron tip. A soldering iron comprises(120): a tip part(130) for melting a solder; a cylindrical or conical heater inserting part(240) which is formed along the tip part from a rear end of the tip part, and which is opened to the rear end side; an iron tip(120) including a heater part(230) which is formed in the heater inserting part, and which is comprised of a heater coiling wire(210) coiled on a bobbin(135) in a coil shape; a joining member(150) for joining a lead wire(270) of the heater coiling wire of the heater part and a lead wire of a temperature sensor(200) for sensing temperature of the tip part with a body part of the soldering iron; and a connecting pipe(260) formed between the heater inserting part and the joining member and made from ceramics such that the respective lead wires pass through the connecting pipe, wherein the heater part is coated with a thermal conductive adhesive(220).

Description

Soldering Iron

1 is a cross-sectional perspective view of a conventional iron tip,

2 is a perspective view of a soldering iron according to the present invention;

3 is a cross-sectional perspective view of a pharyngeal tip in accordance with the present invention.

* Description of the symbols for the main parts of the drawings *

120: iron tip 140: pipe

200: temperature sensor 210: heater winding

220: thermally conductive adhesive 230: heater

TECHNICAL FIELD The present invention relates to a soldering iron, and more particularly, to electrical insulation of a heater portion provided in a heater insertion portion of a soldering iron tip by application of a thermally conductive adhesive.

In general, a soldering iron tip having a thermally conductive material applied in a conical shape and having a built-in heater has been provided, and the heater is generally constructed by winding a wire having a relatively high resistance value in the form of a coil.

On the other hand, in the recent surface mount technology for soldering LSI on a substrate, the parts to be soldered and the parts not to be melted are disposed in a very small range, and when such soldering is performed, the solder tip is formed in a very small size so that the soldering tip is appropriately spread over a very small range. Soldering irons have been proposed.

The inside of such a very small soldering iron is also configured in the same way as a general soldering iron, i.e., a heater is wound around a very small soldering iron in a coil shape.

However, in the case of the heater of the extremely small soldering iron described above, since the iron tip itself is very small, the spacing between the wires wound in the coil shape becomes considerably smaller than that of the general soldering iron.

An example of a heater of such a very small soldering iron is disclosed in "Korean Patent Publication No. 2006-0058633 (May 30, 2006), US Patent Publication No. 2004-0195228 (October 07, 2004)" and the like. .

That is, in the Republic of Korea Patent Publication No. 2006-0058633, the iron tip 20, as shown in Figure 1, the conical portion 23 and the cylindrical portion 24 having the same diameter as the bottom surface of the conical portion 23 is integral The stainless steel pipe P fixed by force insertion etc. is provided in the outer peripheral surface of the front-end | tip part 21 and the cylindrical part 24 which are formed of the material, and are excellent in thermal conductivity.

The tip portion 21 is provided with an insertion recess 25 formed in a cylindrical cavity from the center of the rear end side having a circular cross section toward the tip side, and the heater insertion portion provided at the rear end side of the insertion recess 25. Each member is inserted into 25a).

The heater 30 is inserted into the heater inserting portion 25a, and the heater 30 is formed in a coil shape by an iron-chromium-based metal material containing aluminum made of a cantilever wire as a representative example.

The heater 30 is formed by winding a cantilever wire in a core material (not shown) as many times as desired and putting it in a coil shape at a predetermined temperature (for example, 1100 to 1200 ° C) for a predetermined time to oxidize at a high temperature.

As described above, when the heater 30 is oxidized at a high temperature, a black oxide film is formed on the surface of the wire rod (for example, canal wire) of the heater 30 so as to cover the wire rod, and the black oxide film is the canal wire. Aluminum oxide (alumina) formed by oxidizing aluminum contained in.

That is, since aluminum oxide (alumina) has electrical insulation, the surface of the heater 30 is covered with an insulating oxide film.

