Ceramic capacitor

Abstract

A ceramic capacitor having an improved electrode soldering performance, little or no diffusion of solder even in the case of being used under a high temperature environment and a reduced characteristic deterioration is provided. The dry plating electrodes have a three-layer structure. First layers of the electrodes are respectively provided on both surfaces of a ceramic element assembly and made of any one or more of Cu, Ni-Cu alloy and Zn. Second layers of the electrodes are respectively provided on the surfaces of the first layers and made of a material different from the material of the first layers and any one or more of Cr, Ni-Cr alloy, Fe-Cr alloy, Co-Cr alloy, Ti, Zn, Al, W, V and Mo. Third layers of the electrodes are respectively provided on the surfaces of the second layers and made of any one or more of Cu, Ni-Cu alloy, Ag and Au.

Description

BACKGROUND OF THE INVENTION

The present invention relates to a ceramic capacitor and particularly relates to plate like ceramic capacitor which is used in a high temperature environment.

Generally, the ceramic capacitor of this type is structured such that electrodes are provided on both surfaces of the plate like ceramic element assembly, and further, a lead terminal is soldered to each of the electrodes. Then, as a conventional electrode, a baked coated electrode or a wet pated electrode made of Ag, Cu or the like, which is a metal easily soldered, is applied or it has been considered to form a baked coated electrode or a wet plated electrode made of Ni, Zn or the like, which is a metal in which the Sn contained in the solder is hardly diffused, is applied.

When the ceramic capacitor having the baked coated electrode or the wet plated electrode made of Ag, Cu or the like is used in a high temperature environment (for example, about 150° C.), the Sn contained in the solder used for bonding the lead terminal diffuses into the electrode so that the bonding strength between the electrode and the ceramic deteriorates. Accordingly, there is a risk of problems such as the dielectric loss of the ceramic capacitor being increased, and corona discharge produced in the gap between the electrode and the ceramic will break the ceramic capacitor.

In the case of the ceramic capacitor having the coated baked electrode or the wet plated electrode made of Ni, Zn and the like, since Sn contained in the solder is hardly discharged, the above troubles do not occur. However, there occurs another problem such that the soldering operation of the electrode is deteriorated. Accordingly, ti becomes necessary to use a chloride flux which has a problem in reliably bonding the lead terminal and to provide another electrode for mounting the lead terminal on the electrode made of Ni, Zn or the like.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a ceramic capacitor having an improved performance when soldering an electrode, and no diffusion of solder even in the case of being used in a high temperature environment and reduced characteristic deterioration.

In order to achieve the above object, in accordance with the present invention, there is provided a ceramic capacitor comprising:

(a) a ceramic element assembly and a dry plated electrode provided on a surface of the ceramic element assembly; and

(b) the dry plated electrode having a first layer made of any one or more of Cu, Ni-Cu alloy and Zn, a second layer provided on a surface of the first layer and of a material different from the material of the first layer and is any one or more of Cr, Ni-Cr alloy, Fe-Cr alloy, Co-Cr alloy, Ti, Zn, Al, W, V and Mo, and a third layer provided on a surface of the second layer and made of any one or more of Cu, Ni-Cu alloy, Ag and Au. Further, it is preferable that the thickness of the first layer is about 500 angstroms or more, the thickness of the second layer is about 100 angstroms or more and the thickness of the third layer is about 500 angstroms or more.

Due to the above structure, the first layer secures a suitable strong bonding between the ceramic element assembly and the electrode. The second layer prevents diffusion of the solder (particularly, of Sn contained in the solder) from developing at the interface between the ceramic element assembly and the electrode. Further, the third layer improves the operability of the soldering.

Other features and advantages of the present invention will become apparent from the following description of the invention which refers to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross sectional view which shows an embodiment of a ceramic capacitor in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

An embodiment of a ceramic capacitor in accordance with the present invention will be explained below with reference to the accompanying drawing.

