UA76814C2 - Wireless soldering iron - Google Patents

Abstract

A soldering iron comprises a graphite tip having two separate halves (9, 10) that are electrically isolated from each other. When both halves of the tip are applied to an electrically conductive material, such as the material to be soldered, an electrical circuit between the tip halves (9, 10) and an electrical power source (8) is completed. Therefore, the tip can reach operating temperatures quickly. When the tip is removed from the joint, the electric circuit is broken and the tip material may quickly cool to a safe temperature. The tip material permits higher power outputs than other battery operated portable soldering irons.

Description

Description of the invention

This application is a partial continuation of US patent application Mo09/726546, filed August 18, 2000, which claims priority under the previous US patent application Mob0/149416, filed August 18, 1999.

This invention relates to cordless electrical devices, and more specifically to soldering irons and soldering iron tips.

Many industries and some hobbyists find it necessary to manually create electrical connections between various electrical components. To create such connections, a large number of soldering irons have been developed, which are used in a number of applications, starting from the repair of printed circuit boards and ending with the use in the telecommunications industry and the use in the manufacture and repair of electrical and electromechanical equipment for heavy industry. Existing soldering irons can vary in power source, application, performance, shape, size, 19 temperature, tip type, heat source, price, and portability.

Regardless of the size or functionality of the soldering iron, existing soldering iron tips are generally divided into two main types. The stinger of the first type consists of a heating element surrounded by a non-electrically conductive film material, on top of which a coating is applied in the form of a heat-conducting metal shell. Such a sting is heated by supplying electricity to the heating element. Depending on the application, the size of the sting can vary widely. The power source can also change - starting from a battery with a voltage of 2.48 and ending with an ordinary network socket of an alternating current network with a voltage of 2208. Regardless of the power source, the flow of current to the heating element is typically controlled by a switch in the electrical circuit that leads to the heating element element This switch is often a manual switch located on the outside of the soldering iron. c 29 The tip of a soldering iron of another type is a solid tip made of a heat-conducting material, usually metal, which is heated by burning butane. Such soldering irons are typically portable, and butane is supplied from a can located inside the tool.

There are a number of problems with existing types of soldering iron tips. Soldering irons, which must be plugged into a regular electrical outlet, do not have mobility, and their use is limited. Regardless of the type of tip, the time usually required to reach soldering temperatures is initially in the range of 10 to 60 seconds. "-

If the soldering iron is not completely cooled between its uses, subsequent applications may not require such a long heating time, but still heating does not occur immediately. Likewise, the time required for the desired cooling can be considerable, putting the user at risk of (He) burning and/or burning anything around him after moving the tool away from the work surface and to

From the cooling of this tool. In addition, metal stings can be soldered to the connection, which leads to damage to the connection during the removal of the sting and to the need for additional repairs.

Existing cordless soldering irons remove the mobility issues common to plug-in soldering irons, but create additional cost issues. Butane-fueled soldering irons require that the user store and maintain a supply of highly flammable gas and do not eliminate the other disadvantages noted in C 70 above. Existing battery-powered cordless soldering irons can typically only make 125 connections before being fully discharged and are only capable of output power in the 15-35 watt range. z" To guarantee the user the possibility of an adequate inspection of the joint on which soldering is carried out, electric soldering irons are sometimes equipped with a small light bulb located on the tip of the soldering iron and intended to illuminate the soldering iron and the connection. In these devices, the light is controlled by the same switch that controls the flow of current to the heating element. The disadvantage of this system is the impossibility of using light without heating the 7 tips of the soldering iron. This requires the user to turn on the light separately if he or she wants to illuminate

Ge") the surrounding space without soldering or heating.

As noted above, soldering irons are initially used to create conductive connections in a variety of electrical and electronic equipment. Visual control of the soldered connection does not always -shsh 20 allow you to accurately determine whether this connection is correctly formed and whether it is now electrically conductive. So, for those users who want to check the received connection or make sure of the integrity of the electrical circuits

T" of the circle between two other points of this circle, you have to carry a separate device for checking the integrity of the circles.