The outer diameter of the first cylindrical member 31 is formed larger than the inner diameter of the temperature sensor inserting portion 25b, the heater 30 is in a state in which the first cylindrical member 31 and the second cylindrical member 32 are inserted It is inserted into the heater inserting portion 25a.

The first cylindrical member 31 is made of a ceramic material having excellent electrical insulation and heat resistance, and in order to insert the second cylindrical member 32 and the temperature sensor 33 into the temperature sensor inserting portion 25b, First, the detection cable 34 is drawn out through the tip of the second cylindrical member 32, and the temperature sensor 33 is formed on the detection cable 34.

Further, US Patent Application Publication No. 2004-0195228 discloses a soldering iron for heating the iron tip and releasing gas near the iron tip.

The soldering iron is a soldering tip, a heater cartridge for coupling with the soldering tip, a channel formed between the heater cartridge between the input and output openings separated from each other in the axial direction of the heater cartridge, the input opening of the heater cartridge in combination with the heater cartridge. Gas injector for supplying gas through the, is configured to include an exhaust pipe surrounding at least one portion of the heater cartridge to provide a gas passage.

However, the above-described Korean Patent Publication No. 2006-0058633 is a method of making a heater embedded in the tip of the iron, and the surface of the heater is formed of an insulating oxide film by putting the heater in a high temperature furnace for a predetermined time to oxidize it at a high temperature. In addition to the complex problem, there was a disadvantage in that the thermal deformation of the heater is induced in the oxidation process for forming the insulating oxide film.

In addition, US Patent Application Publication No. 2004-0195228 discloses a soldering iron device having a gas chamber for injecting gas, which has a problem in that the configuration of the device is complicated.

SUMMARY OF THE INVENTION An object of the present invention is to solve the problems as described above, and to provide a soldering iron having a thermally conductive adhesive coated on a heater and having a temperature sensor.

In order to achieve the above object, the soldering iron according to the present invention has a front end portion for melting solder, a cylindrical or conical heater insertion portion formed along the front end portion at the rear end of the front end portion and opened to the rear end side, and positioned at the heater insertion portion and the coil A soldering iron having a soldering iron tip including a heater portion comprising a heater winding wound around a bobbin in a shape, wherein the heater portion is coated with a thermally conductive adhesive.

 In addition, in the soldering iron according to the present invention, the iron tip further comprises a coupling member for coupling the lead wire of the heater winding of the heater portion and the lead wire of the temperature sensor for sensing the temperature of the tip portion to the body portion of the soldering iron. It is done.

In addition, in the soldering iron according to the present invention, the iron tip is characterized in that it further comprises a connection pipe which is provided between the heater inserting portion and the coupling member to penetrate the respective lead wires.

In addition, in the soldering iron according to the present invention, the coupling member is characterized in that it comprises a fastener for coupling with the body portion of the soldering iron.

In addition, in the soldering iron according to the present invention, the heater unit is characterized in that it comprises a bobbin on which the heater winding is wound and a side through-hole through which the heater winding passes.

In addition, in the soldering iron according to the present invention, the thermally conductive adhesive has a mixing ratio of the thermally conductive adhesive and water at about 10: 1.4, and is used after drying at room temperature for at least 24 hours or at 65 ° C for at least 4 hours. do.

The above and other objects and novel features of the present invention will become more apparent from the description of the specification and the accompanying drawings.

First, the concept of the present invention will be described.

The soldering iron of the present invention is a soldering iron having a soldering tip for melting solder to the tip, wherein the tip of the tip is formed in the shape of a cylindrical heater insert and a coil formed along the front end from the rear end and open to the rear end. And a heater part coated with a heat conductive adhesive and inserted into the heater inserting part.

In the heater part, a heater winding for heating the tip of the iron tip is formed in a coil shape on a bobbin made of ceramic insulating material, and the material of the heater winding is made of a resistance heating element such as nickel chromium. It is covered with a conductive adhesive.

That is, by covering the surface of the heater part with a heat conductive adhesive, the heater winding constituting the heater part having a resistance value and generating heat is electrically insulated, and at the same time, heat generated from the heater part is transferred to the tip portion, and the heater winding is heated by the heat conductive adhesive. The electrical contacts between each other are insulated.