As shown in FIG. 1 , a ceramic capacitor is provided with a ceramic element assembly 1 , electrodes 5 a and 5 b respectively formed on both surfaces of the ceramic element assembly, and lead terminals 6 a and 6 b respectively bonded to the electrodes 5 a and 5 b by solders 9 a and 9 b. The ceramic element assembly 1 is made of, for example, a ceramic dielectric of the BaTiO 3 system, SrTiO 3 system and TiO 2 system and the like.

The electrodes 5 a and 5 b are formed on both surfaces of the ceramic element assembly by a dry plating method after the ceramic element assembly 1 is heated of a predetermined temperature. The heating temperature of the ceramic element assembly 1 is not critical but it is preferable to set the temperature to about 150° C. or less so as to decrease the residual stress within the ceramic element assembly 1 . The dry plating method includes, for example, the sputtering method, depositing method, thermal spraying method, ion plating method and the like. The dry plated electrodes 5 a and 5 b have a three-layer construction.

First layers 2 a and 2 b of the electrodes 5 a and 5 b are respectively provided on both surfaces of the ceramic element assembly 1 and are made of any one or more of Cu, Ni-Cu alloy and Zn. These metals or alloys are materials capable of obtaining a suitable bonding power with respect to the ceramic and the bonding power is considered to be obtained by a suitable bonding with oxygen within the ceramic. Accordingly, a suitable bonding strength can be secured between the ceramic element assembly 1 and the electrodes 5 a and 5 b. On the contrary, if the bonding between the metal (or the alloy) and the oxygen within the ceramic is too weak, the bonding strength between the ceramic element assembly and the electrodes is insufficient, and inversely if the bonding is too strong, the characteristic is deteriorated due to reduction of the ceramic element assembly.

Second layers 3 a and 3 b of the electrodes 5 a and 5 b are respectively provided on the surfaces of the first layers 2 a and 2 b, and are made of a material which is different from the material used for the first layer 2 a and 2 b and comprises any one or more of Cr, Ni-Cr alloy, Fe-Cr alloy, Co-Cr alloy, Ti, Zn, Al, W, V and Mo. These metals or alloys materials into which Sn and Pb hardly diffuse so that the diffusion of the solders 9 a and 9 b (particularly, of Sn contained in the solders 9 a and 9 b ) does not extend to the interface between the ceramic element assembly 1 and the electrode 5 a and the interface between the ceramic element assembly 1 and the electrode 5 b. Accordingly, the bonding strength between the electrodes 5 a and 5 b and the ceramic element assembly 1 is not deteriorated so that there does not occur the problems such that the dielectric loss of the ceramic capacitor is increased, or that the ceramic capacitor is broken due to corona discharge in the gap produced between the electrodes and the ceramic element assembly.

Third layers 4 a and 4 b of the electrodes 5 a and 5 b are respectively provided on the surfaces of the second layers 3 a and 3 b, and are made of any one or more of Cu, Ni-Cu alloy, Ag and Au. These metals or alloys are materials having an improved wetting property vis-a-vis the solder so that the lead terminals 6 a and 6 b can be bonded to the electrodes 5 a and 5 b with high reliability.

Further, the thickness of the first layers 2 a and 2 b is set to about 500 angstroms or more, the thickness of the second layers 3 a and 3 b is set to about 100 angstroms or more and the thickness of the third layers 4 a and 4 b is set to about 500 angstroms or more. This is because if the thickness is less than the above value, there is a risk that the above operation and effect of the respective layers 2 a to 4 b will be insufficiently obtained. The ceramic capacitor obtained by the above manner has an improved electrode 5 a and 5 b soldering performance, a reduced diffusion developing characteristic of the solder even if the ceramic capacitor is used under a high temperature environment, and a reduced performance deterioration.

Further, the ceramic capacitor in accordance with the present invention is not limited to the above embodiment and can be variously modified within the scope of the invention. Particularly, the shape of the ceramic element assembly, the shape of the electrodes and the like are optional so that various kinds of shapes such as a circular shape, an oval shape, a rectangular shape and the like can be selected in correspondence to the specification.