Thus, there is a need for a soldering iron that can be quickly heated and cooled, minimizing the risk of burns to the user, ignition in the space surrounding him or her. In an ideal case, a soldering iron can be

HF) is portable and can be used to create a large number of connections at high output power without the need for recharging. There is also a need for a portable soldering iron that can also be used as a flashlight bulb and/or as a circuit integrity monitor, reducing the number of tools the user needs to carry to the job site. 60 The present invention provides a soldering iron with a graphite tip having two separate halves that are electrically isolated from each other. The halves of the stinger are each connected to opposite sides of the power source. When both halves of the tip are placed on an electrically conductive material, such as the material to be soldered, the electrical circuit between the tip halves and the power source is closed.

The halves of the sting are made of a material with a high electrical resistivity and low thermal conductivity. Therefore, the sting can quickly reach operating temperatures. When the sting is removed from the joint,

the electrical circuit is broken and the sting material cools rapidly.

Since current can only flow when both parts of the prong are connected in an electrical circuit, a separate switch is not needed. In addition, the soldering iron can be used without waiting for the tip to heat up. It stings too

Reduces the risk of burning the user and/or igniting his or her surroundings because the stinger heats and cools quickly. In addition, the sting material eliminates the risk of the sting sticking to the joint. The tip material also provides increased power output compared to other popular portable battery-powered soldering irons, and allows you to create more than 300 joints each time after a full charge.

In accordance with additional aspects of the present invention, in one particular embodiment, the 7/0 soldering iron additionally includes a bulb located on the body to illuminate the tip and connection.

The bulb is controlled by a separate switch, allowing the tool being used to illuminate the space surrounding the user, virtually without heating the tip. This aspect of the invention allows the user to avoid having to carry a separate light source when the user is working or intending to work in areas where there is insufficient lighting.

In accordance with other aspects of the invention, another specific embodiment is proposed, in which the tool includes an electrical outlet connected in series with a light bulb, a power source and a probe for checking the integrity of the circles. This aspect of the invention allows using a soldering iron to monitor the integrity of circuits by applying the lead and probe directly to a new solder joint or to another part of the circuit being monitored.

This aspect of the invention allows the user to avoid having to carry a separate device for monitoring the number of circles.

The above-mentioned aspects and many of the advantages inherent in this invention will become more clear when referring to the following detailed description, if it is considered together with the attached drawings, while: Fig. 1 shows a view of one specific variant of the soldering iron, made in accordance with the given ; Fig. 2 shows a front view of one specific embodiment of a soldering iron tip made i) according to this invention; Fig. 3 shows a side view of the tip of the soldering iron shown in Fig. 2; Fig. A4 shows a view from the end of the tip of the soldering iron shown in Fig. 2; and Fig. 5 shows a schematic diagram of a circuit intended for use with the specific embodiment shown in Fig. 1. -

Turning to Fig. 1, we note that here is shown a specific variant of the cordless soldering iron, (du made in accordance with this invention. The soldering iron 1 includes a tip 2 attached to the body 3, an electric bulb 4 located on the body C, for lighting the tip 2 and the surrounding working surfaces (not shown), the switch 5, located on the housing C, for controlling the electric bulb 4, the output b for checking the integrity of the circles and the probe 7 for checking the integrity of the circles, located on the housing C, as well as means 8 power supply (see Fig. 5).

If we speak in more detail, the body C is an elongated, essentially tubular element made of a rigid heat-resistant material, such as plastic or any other materials known to specialists in this field of technology. Those skilled in the art will appreciate that the housing configuration can be varied widely for use in various applications.

Referring to Fig. 2, C and 4, we note that the sting 2 includes two electrodes 9 and 10, electrically isolated from each other by an insulator 11 located between them. In the case of a specific embodiment shown in Fig.2, C and 4, the electrodes 9 and 10 have a semi-cylindrical cross-sectional shape. In the longitudinal direction, each electrode is tapered at an angle A along its distal third and then truncated at a -I angle B at the distal end, thereby forming a flat, inclined surface for application to the joint to be soldered. Those skilled in the art will appreciate that the size and shape of the stinger can also be changed at

Me. applications in various soldering options.

