Positive temperature coefficient heater

A positive temperature coefficient heater may include at least one positive temperature coefficient rod having a heating module inserted into a rod case made of brass and plated with tin, at least one heat-radiating fin made of brass, plated with tin, and contacted and coupled with each of opposite outer faces of the positive temperature coefficient rod, and upper and lower housings coupled to opposite longitudinal ends of the positive temperature coefficient rod, wherein the positive temperature coefficient rod and the heat-radiating fin are joined together by soldered portions.

CROSS-REFERENCE TO RELATED APPLICATION

The present application claims priority to Korean Patent Application Number 10-2008-123654 filed on Dec. 5, 2008, the entire contents of which application is incorporated herein for all purposes by this reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a positive temperature coefficient (PTC) heater, and more particularly, to a PTC heater in which a PTC rod and a heat-radiating fin are joined together by soldering, thereby improving a coupling force and heat transfer efficiency, increasing durability due to the improved coupling force, making it possible to remove side frames as well as a cover of the heat-radiating fin to reduce material cost and weight, particularly in which the soldering is performed in a relative low-temperature state using a tin solder, thereby preventing characteristics of a PTC element from being varied during the soldering, and thus smoothly exerting performance of the PTC element.

2. Description of Related Art

A vehicle is equipped with an air conditioning system for selectively supplying cold and warm air to the inside thereof. In the summer season, an air conditioner is actuated to supply the cold air. In the winter season, a heater is actuated to supply the warm air.

In general, the heater is based on a heating system in which a coolant heated by circulating through an engine exchanges heat with air introduced by a fan, so that warmed air is supplied to the inside of the vehicle. This heating system has high energy efficiency because it uses the heat generated from the engine.

However, in the winter season, it takes some time until the engine is heated after starting. Thus, after starting, the heating is not immediately performed. As such, for the heating, the engine often idles for a predetermined time prior to moving the vehicle until the engine is heated to raise the temperature of the coolant. This idling of the engine causes energy consumption and environmental pollution.

In order to prevent this problem, a use has been made of a method of heating the interior of the vehicle using a separate pre-heater for a predetermined time when the engine is being warmed up. A conventional heater using a heating coil effectively performs the heating due to a high quantity of heat, but its parts are frequently repaired and exchanged due to a short lifetime of the heating coil.

Thus, a heater using a positive temperature coefficient (PTC) element has recently been developed. This PTC heater has low fire danger, and can guarantee semi-permanent use due to a long lifetime. For this reason, the coverage of the PTC heater becomes very wide. Further, the PTC heater used for the pre-heater by nature generally has a relatively small capacity. Recently, there has been a tendency to develop a high capacity of PTC heater due to diversification of the vehicle and user's demand.

FIGS. 1 and 2are schematic exploded perspective views illustrating the structure of an exemplary PTC heater.

As illustrated inFIGS. 1 and 2, the PTC heater generally includes a plurality of PTC rods10, each of which has a built-in PTC element and an anode terminal11protruding from one end thereof and is electrically heated to generate heat, heat-radiating fin modules20, which are coupled in close contact with opposite sides of the respective PTC rods10in pairs, cathode terminals30disposed in parallel between the neighboring heat-radiating fin modules20, and upper and lower housings40and50coupled to opposite longitudinal ends of the PTC rods10.

At this time, in order to allow the PTC rods10, heat-radiating fin modules20and cathode terminals30, all of which are disposed parallel to one another, to be coupled in close contact with each other between the upper and lower housings40and50, the outermost heat-radiating fin modules20are mounted with side frames60on left-hand and right-hand outer sides thereof. In detail, the side frames60are curved inwards, and are coupled to the upper and lower housings40and50. The PTC rods10, heat-radiating fin modules20and cathode terminals30are coupled in close contact with one another by means of an elastic contact force of the curved side frames60. This coupling allows elasticity and heat to be efficiently transferred among the PTC rods10, heat-radiating fin modules20and cathode terminals30. As a result, the entire structure of the PTC heater is formed.

Meanwhile, as illustrated inFIG. 1, each heat-radiating fin module20is for increasing efficiency with which each PTC rod10exchanges heat with air, and includes a heat-radiating fin21corrugated in a lengthwise direction so as to increase a contact area with air, a case22fixedly holding the heat-radiating fin21, and a cover23fastened to the case22by bolts24so as to close an open side of the case22. Here, in order to fix the heat-radiating fin21as a component for substantially improving the heat-exchange efficiency, the case22and cover23are separately prepared such that the heat-radiating fin21is prevented from being separated or moving from the PTC rod10.