Next, experimental results performed by the inventors of the present invention will be described below with reference to FIG. 1. A ceramic capacitor sample for the experimentation is manufactured in the following manner. After heating a disc like ceramic element assembly 1 of BaTiO 3 system ceramic having a diameter of 13 mm and a thickness of 0.5 mm to a temperature of 150° C. or less under a vacuum of 10 −4 Torr, a metal or alloy selected among Cu, Ni-Cu alloy and Zn is sputtered to the upper and lower surfaces of the ceramic element assembly 1 , thereby respectively forming the first layers 2 a and 2 b having a thickness of at least 500 angstroms.

Next, a metal or alloy selected among Cr, Ni-Cr alloy, Fe-Cr alloy, Co-Cr alloy, Ti, Zn, Al, W, V and Mo is sputtered, thereby respectively forming the second layers 3 a and 3 b having a thickness of at least 100 angstroms on the surfaces of the first layers 2 a and 2 b. Further, a metal or alloy selected among Cu, Ni-Cu alloy, Ag and Au is sputtered, thereby forming the third layers 4 a and 4 b having a thickness of at least 500 angstroms on the surfaces of the second layers 3 a and 3 b.

As mentioned above, after the electrodes 5 a and 5 b are respectively formed on both surfaces of the ceramic element assembly 1 , the lead terminals 6 a and 6 b made of a soldered annealed copper wire and having a diameter of 0.6 mm are respectively bonded to the electrodes 5 a and 5 b by solders 9 a and 9 b, and the wetting property of the solder thereof has been observed. Further, after keeping the ceramic capacitor sample at a temperature of 125° C. for 1000 hours, electric characteristics such as dielectric constant 6 , dielectric less and insulation resistance have been measured. The measured results shown in tables 1—1 to 1-11 have been obtained. The wetting property of the solder in the tables is determined such as to be good if the contact angle between the electrodes 5 a and 5 b and the solders 9 a and 9 b is less than 90 degrees, and to be bad if the contact angle is equal to or more than 90 degrees.

	TABLE 1-1
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Cu	Cr	Cu	Good	8200	0.51	80000
Cu	Cr	Ni—Cu	Good	8200	0.51	80000
		(70:30)
Cu	Cr	Ni—Cu	Good	8200	0.51	80000
		(10:90)
Cu	Cr	Ag	Good	8200	0.51	80000
Cu	Cr	Au	Good	8200	0.51	80000
Cu	Ni—Cr	Cu	Good	8200	0.51	80000
	(90:10)
Cu	Ni—Cr	Ni—Cu	Good	8200	0.51	80000
	(90:10)	(70:30)
Cu	Ni—Cr	Ni—Cu	Good	8200	0.51	80000
	(90:10)	(10:90)
Cu	Ni—Cr	Ag	Good	8200	0.51	80000
	(90:10)
Cu	Ni—Cr	Au	Good	8200	0.51	80000
	(90:10)
Cu	Ni—Cr	Cu	Good	8200	0.51	80000
	(20:80)
Cu	Ni—Cr	Ni—Cu	Good	8200	0.51	80000
	(20:80)	(70:30)
Cu	Ni—Cr	Ni—Cu	Good	8200	0.51	80000
	(20:80)	(10:90)
Cu	Ni—Cr	Ag	Good	8200	0.51	80000
	(20:80)
Cu	Ni—Cr	Au	Good	8200	0.51	80000
	(20:80)
Cu	Ni—Cr	Cu	Good	8200	0.51	80000
	(83:17)
Cu	Ni—Cr	Ni—Cu	Good	8200	0.51	80000
	(83:17)	(70:30)
Cu	Fe—Cr	Ni—Cu	Good	8200	0.51	80000
	(83:17)	(10:90)
Cu	Fe—Cr	Ag	Good	8200	0.51	80000
	(83:17)
Cu	Fe—Cr	Au	Good	8200	0.51	80000
	(83:17)