Go! Electrodes 9 and 10 are preferably made of graphite or material containing graphite. For example, acceptable results have been obtained with battery electrodes that contain graphite, such as those available from Emegeadu's model Mo1209 heavy-duty flashlight batteries manufactured by Emegeadu Vaiegu Sotrapu, Ips. state of Ohio, USA. Alternatively, the electrodes can be made of other materials that are semiconductors in terms of current transmission and have low thermal conductivity, for example, germanium and silicon. The electrical resistivity of the tip materials should be at least 1500 micro-ohm.cm (μohm.cm), and preferably greater than 3000 μohm.cm, while the thermal conductivity should be less than 10 British thermal units per hour per foot-degree Fahrenheit (BTO/hr.ft-.E), and is preferably in the range of 1 to 10 BTO/hr.ft.eR. When electricity is applied, the electrode material reaches a temperature of about 6002E in a few seconds and remains solid at temperatures that exceed about 10009 P. In addition, the electrode material preferably has a compressive and tensile strength of 60, sufficient to allow the manufacture of electrodes with tolerances of less than 1 mm, rigidly held in place by the body C and superimposed on the joint to be soldered, without mechanical damage The sting should have a density in the range of 1.5 to 1.75g/cm2 and a minimum flexural strength of 1500 psi (fn-s/sq.d).

In one particular embodiment, the insulator 11 is made of mica. Alternatively, Insulator 11 can be made of a solid dielectric material that can withstand temperatures exceeding approximately 10002E without changing its state.

The stinger 2 is attached to the housing 3 in the usual way - preferably with the possibility of detachment

Change widely for use in various soldering options. The availability of a detachable tip also allows you to use different tips for different applications with the same tool. After fixing, the electrodes 9 and 10 are separately electrically connected in the usual way to the positive and negative terminals of the power supply 8. A variety of power supplies can be used, including rechargeable batteries or non-rechargeable batteries, or low voltage 7/0 obtained from the mains voltage via a transformer. The power supply in accordance with Fig. 1 is a pair of nickel-cadmium batteries located inside the case 3, which provide a nominal voltage of 2.4 volts and 700-750 milliampere-hours. Optionally, the electrodes 9 and 10 can be electrically isolated from the power supply means 8 using a switch or other means of interrupting the flow of current in the electrical circuit.

When both electrodes 9 and 10 are applied to an electrically conductive or semiconducting material, such as solder, an electric circuit is closed, which goes from the positive terminal of the power supply 8, through the electrode 9, through the electrically conductive or semiconducting material on which the sting is applied, through the electrode 10 to of the negative terminal of the 8 power supply. The flow of current causes the electrodes 9 and 10 to heat up to a temperature of about 6002E or more within a few seconds, allowing the tool to be used in the same manner as a conventional soldering iron. With this arrangement, the proposed device provides an alternating current equivalent in power to the application of approximately 25-50 watts of heat to the joint to be soldered. An additional property of the preferred electrode material is that it cannot be soldered to the joint during use. When the user of the device wants to stop heating, the device can be removed from the conductive or semiconducting material by interrupting the flow of current. Ha

When the current supply is interrupted, the electrodes cool within seconds to a temperature safe for contact with human skin or clothing. at

The device - optionally - includes a conventional electric light bulb 4, for example, an incandescent bulb or a light-emitting diode. As shown in Fig.1, the light bulb 4 is located on the housing C in such a way that the light emitted by it will illuminate the stinger 2 and the surrounding working area during use. As shown in Fig. 5, the light bulb 4 is usually electrically connected to the power supply 8, and it is controlled by the switch 5. When the switch 5 is closed, the circuit coming from one terminal of the power supply 8 is also closed - through the switch 5, through the electric bulb 4 to the terminal of the opposite polarity of the power supply 8, which (o provides illumination with the help of the electric bulb 4 without supplying electricity to the sting 2. Since the electric bulb 4 can be turned on without heating the sting 2, this bulb can be used to illuminate the space that surrounds the user, without the risk of accidentally burning the user or igniting nearby flammable materials.