Thus, each heat-radiating fin module20is complicated when manufactured, and increases the number of parts, because the case22and cover23are additionally required to fix the heat-radiating fin21. In order to solve this problem, the method of manufacturing the PTC heater is changed. For example, as illustrated inFIG. 2, a method of manufacturing each heat-radiating fin module20′ using a simple fin guide25and heat-radiating fin21has been developed. In this method, the heat-radiating fin module20′ also requires the fin guide25to fix the heat-radiating fin21, and the fin guide25is configured so that opposite edges thereof are bent into flanges25a. Although this structure can be regarded to be simpler than that ofFIG. 1, the heat-radiating fin module20′ still suffers from a complicated manufacturing process and a number of parts.

Further, since this heat-radiating fin module20or20′ is configured so that the separate part, i.e. the case22or the fin guide25, is interposed between the heat-radiating fin21and the PTC rod10, heat transfer efficiency with which the heat emitted from the PTC rod10is transferred to the heat-radiating fin21is lowered. Furthermore, since the contact between the PTC rod10and the heat-radiating fin21is caused by the elastic contact force of the side frames60, the contact is dependent upon surface roughness of the PTC rod10and/or the heat-radiating fin21, and thus the heat transfer efficiency is lowered.

BRIEF SUMMARY OF THE INVENTION

Various aspects of the present invention are directed to provide a positive temperature coefficient (PTC) heater, in which a PTC rod and a heat-radiating fin are joined together by soldering, thereby improving a coupling force and heat transfer efficiency, increasing durability due to the improved coupling force, making it possible to remove side frames as well as a cover of the heat-radiating fin to reduce material cost and weight, particularly in which the soldering is performed in a relative low-temperature state using a tin solder, thereby preventing characteristics of the PTC element from being varied during the soldering, and thus smoothly exerting performance of the PTC element.

In an aspect of the present invention, a method of manufacturing a positive temperature coefficient heater, may include plating a rod case of brass with tin, plating a heat-radiating fin of brass with tin, inserting a heating module into the rod case so as to assemble a positive temperature coefficient rod, temporarily coupling the positive temperature coefficient rod with the heat-radiating fin using a separate fixture, and joining the positive temperature coefficient rod and the heat-radiating fin together by means of soldering, and coupling upper and lower housings to opposite longitudinal ends of the positive temperature coefficient rod and the heat-radiating fin.

The soldering may use a lead-free solder, wherein the soldering is performed when side frames, which are linear in a longitudinal direction, are mounted on outer sides of the outermost heat-radiating fins after the positive temperature coefficient rod is temporarily coupled with the heat-radiating fin.

In another aspect of the present invention, the positive temperature coefficient heater may include at least one positive temperature coefficient rod having a heating module inserted into a rod case made of brass and plated with tin, at least one heat-radiating fin made of brass, plated with tin, and contacted and coupled with each of opposite outer faces of the positive temperature coefficient rod, and upper and lower housings coupled to opposite longitudinal ends of the positive temperature coefficient rod, wherein the positive temperature coefficient rod and the heat-radiating fin are joined together by soldered portions.

The upper and lower housings may be coupled with side frames, which are linear in a longitudinal direction, at opposite ends thereof, wherein the side frames are mounted on the outer sides of the outermost heat-radiating fins.

The rod case may have a closed cross section.

The heating module may include a PTC element, an anode terminal, and an insulator disposed in the rod case and configured to electrically insulating the anode terminal from the rod case.

According to embodiments of the present invention, since the PTC rod and the heat-radiating fin are joined together by soldering, the PTC heater improves a coupling force and heat transfer efficiency, increases durability due to the improved coupling force, makes it possible to remove the side frames as well as the cover of the heat-radiating fin to reduce material cost and weight. Particularly, the soldering is performed in a relative low-temperature state using the thin solder, thereby preventing characteristics of the PTC element from being varied during the soldering, and thus smoothly exerting performance of the PTC element.

DETAILED DESCRIPTION OF THE INVENTION

In various embodiments, a method of manufacturing a positive temperature coefficient (PTC) heater includes plating a rod case11of brass with tin (S1), plating a heat-radiating fin21of brass with tin (S2), inserting a heating module into the rod case11so as to assemble a PTC rod10(S3), temporarily coupling the PTC rod10with the heat-radiating fin21using a separate fixture and joining the PTC rod10and the heat-radiating fin21together by means of soldering (S4and S5), and coupling upper and lower housings40and50to opposite longitudinal ends of the PTC rod10and the heat-radiating fin21(S6).