As a result, electric shorts can be avoided in the case where the heater windings are in contact with each other, so that the gap between the heater windings formed in the coil shape can be narrowed and arranged, and electrical troubles such as disconnection can be easily prevented by the thermally conductive adhesive. have.

Therefore, the heater part embedded in the iron tip of the present invention can further reduce the distance between the heater windings arranged in a coil shape, and accordingly, the size of the heater part can be made small, so that the iron tip can be configured to a very small size. have.

In addition, since the spacing between the heater windings can be reduced, the amount of heating per unit volume also increases, so that the iron tip can be quickly heated.

In addition, the iron tip connector is made of ceramic, etc., and is located at the rear end of the iron tip to prevent the heat of the heater from easily conducting to the body. Therefore, the soldering iron can continuously hold the handle of the soldering iron body for a long time. This gives you a soldering iron suitable for your work.

In addition, the connector serves to fix the power supply line for supplying power to the heater or the signal line of the sensor (hereinafter referred to as lead wire) does not come into contact with each other.

Since the connection part between the handle of the soldering iron is made of a ceramic tube and a coupling member, heat is not easily conducted. Therefore, the soldering iron can be held continuously for a long time during the soldering operation to obtain a soldering iron suitable for working. have.

EMBODIMENT OF THE INVENTION Hereinafter, the structure of this invention is demonstrated according to drawing.

In addition, in description of this invention, the same code | symbol is attached | subjected to the same part and the repeated description is abbreviate | omitted.

It demonstrates according to FIG.

Figure 2 is a perspective view of a soldering iron according to the present invention, Figure 3 is a cross-sectional perspective view of a soldering iron tip according to the present invention.

As shown in FIG. 2, the soldering iron 100 is used to melt the solder with the tip 130 to perform soldering or to remove the solder.

The soldering iron 100 has a heater portion 230 for inserting a large amount of solder into the soldering iron 100, and a soldering iron tip 120 having a tip 130 and a body 110 connected to a rear end of the soldering tip 120. Equipped.

The tip portion 130 is formed of a rod-shaped copper material having high thermal conductivity, and a railroad gold layer is formed on the outer circumferential surface of the tip portion 130, which is a portion connected to the solder, to prevent corrosion.

The rear end of the iron tip 120 is coupled to the front end of the body portion 110 through a socket that is a coupling member 150, the rear end of the body portion 110 has a cable having an outlet (not shown) connected to the power source 170 is provided.

The middle portion of the body portion 110 is provided with a handle portion 160 for holding the soldering iron 100 by hand when performing the soldering operation, the controller portion 110 is provided with an insulating transformer (not shown) ) Is built-in.

Although not shown in detail as a known configuration in the art, the isolation transformer converts the power supplied from the power source into a power source suitable for the operation of the soldering iron 100 so that the heater unit 230 and the temperature of the heater unit 230 disposed in the soldering tip 120 are used. Supply to the controller.

The temperature controller provided in the controller device is connected through the cable 170 and the temperature sensor 200 disposed in the tip of the iron tip 120, and supplies power to the heater unit 230 according to the feedback from the temperature sensor 200. Turn it on or off.

The temperature of the iron tip 120 is controlled to be maintained at a predetermined temperature by turning on and off the heater unit 230 by the temperature controller, and the controller device is not limited to being mounted inside the body unit 110. It may be provided outside the body portion 110 in the form.

In addition, the iron tip 120 to the body portion 110 made of synthetic resin and the like is coupled and fixed by the connection member 150.

In addition, as shown in Figure 3, the iron tip 120 is a conical portion 131, a cylindrical portion 133 formed to extend to the conical portion 131, the cylindrical portion 133 is integrally formed and thermally conductive It consists of a stainless steel pipe 140 fixed by a mechanical coupling known in the art, such as forced insertion into the outer peripheral surface of the tip portion 130 and the cylindrical portion 133 made of this excellent material.