As shown in Fig. 1, the device can be additionally - optionally - provided with a node for monitoring the integrity of the circles, which has an output b for monitoring the integrity of the circles and a probe 7 for monitoring the integrity of the circles. Terminal b " additionally includes a wire 12, for example, a 26-gauge wire, passing from the housing 3, which is located at one end of the wire, and has an alligator clip 13 attached to the distal end - from the wire 12. Probe 7 for for checking the integrity of the circles is a probe similar to those used in conventional electrical control equipment, for example, a short rigid electrically conductive needle-shaped "" probe. Those skilled in the art will easily understand that within the scope of the claims and the purpose of the invention, a control output the integrity of the circles and the probe for checking the integrity of the circles can be made of any electrically conductive material. As shown in Fig. 5, the pin 6 for checking the integrity of the circles is electrically connected -I with the means of power supply 8 by means of a circuit passing through the light bulb 4. The probe 7 is connected to the terminal of the opposite polarity of the power supply 8. Referring to Fig. 5, we note that the sting

Ф is connected in series with means 8 of power supply. A conductor 20 is provided in parallel with the sting. A light bulb 4 and a (axis) switch 5 are located in series along the conductor 20. The terminal 6 is connected to the conductor 20 in connection 22, which is a bush 50 located between the light bulb 4 and the switch 5. This node is used to control the circuit by attaching the alligator clip 13 to one side of the wheel being monitored, and touching the probe 7 to the opposite side of the wheel. If the monitored circuit is electrically unbroken, then the current will flow from the means of power supply 8, through the electric bulb 4, through the terminal b for monitoring the integrity of the circuits, through the monitored circuit, through the probe 7 for monitoring the integrity of the circuits and back to the means of power supply 8, as a result, the circuit is closed and the light bulb 4 lights up. The light bulb 4 quickly demonstrates the integrity of the monitored circuit. This particular embodiment is useful, in particular, for i) cordless soldering irons, since the user can control the soldered connection without needing to obtain a name) or carry a separate tool.

As shown in Fig. 1, there are end caps 14 and 15 to protect the sting 2 and the terminal 16 to control the integrity of the circles from damage. The end caps are removably attached to the body by conventional means, such as friction fit, clamping, threaded surfaces, etc.

Although a preferred specific embodiment has been illustrated and described, it should be understood that various changes may be made within the scope of the claims of the invention.

Specific variants of the invention, in which the right or privilege of exclusive ownership is claimed, 65 are characterized by the following claims.

Claims (42)