In other embodiments, a PTC heater includes a PTC rod10having a heating module inserted into a rod case11of brass plated with tin, a heat-radiating fin21of brass plated with tin, and contacted and coupled with each of opposite faces of the PTC rod10, and upper and lower housings40and50coupled to opposite longitudinal ends of the PTC rod10, wherein the PTC rod10and the heat-radiating fin21are joined together by soldered portions.

FIG. 3is a flow chart illustrating a method of manufacturing a PTC heater according to various embodiments of the present invention.FIG. 4is a schematic sectional view illustrating the internal structure of a PTC heater according to various embodiments of the present invention.

According to various embodiments of the present invention, the PCT heater includes at least one PTC rod10, at least one heat-radiating fin21, and upper and lower housings40and50. Cathode terminals are disposed parallel to the heat-radiating fins21as in the prior art. Alternatively, the cathode terminals may be separately coupled to the upper housing40so as to come into contact with outer sides of the PTC rods10.

The PTC rod10is configured so that a heating module capable of electrically generating heat is inserted into a rod case11. As illustrated inFIG. 4, the heating module includes a PTC element18electrically generating heat, an anode terminal17supplied with electricity, and an insulator12electrically insulating the anode terminal17from the rod case11.

According to various embodiments of the present invention, the PCT heater is different from prior PTC heaters in that components thereof are joined together by soldering rather than by elastic contact force of side frames. Thus, the rod case11and the heat-radiating fin21are made of brass, are plated with tin (Sn), and are joined together by soldering, so that heat transfer efficiency between the PTC rod10and the heat-radiating fin21is improved.

More specifically, in the PTC heater, the PTC rod10has the heating module inserted into the rod case11, which is made of brass and is plated with tin. The heat-radiating fin21is made of brass, is plated with tin, and is contacted and coupled with each of opposite faces of the PTC rod10. The upper and lower housings40and50are coupled to opposite longitudinal ends of the PTC rod10, respectively. Here, the PTC rod10and the heat-radiating fin21are joined together by soldering.

Further, the side frames60are disposed on outer sides of the heat-radiating fins21at opposite ends of the upper and lower housings40and50so as to form a frame structure along with the upper and lower housings40and50(seeFIGS. 1 and 2). Since the side frames60are not required to apply the elastic contact force to the PTC rods10and the heat-radiating fins21unlike prior side frames, they are not curved in a longitudinal direction, but are linear in the longitudinal direction so as to be mounted in use for the frame structure.

As for a method of manufacturing the PTC heater according to various embodiments of the present invention, first, the rod case11is made of brass and is then plated with tin (S1). The heat-radiating fin21is made of brass and is then plated with tin (S2). The heating module is inserted into the rod case11, thereby assembling the PTC rod10(S3). In this state, the PTC rod10is temporarily coupled with the heat-radiating fin21using a separate fixture (S4), and then the PTC rod10and the heat-radiating fin21are joined together with a solder by soldering (S5). The upper and lower housings40and50are coupled to opposite longitudinal ends of the PTC rod10and the heat-radiating fin21(S6). Thereby, the PTC heater is manufactured.

At this time, the solder for the soldering includes a lead (Pb)-free solder.

Meanwhile, the side frames can be removed from the PTC heater. However, according to various embodiments of the present invention, the side frames are mounted on the outer sides of the outermost heat-radiating fins21. To this end, the side frames, which are linear in the longitudinal direction, are mounted on the outer sides of the outermost heat-radiating fins21in the state in which the PTC rod10is temporarily coupled with the heat-radiating fin21using a separate fixture. Afterwards, the side frames are soldered to the heat-radiating fins21. However, according to other embodiments of the present invention, the PTC heater can be configured in such a manner that the side frames are not separately mounted.

According to various embodiments of the present invention, since the PTC rod and the heat-radiating fin are joined together by soldering, the PTC heater improves a coupling force and heat transfer efficiency, increases durability due to the improved coupling force, makes it possible to remove the side frames as well as the cover of the heat-radiating fin to reduce material cost and weight. Particularly, the soldering is performed in a relatively low-temperature state using the thin solder, thereby preventing characteristics of the PTC element from being varied during the soldering, and thus smoothly exerting performance of the PTC element.

For convenience in explanation and accurate definition in the appended claims, the terms “upper”, “lower”, “inside”, and “outer” are used to describe features of the exemplary embodiments with reference to the positions of such features as displayed in the figures.