I. Field
The present invention relates generally to electronic protection circuitry. More, specifically, the present invention relates to a self-activating surface mount thermal fuse.
II. Background Details
Protection circuits are often times utilized in electronic circuits to isolate failed circuits from other circuits. For example, a protection circuit may be utilized to prevent a cascade failure of circuit modules in an electronic automotive engine controller. Protection circuits may also be utilized to guard against more serious problems, such as a fire caused by a power supply circuit failure.
One type of protection circuit is a thermal fuse. A thermal fuse functions similar to that of a typical glass fuse. That is, under normal operating conditions the fuse behaves like a short circuit and during a fault condition the fuse behaves like an open circuit. Thermal fuses transition between these two modes of operation when the temperature of the thermal fuse exceeds a specified temperature. To facilitate these modes, thermal fuses include a conduction element, such as a fusible wire, a set of metal contacts, or set of soldered metal contacts, that can switch from a conductive to a non-conductive state. A sensing element may also be incorporated. The physical state of the sensing element changes with respect to the temperature of the sensing element. For example, the sensing element may correspond to a low melting metal alloy or a discrete melting organic compound that melts at an activation temperature. When the sensing element changes state, the conduction element switches from the conductive to the non-conductive state by physically interrupting an electrical conduction path.
In operation, current flows through the fuse element. Once the sensing element reaches the specified temperature, it changes state and the conduction element switches from the conductive to the non-conductive state.
One disadvantage with existing thermal fuses is that during installation of the thermal fuse, care must be taken to prevent the thermal fuse from reaching the temperature at which the sensing element changes state. As a result, existing thermal fuses cannot be mounted to a circuit panel via reflow ovens, which operate at temperatures that will cause the sensing element to open prematurely.
In one aspect, a reflowable thermal fuse includes a positive-temperature-coefficient (PTC) device with first and second ends, a conduction element with a first end in electrical communication with the second end of the PTC device, and a restraining element, with a first end in electrical communication with the first end of the PTC device and a second end in electrical communication with a second end of the conduction element. The restraining element is adapted to prevent the conduction element from coming out of electrical communication with the PTC device in an installation state of the thermal fuse. During a fault condition, heat applied to the thermal fuse causes current flowing between the first end of the PTC device and the second end of the conduction element to be diverted to the restraining element, causing the restraining element to release the conduction element and activate the fuse.
In another aspect, a method for placing a reflowable thermal fuse on a panel includes providing a reflowable thermal fuse as described above. The reflowable thermal fuse is then placed on a panel that includes pads for soldering the surface mountable fuse to the panel. The panel is then run through a reflow oven so as to solder the surface mountable fuse to the panel.
To overcome the problems described above, a reflowable thermal fuse is provided. Generally, the reflowable thermal fuse includes a conduction element through which a load current flows, a positive-temperature-coefficient (PTC) device, and a restraining element. The restraining element is utilized to keep the conduction element in a closed state during a reflow process.
Under normal operating conditions, current that flows into the reflowable thermal fuse flows primarily through the PTC device and the conduction element. Some current also flows through the restraining element. During a high temperature and/or high current fault condition, the resistance of the PTC device increases. This in turn causes current flowing through the PTC device to be diverted to the restraining element until the restraining element mechanically opens. After the restraining element opens, the conduction element is allowed to enter an open state. In some embodiments, a high ambient temperature around the reflowable thermal fuse causes the sensor to lose resilience and/or melt. This in turn enables the conduction element to enter the open state. In other embodiments, current flowing into the reflowable thermal fuse and through the PTC device causes the PTC device to generate enough heat to cause the sensor to lose resilience and/or melt and thereby release the conduction element.
The details of the reflowable thermal fuse are set out in more detail below. The accompanying drawings are included to provide a further understanding and are incorporated in and constitute a part of this specification.
As shown in
Referring back to
Referring to
The current 310 through the PTC device 105 corresponds to the resistance 305 of the PTC device 105 over the voltage across the PTC device 105. The current 310 may be inversely proportional to the resistance 305 of the PTC device 105. As shown, as the resistance 305 increases, the current 310 decreases until almost no current flows through the PTC device 105.
Referring back to
The restraining element 115 may include a first end in electrical communication with the first end of the PTC device 105 and a second end in electrical communication with a second end of the conduction element 110. The restraining element 115 is adapted to prevent the conduction element 110 from coming out of electrical communication with the PTC device 105 during an installation state of the reflowable thermal fuse 100. For example, one end of the restraining element 115 element may be physically attached to the conduction element 110 and the other end may be physically attached to the housing and/or substrate.
The restraining element 115 may correspond to any material capable of conducting electricity. For example, the restraining element 115 may be made of copper, stainless steel, or an alloy. The diameter of the restraining element 115 may be sized so as to enable blowing, or opening, the restraining element 115 during a fault condition. In one embodiment, the restraining element 115 opens when a current of about 1 Ampere flows through it. Applicants contemplate that the restraining element 115 may be increased or decrease in diameter, and/or another dimension, allowing for higher or lower currents.
The PTC device 105 may be disposed below the conduction element 110, as shown. A first end of the PTC device 105 may be in electrical communication with a second pad 210.
The restraining element 115 may be draped over a portion of the conduction element 110 and fixed to the first and second pads 205 and 210 as shown.
During the reflow process, the sensor of the conduction element may lose its holding strength. For example, in a sensor made of solder, the solder may melt. However, the solder may be held in place via the surface tension of the solder. The restraining element may prevent the conduction element from mechanically opening during the reflow process. After reflowing, the panel is allowed to cool at which time the sensor may once again regain its holding strength.
At block 505, the reflowable thermal fuse 100 may be utilized in a non-fault condition state. Referring to
At block 510, a fault condition may occur. For example, the ambient temperature in the vicinity of the reflowable thermal fuse 100 may increase to a dangerous level, such as 200° C.
At block 515, the resistance of the PTC device 105 may begin to increase with increases in the ambient temperature, as described in
At block 520, the current flowing through the restraining element 115 reaches a point that causes the restraining element 115 to mechanically open, thus releasing the conduction element 110.
At block 525, the conduction element 110 may mechanically open. The conduction element 110 may open immediately after the restraining element 115 releases the conduction element 110. For example, the sensor of the conduction element 110 may have already lost its holding strength. Alternatively, the ambient temperature around the reflowable thermal fuse 100 may continue to increase and the sensor may give way at an elevated temperature. In yet another alternative, the current flowing into the reflowable thermal fuse 100 and through the PTC device 105 may cause the PTC device 105 to self heat to temperature sufficient enough to cause the sensor of the conduction element 110 to lose its holding strength.
As can be seen from the description above, the reflowable thermal fuse overcomes the problems associated with placement of thermal fuses on panels via reflow ovens. The restraining element enables securing the conduction element during the reflow process. Then during a fault condition, the PTC device effectively directs the current flowing through the reflowable thermal fuse to the restraining element, which in turn causes the restraining element to open. This in turn releases the conduction element.
While the reflowable thermal fuse and the method for using the reflowable thermal fuse have been described with reference to certain embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the claims of the application. In addition, many modifications may be made to adapt a particular situation or material to the teachings without departing from its scope. Therefore, it is intended that reflowable thermal fuse and method for using the reflowable thermal fuse are not to be limited to the particular embodiments disclosed, but to any embodiments that fall within the scope of the claims.