JPH0319387A - Hybrid integrated circuit - Google Patents

Abstract

PURPOSE:To protect an integrated circuit of this design from malfunction even if a conductor is disconnected near the end face of a protective glass film by a method wherein a part of a conductor continuously formed on a substrate covered with a protective glass film and an exposed part of the conductor which serves as a component mounting section are connected to each other with a resistor formed on the substrated concerned. CONSTITUTION:A conductor pattern 2 is formed on a ceramic substrate 1 to constitute a thick film circuit, and a protective glass film 3 is formed covering the conductor 2. The conductor 2 and the protective glass film 3 are formed respectively in such a manner that Ag conductive paste and glass paste are printed and burned. The protective glass film 3 is not formed on a component mounting section 2A of the conductor 2 so as to make it exposed. A resistor 6 or Ru resistor paste is previously printed and burned under the conductors 2A and 2B near the end face 3A of the glass film 3. By this constitution, even if corrosion 7 advances from the end face 3A of the glass protective film 3 to make the conductor 2 disconnected, electrical conduction can be secured by the lower resistor 6 at a resistance value of a few to hundreds of OMEGA.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to hybrid S81 circuits. "Prior Art" In hybrid integrated circuits, a glass coating is applied to protect the thick film or thin film circuits formed on the substrate.However, as shown in FIG. Of the parts 2, the part where the leads of components 5 such as monolithic ICs and transistors are soldered, that is, the component mounting area, must be exposed. The part 2 is finally covered with the solder 4 by mounting the part crystal 5. ``Problem to be Solved by the Invention'' However, the protective glass film 3 is formed by printing and firing a glass paste. Therefore, the glass tends to sag on the end surface 3A of the protective glass shank 3. For this reason, the solder 4 may not fully blend into the conductor 2 near the end surface 3A of the protective glass limb 3, and the conductor 2 may be exposed. Conductor 2 is often made of Ag (silver) based conductor due to its good solder properties.
System conductor 2 has the property of being easily corroded under certain environments. Therefore, if exposed to high temperature and high humidity conditions or corrosive gas, the end surface 3A of the protective glass film 3 may
There was a problem in that the corrosion 7 of the conductor 2 progressed from minute exposed areas, which could lead to core breakage of the conductor 2. The present invention has been made in view of the above-mentioned problems, and its purpose is to provide a hybrid integrated circuit that does not malfunction even if the conductor 2 is disconnected near the protective glass edge 3A. There is a particular thing. "Means for Solving the Problems" In order to achieve the above object, in the present invention, as illustrated in FIG. A hybrid integrated circuit is provided in which a covered portion 2B and an exposed portion 2A as a component mounting portion are connected by a resistor 6 formed on the substrate 1. "Function" In the hybrid integrated circuit configured as described above, even if the conductor 2 were to break near the end surface 3A of the protective glass film 3, the resistor 6 would ensure electrical continuity. For this reason,
Confusion does not lead to malfunction of the integrated circuit. "Example" An example of the present invention will be described with reference to the drawings. Figure 1 is a cross-sectional view showing the vicinity of the component mounting area of a hybrid integrated circuit. A pattern of conductors 2 forming an oval thick film circuit is formed on a ceramic substrate 1, and a protective glass film 3 is formed to cover the conductors 2. The conductor 2 is formed by printing and baking an Ag-based conductor paste, and the protective glass film 3 is formed by printing and baking a glass paste. The protective glass film 3 is not formed on the two component mounting portions of the conductor 2, so that the component mounting portion 2A is exposed. A resistor 6 is printed and fired in advance under the exposed component mounting portion 2A and the conductor 2B near the end surface 3A of the protective glass 113, resulting in a two-layer structure. The resistor 6 is formed by printing and firing a Ru-based (ruthenium-based) resistor paste. Therefore, in the manufacturing process, R is first placed on the ceramic substrate 1.
Print and fire the U-based resistor 6, then print and fire the Ag-based conductor 2 with a portion overlapping the Ru-based resistor 6, and after Ik, print and fire the protective glass R3, leaving two people in the component mounting section. You'll end up cheating. Then, the solder 4 is placed on the component mounting portion 2A of the conductor 2 by printing or dipping, and the leads of the mounted component 5 are soldered by reflow or the like. The exposed component mounting portion 2A of the conductor 2 is covered with solder 4. The present embodiment is constructed as described above, and the conductor pattern from the portion 2B of the conductor 2 covered by the protective glass WA3 to the portion 2A exposed outside the protective glass film 3 as the component mounting portion 2 is connected to the conductor 2. It is formed in a two-layer oval structure with a resistor element 6 and a resistor element 6. For this reason, if the end of the protective glass film 3 3A
Even if the solder 4 does not fit well and a minute exposed point is created on the Ag-based conductor 2, and corrosion 7 progresses from there and the conductor 2 is disconnected, the Ru-based resistor 6 forming the lower layer will resist resistance from several Ω to several Ω. Since the Ru-based resistor 6, which ensures electrical continuity with a resistance value of 100Ω, is resistant to corrosion, it is unlikely that the corrosion 7 of the Ag-based conductor 2 would progress to the Ru-based resistor 6. Therefore, conduction between the mounted component 5 and the thick film circuit is ensured, so that the function of the hybrid integrated circuit does not stop. In the embodiment described above, the pattern extending from the portion 2B covered with the protective glass film 2 to the component mounting portion 2A is a two-layer structure consisting of the conductor 2 and the resistor 6, but it is not necessarily necessary to have a two-layer structure. For example, as shown in FIG. 2, a resistor 8 formed on the substrate 1 in parallel with the conductor 2 separates the portion 2B of the conductor 2 covered with the protective glass film 3 and the exposed parts WI mounting part 2. You may also connect them. "Effects of the Invention" Since the present invention is configured as described above and has a resistor connected to the conductor before and after the end surface of the protective glass film, even if the conductor is disconnected near the end surface of the protective glass film, the resistor This has the effect that continuity is ensured and the function of the hybrid integrated circuit does not stop.Therefore, it is possible to provide a highly reliable hybrid integrated circuit.

[Brief explanation of drawings]

15th! U is a cross-sectional view of a hybrid integrated circuit showing a first embodiment of the present invention, and FIG. 2 is a plan view showing a second embodiment.
Figure 3 is a cross-sectional view of a conventional hybrid integrated circuit. 1. ．． ．． Ceramic substrate, 2,. Conductor, 2A. ．．
．． Component mounting section, 3. ．． ．． Protective glass film, 3A. ．． ．．
In short, 4. ．． ．． Solder, 5. ．． ．． Parts, 6,8.
．． ．． Resistor.

Claims (1)

[Claims] A portion of a continuous conductor formed on a substrate covered by a protective glass film and a portion exposed as a component mounting portion are connected by a resistor formed on the substrate. Hybrid integrated circuit.