The formula of the invention 1. A tip assembly for a soldering iron powered by a power supply that contains two 9 electrodes, each having an electrical resistivity of 1500 µOhm'cm or more, a thermal conductivity of less than British thermal units per hour per foot degree Fahrenheit (BTO /h'ftR) or equal thereto, a flexural strength of at least about 1,500 pounds-force per square inch (fn-s/sq.d) and a density of about 1.5 to 1.75 g/cm, and each electrically insulated from the other by an insulator located between the /p0 electrodes, and each of the electrodes has a configuration that provides a separate electrical connection to the positive and negative terminals of the power supply. 2. Sting assembly according to claim 1, in which each electrode has a thermal conductivity of 1 to 10 BTO/h: ft o. 3. Sting assembly according to claim 1, in which each electrode has an electrical resistivity greater than 3000 μΩ' cm. 4. Sting assembly according to claim 3, in which each electrode has a thermal conductivity of 1 to 10 BTO/h ft eE. 12 5. Soldering iron fed by means of an electric supply, which contains a soldering tip containing two electrodes, each of which has an electrical resistivity of 1500 μOhm' cm or more, a thermal conductivity of less than or equal to 10 BTO/h ft eE, a flexural strength of at least about 1500 fn-s/sq.d and a density of about 1.5 to 1.75 g/cm, and each electrically isolated from the other by an insulator located between the 20 electrodes, each of the electrodes being separately electrically connected with the positive and negative terminals of the power supply. 6. Soldering iron according to claim 5, in which each electrode has a thermal conductivity from 1 to 10 BTO/h' ft R. 7. Soldering iron according to claim 5, in which each electrode has an electrical resistivity greater than 3000 μΩ cm. 8. Soldering iron according to claim 7, in which each electrode has a thermal conductivity of from 1 to 10 BTO/h' ft oR. p. 29 9. A soldering device comprising a tip attached to a housing and a power source, wherein the tip is rigidly held in place by the housing and consists of two electrodes, each of which has an electrical resistivity of 1500 μOhm cm or more, a thermal conductivity, of less than or equal to 10 BTO/hr ft "PE, a flexural strength of at least about 1500 fn-s/sq.d and a density of about 1.5 to 1.75 g/cm, « zr | Each electrically isolated from the other an insulator located between the electrodes, and each of the electrodes is separately electrically connected to the positive and negative terminals of the power supply, and the body (-zh7 is an elongated, essentially tubular element made of any rigid heat-resistant material. 10. The device according to claim 9, in which each electrode has a thermal conductivity of 1 to 10 BTO/h: ft or. 11. The device according to claim 9, in which each electrode has an electrical resistivity greater than 3000 μΩ'cm. what 12. The device according to claim 11, in which each electrode has a thermal conductivity of from 1 to 10 BTO/hour'ft R. - 13. A soldering device containing a power source and a heating device, electrically connected to the power source in such a way that a current can be transmitted through a part of this device, and the heating device has an electrical resistivity of 1500 μOhm'cm or more, a bending strength " at least about 1500 fn-s/sq.d and a density of about 1.5 to 1.75 g/cm". 14. The device according to claim 13, in which the heating device has a thermal conductivity of less than or equal to 10 BTO/hour-foot. :with" 15. The device according to claim 14, in which the heating device has an electrical resistivity greater than 3000 μΩ' cm. 16. The device according to claim 13, in which the heating device has an electrical resistivity greater than 3000 μΩ' cm. 17. The device according to claim 13, in which the heating device is a soldering iron tip. -AND 18. The device according to claim 17, in which the tip of the soldering iron contains first and second electrodes. 19. The device according to claim 13, which is a soldering iron. b 20. The device of claim 13, wherein the heating device includes graphite. at 21. The device according to claim 13, in which the power source includes at least one battery. tsu 5 22. The device according to claim 13, which also includes a housing made of a heat-resistant material. 23. A soldering device comprising a housing, a battery power source connected to the housing, and the battery power source includes positive and negative terminals, and a heating element connected to the housing, and this heating element is connected with a positive or negative terminal, and wherein the heating element is made of a material having an electrical resistivity of 1500 µOhm'cm or more, a flexural strength of at least about 1500 fn-s/sq.d, and a density of about 1.5 to 1 .75 g/cm. 24. The device according to claim 23, in which the body is made of a heat-resistant material. name) 25. The device according to claim 23, in which the battery power source includes at least one battery. 60 26. The device according to claim 23, in which the heating element has a thermal conductivity of less than or equal to 10 BTO/h'futoER. 27. The device according to claim 23, in which the heating element has an electrical resistivity greater than 3000 μΩ'cm. 28. The device of claim 27, wherein the heating element has a thermal conductivity of less than or equal to 10 BTO/hour'ftE. 29. The device according to claim 23, in which the heating element includes graphite. 30. The device according to claim 23, which is a soldering iron. 31. A soldering device comprising an electrically conductive structure and at least one heating element electrically coupled to the electrically conductive structure, wherein the heating element has an electrical resistivity of 1500 μΩcm or more, a bending strength of at least about 1500 fn-s/sq.d and density from about 1.5 to 1.75 g/cm? 32. The device of claim 31, wherein the heating element has a thermal conductivity of less than or equal to 10 BTO/hour'ftE. 33. The device according to claim 32, in which the heating element has an electrical resistivity greater than 3000 μΩ'cm. then 34. The device according to claim 31, in which the heating element has an electrical resistivity greater than 3000 μΩ'cm. 35. The device according to claim 31, which is a soldering iron. 36. The device according to claim 31, in which the heating element includes graphite. 37. Electronic circuit for a soldering device containing a power source connected electrically 75 to at least one heating element, wherein the heating element has an electrical resistivity of 1500 μOhm-cm or more, a bending strength of at least about 1500 fn- s/sq.d and density from approximately 1.5 to 1.75 g/cm. 38. An electronic circuit according to claim 37, in which the heating element has a thermal conductivity of less than or equal to 10 BTU/h: ft "E. 39. Electronic circuit according to claim 38, in which the heating element has an electrical resistivity greater than 3000 MkΩm cm. 40. Electronic circuit according to claim 37, in which the heating element has an electrical resistivity greater than 3000 MkΩm cm. 41. Electronic circuit according to claim 37, in which the power source includes at least one battery. with 42. Electronic circuit according to claim 37, in which the heating element includes graphite. Ge) « «- (ee) (Se) and - - and? -i (o) (ee) - 70 s» ime) 60 b5