In addition, the tip portion 130 is provided with a heater inserting portion 240 having a circular cross section and formed in a cylindrical or conical cavity from the center of the rear end side toward the tip side.

The heater inserting part 240 and the temperature sensor inserting part 132 are configured to communicate with each other, and the heater inserting part 240 is formed inside the cylindrical part 133 and is configured as a cylindrical or conical cavity.

The temperature sensor inserting portion 132 is formed inside the conical portion 131 and has a cylindrical or conical cavities whose inner diameter is set smaller than the cross-sectional inner diameter of the heater 230.

The heater unit 230 is inserted into the heater inserting unit 240, and the heater unit 230 includes a bobbin 135 made of ceramic having excellent electrical insulation and heat resistance, and a heater winding 210 wound on the bobbin 135. It consists of a temperature sensor 200 for detecting the temperature of the tip 130.

The heater winding 210 is made of a coil shape and the material of the coil is made of a nickel chromium-based metal as a representative example.

In addition, the heater winding 210 is wound in a coil shape by a desired number of times, and the thermally conductive adhesive 220 described below is applied onto the coiled heater unit 230 and cured for a predetermined temperature.

That is, the heater winding 210 of the heater unit 230 has electrical insulation at high temperature by the heat conductive adhesive.

The temperature sensor 200 is for detecting the temperature of the tip portion 130 and is located at the foremost portion of the space formed in the temperature sensor insertion portion 132 of the tip portion 130 and does not contact the cylindrical inner circumferential surface 134. To prevent corrosion due to contact and friction of the metal and friction, and is bonded to the cylindrical inner circumferential surface 134 of the tip portion 130 via a thermally conductive adhesive, the specification of the temperature sensor 200 is a thermocouple known in the art (Thermo) couple K type) is used.

The bobbin 135 of the heater unit 230 is formed of a cylindrical ceramic (Al ₂ O ₃ ) bobbin four-hole pipe, the heater winding 210 is wound at predetermined intervals on the bobbin 135 made of ceramic, the bobbin 135 The inside of the hole is formed, the signal line (hereinafter referred to as lead wire 270) of the temperature sensor 200 and the heater winding 210 passes through the connecting pipe 260 through the hole of the coupling member 150 It is connected to the joint wire 280.

In addition, the bobbin 135 is formed with a side through-hole 136 for withdrawal of the heater winding 210.

The side through hole 136 prevents the convenience of the winding of the heater winding 210 and the mixing with the non-charged metal parts (eg, the tip 130, the pipe 140, etc.).

The connector 260 is a four-hole ceramic tube made of ceramic having excellent electrical insulation and heat resistance, and four lead wires 270 are connected to the joint wire 280 of the coupling member 150 through the through holes of the connector 260. The connection is prevented, and the contact between the lead wires 270 is prevented and the lead wires 270 are supported.

The connector 260 may not be provided according to a manufacturer's need, and the lead wire 270 drawn from the bobbin 135 may be connected to the joint wire 280 of the coupling member 150 without the connector 260. Can be.

Coupling member 150 is one position fixing fixture for easy coupling between the four plug-type joint wire 280 and the body portion 110 connected to the lead wire 270 passed through the connecting pipe 260 ( 290 is formed, and when the coupling member 150 and the pipe 140 is coupled, the coupling member 150 and the pipe 140 is fixed to the punch or two to three protrusions at the rear of the pipe 140 (not shown). The coupling member 150 is fitted to the pipe 140.

This fitting strengthens the fixing of the coupling member 150 and the pipe 140 of the iron tip 120, and the four joint wires 280 of the coupling member 150 is the front end of the body portion 110. Is connected to the cable 170 and the coupling terminal (not shown) located in the front end of the body portion 110, the fastener 290 is inserted into the groove of the body portion 110 is fixed.

