Background of The Invention Ceramic heater devices are well known in the art. The ceramic heater tip of a glow plug is generally a cylindrical element which is brazed to a metallic body or housing. However, the brazing is susceptible to failure due to the high combustion chamber pressures and temperature.

Further, such cylindrical ceramic heater tips become caked with a carbon coating during normal use. If service is required for the glow plug, the glow plug must be extracted from the cylinder head. The carbon build-up on the ceramic tip tends to lock the ceramic tip in the cylinder head. As the repairer removes the metallic body, the ceramic tip occasionally becomes dislodged from the metallic body and remains in the cylinder head, which is highly undesirable.

Attempts have been made to address this problem by improving the mechanical joint structure for positively retaining the ceramic heating tip within the bore of the body of the glow plug, as disclosed in U.S. Patent No. 5,084,607. However, this proposed design requires additional precision parts to be manufactured, and thus increases the cost of the glow plug.

Summary of the Invention The disadvantages of the prior art may be overcome by providing a ceramic heating device having a tapered ceramic heating tip wedgingly engaging a bore of a body of a glow plug.

According to one aspect of the invention, there is provided a ceramic heating device comprising a metallic body having a central bore and means for securing the metallic body to a cylinder head of an engine, a ceramic heater portion having a tapered body, conduction means for electrically connecting a core of the ceramic heater portion, and fitting means for frictionally securing the ceramic heater portion within the central bore in electrical contact with the metallic body and positioning a distal tip of the ceramic heater portion longitudinally from the metallic body.

According to another aspect of the invention, there is provided a ceramic heating device comprising a metallic body having a central bore and means for securing the metallic body to a cylinder head of an engine, a ceramic heater portion having a tapered body, a conductor for electrically connecting a core of the ceramic heater portion, an annular ring fitted within the central bore for frictionally securing the ceramic heater portion within the central bore in electrical contact with the metallic body and positioning a distal tip of the ceramic heater portion longitudinally from the metallic body. The conductor extends through the bore in electrically contact with a core of the ceramic heater portion. An insulator cap closes the bore and the conductor extends through the cap. The annular ring has an inner bore having a taper complementary to the taper of the ceramic heater portion. The annular ring abuts a flange at a distal end of the central bore. The central bore is filled with epoxy to secure the ceramic heater portion in the distal end of the metallic body.

According to another aspect of the invention, there is provided a ceramic heater for a glow plug comprising a metallic body having a central bore, a conductor electrically connected to the ceramic heater and insulated from the metallic body. The ceramic heater has a tapered body for frictionally engaging within the central bore in electrical contact with the metallic body.

According to another aspect of the invention, there is provided a glow plug having an annular ring fitted within a central bore. The annular ring has an inner bore having a taper complementary to the tapered body of the ceramic heater portion.

According to another aspect of the invention, there is provided a flow plug having a tapered annular bore. The taper is complementary to the tapered body of the ceramic heater portion.

Description of the Drawings In drawings which illustrate embodiments of the invention Figure 1 is a side sectional view of the ceramic heating device of the present invention; Figure 2 is a detailed sectional view of the interconnection between a tapered ceramic tip and an inner bore of a metallic body of the ceramic heating device of the embodiment of Figure 1; and Figure 3 is a detailed sectional view of the interconnection between the tapered ceramic tip and an inner bore of a metallic body of the ceramic heating device of a second embodiment.

Description of the Invention The ceramic heating device of the present invention is generally illustrated in Figure 1 as glow plug 10. Glow plug 10 includes a rigid metallic body 12 having a central longitudinal bore 14 extending therethrough. A circumferentially extending lip or flange 16 extends into bore 14 at the distal end of barrel 18. Barrel 18 has an external thread 20 for threadably engaging or securing the glow plug 10 in an internal threaded bore of the cylinder head of a diesel engine (not shown). Body 12 also has a head 22 having a hex nut configuration for mechanically rotating the body 12.

The ceramic heater portion 24 has a generally tapered body. The distal end 26 of ceramic heater portion 24 is of a conventional design well known in the art (see for example U.S. Patent Nos. 5,519,187, 4,742,095, and 3,04,778). Generally, the ceramic heater portion 24 comprises three layers comprising a ceramic rod core 28, an annular ceramic tubular member 30 and a ceramic outer tube 32 sintered to the tubular member 30.

A conduction means, shown as conductor wire 34 extends centrally through the bore 14 and is insulated from the metallic body 12. Non-metallic insulator cap 36 is fitted in a near end of bore 14. A connector cap 38 is fitted on the exposed end of conductive wire 34.

Conductor wire 34 extends through the insulator cap 36 to the ceramic rod core 28 of ceramic heater portion 24.

The near end of ceramic heater portion 24 abuts with a fitting means, shown as conductive annular sleeve 40, so that the distal tip 26 extends longitudinally from the metallic body 12 a predetermined distance. The inner bore surface of sleeve 40 is tapered to complementarily fit with the taper of ceramic heater portion 24. The cavity in bore 14 between non-metallic insulator cap 36 and the near end of ceramic heater portion 24 is filled with an epoxy resin filler 42.

To assemble, conductive sleeve 40 is concentrically inserted into bore 14 to abut with lip 16 at the distal end of barrel 18. Ceramic heater portion 24 is then inserted into bore 14 to become frictionally engaged within conductive annular sleeve 40 in a wedged manner, thereby permitting ceramic heater portion 24 to electrically contact body 12. The distal end of conductive wire 34 is firmly fitted within and in electrical contact with an end bore 44 of ceramic rod core 28 of ceramic heater portion 24. The bore 14 is filled with epoxy resin filler 42 for curing therein. Epoxy 42 secures ceramic heater portion 24 in frictional engagement and electrical contact with metallic body 12. Non-metallic insulator cap 36 is fitted over the end of conductive wire 34 to support the conductive wire 34, while epoxy resin filler 42 cures.

Connector cap 38 is then placed over the near end of conductive wire 34.

The ceramic heater device of the present invention is ready to be used in a conventional manner in replacement of any existing glow plug. It is readily understood that the size of the glow plug 10 is dictated by the specific diesel engine in which the glow plug 10 is to be used.

On removing the glow plug 10 from the cylinder head, it is apparent that the positive wedge fitting between the ceramic heater portion 24 and conductive annular sleeve 40 will provide a positive wedge force to the ceramic heater portion 24 to remove same as the body 12 is being urged out of cylinder head. The positive wedge force prevents the ceramic heater portion 24 from coming out of the body 12 and remaining in the cylinder head.

Referring to Figure 3, a second embodiment of the present invention is illustrated.

Metallic body 50 has a barrel 52 having a central bore 54. The distal end of the bore 54 has a fitting means, shown as an inner circumferential tapered surface 56 which is complementary to the taper of the ceramic heater portion 24. Ceramic heater portion 24 will frictionally engage tapered surface 56 in a wedged manner. Tapered surface 56 is positioned along the bore 54 such that the distal tip 26 of the ceramic heater portion extends longitudinally from the metallic body 50 a predetermined distance.

Although a preferred embodiment has been described in detail above, those of ordinary skill in the art will recognize that modifications are possible without departing from the teachings of the present invention. All such modifications are intended to be encompassed herein.