The heater winding portion 210 wound on the cylindrical ceramic bobbin 135 with a heating wire is wound around the heater inserting portion 240 having a larger diameter than the temperature sensor inserting portion 132 on which the temperature sensor 200 is disposed. The thermally conductive adhesive 220 is applied to and inserted into the part 240.

The thermally conductive adhesive 220 is applied to the heater inserting part 240 using a silicon gun, and the mixing ratio of the adhesive powder and water of the thermal conductive adhesive 220 is 80 to 90 parts by weight of the adhesive powder. To 10 to 20 parts by weight of the adhesive powder and water is mixed, it is cured when dried for at least 24 hours at room temperature or 4 hours at 65 ℃ ± 5 ℃.

The optimal mixing ratio of the thermally conductive adhesive 220 is mixed with 88 parts by weight (w%) of the powder for the adhesive in a ratio of 12 parts by weight (w%) of water, the thermally conductive adhesive 220 is prepared at room temperature for 24 hours or Cured after drying at 65 ℃ for 4 hours.

80 to 90 parts by weight of the adhesive powder and 10 to 20 parts by weight of water out of the mixing ratio of the thermal conductivity adhesive 220 takes a lot of drying time or rapid work hardening due to rapid curing.

In addition, when the drying time (24 hours at room temperature or 4 hours at 65 ℃ ± 5 ℃) is exceeded, workability such as insertion of the heater portion during soldering iron assembly is significantly reduced, and if the drying time is less than the drying time adhesive ( The less hardening of the 220) causes a problem in the soldering iron assembly work.

As the thermally conductive adhesive 220, generally, an alumina adhesive, a red bond 919 or a red bond 920 is used, and a compatible thermal conductive adhesive may be used as long as the thermal conductive adhesive 220 has an equivalent performance.

The thermally conductive adhesive 220 has a high electrical insulation performance and at the same time has a particularly high thermal conductivity adhesive, which is applied to a specification requiring continuous heat dissipation, and attachment of heating elements and furnace elements. It is a high-temperature ceramic adhesive with high electrical resistance and dielectric strength and can be used up to 1600 ℃.

As mentioned above, although the invention made by this inventor was demonstrated concretely according to the said Example, this invention is not limited to the said Example and can be variously changed in the range which does not deviate from the summary.

According to the soldering iron according to the present invention, by coating the heater portion of the soldering iron using a thermal conductive adhesive, the production cost according to the simplification of the manufacturing process of the heater portion is reduced, and the heat generated from the heater portion is transferred to the iron tip portion without loss. The effect that the heat transfer utilization efficiency of can be increased is obtained.

In addition, according to the soldering iron according to the present invention, since disconnection of the heater is prevented by using a thermally conductive adhesive, which is a high electrical insulating material, the winding interval of the heater winding is further reduced, thereby minimizing the soldering iron by increasing the amount of heating per unit volume. The effect can be obtained.

Claims (6)

A tip for melting solder, A cylindrical or conical heater insert formed in the rear end of the front end and opened toward the rear end, A soldering iron tip including a heater part disposed on the heater inserting part and comprising a heater winding wound on a bobbin in a coil shape. Coupling member for coupling the lead wire of the heater winding of the heater unit and the lead wire of the temperature sensor for sensing the temperature of the tip portion to the body portion of the soldering iron; It is provided between the heater inserting portion and the coupling member provided with a connecting tube made of a ceramic penetrating the respective lead wires, The soldering iron, characterized in that the heater is coated with a thermally conductive adhesive. delete delete The method of claim 1, The coupling member is a soldering iron, characterized in that it comprises a fixture for coupling with the body portion of the soldering iron. The method of claim 1, The heater part has a bobbin wound around the heater winding and the soldering iron, characterized in that it has a side through hole through which the heater winding passes. The method of claim 1, The mixing ratio of the adhesive powder and water of the thermally conductive adhesive is 80 to 90 parts by weight of the adhesive powder, 10 to 20 parts by weight of water, and dried for 24 hours at room temperature or 4 hours at 65 ℃ ± 5 ℃ to use Soldering iron, characterized in that.

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