	TABLE 1-2
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Cu	Co—Cr	Cu	Good	8200	0.51	80000
	(50:50)
Cu	Co—Cr	Ni—Cu	Good	8200	0.51	80000
	(50:50)	(70:30)
Cu	Co—Cr	Ni—Cu	Good	8200	0.51	80000
	(50:50)	(10:90)
Cu	Co—Cr	Ag	Good	8200	0.51	80000
	(50:50)
Cu	Co—Cr	Au	Good	8200	0.51	80000
	(50:50)
Cu	Ti	Cu	Good	8200	0.56	80000
Cu	Ti	Ni—Cu	Good	8200	0.56	80000
		(70:30)
Cu	Ti	Ni—Cu	Good	8200	0.56	80000
		(10:90)
Cu	Ti	Ag	Good	8200	0.56	80000
Cu	Ti	Au	Good	8200	0.56	80000
Cu	Zn	Cu	Good	8200	0.62	80000
Cu	Zn	Ni—Cu	Good	8200	0.62	80000
		(70:30)
Cu	Zn	Ni—Cu	Good	8200	0.62	80000
		(10:90)
Cu	Zn	Ag	Good	8200	0.62	80000
Cu	Zn	Au	Good	8200	0.62	80000
Cu	Al	Cu	Good	8200	0.60	80000
Cu	Al	Ni—Cu	Good	8200	0.60	80000
		(70:30)
Cu	Al	Ni—Cu	Good	8200	0.60	80000
		(10:90)
Cu	Al	Ag	Good	8200	0.60	80000
Cu	Al	Au	Good	8200	0.60	80000
Cu	W	Cu	Good	8200	0.58	80000
Cu	W	Ni—Cu	Good	8200	0.58	80000
		(70:30)
Cu	W	Ni—Cu	Good	8200	0.58	80000
		(10:90)
Cu	W	Ag	Good	8200	0.58	80000
Cu	W	Au	Good	8200	0.58	80000

	TABLE 1-3
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Cu	V	Cu	Good	8200	0.58	80000
Cu	V	Ni—Cu	Good	8200	0.58	80000
		(70:30)
Cu	V	Ni—Cu	Good	8200	0.58	80000
		(10:90)
Cu	V	Ag	Good	8200	0.58	80000
Cu	V	Au	Good	8200	0.58	80000
Cu	Mo	Cu	Good	8200	0.58	80000
Cu	Mo	Ni—Cu	Good	8200	0.58	80000
		(70:30)
Cu	Mo	Ni—Cu	Good	8200	0.58	80000
		(10:90)
Cu	Mo	Ag	Good	8200	0.58	80000
Cu	Mo	Au	Good	8200	0.58	80000
Ni—Cu	Cr	Cu	Good	8300	0.48	60000
(70:30)
Ni—Cu	Cr	Ni—Cu	Good	8300	0.48	60000
(70:30)		(70:30)
Ni—Cu	Cr	Ni—Cu	Good	8300	0.48	60000
(70:30)		(10:90)
Ni—Cu	Cr	Ag	Good	8300	0.48	60000
(70:30)
Ni—Cu	Cr	Au	Good	8300	0.48	60000
(70:30)
Ni—Cu	Ni—Cr	Cu	Good	8300	0.48	60000
(70:30)	(90:10)
Ni—Cu	Ni—Cr	Ni—Cu	Good	8300	0.48	60000
(70:30)	(90:10)	(70:30)
Ni—Cu	Ni—Cu	Ni—Cu	Good	8300	0.48	60000
(70:30)	(90:10)	(10:90)
Ni—Cu	Ni—Cr	Ag	Good	8300	0.48	60000
(70:30)	(90:10)
Ni—Cu	Ni—Cr	Au	Good	8300	0.48	60000
(70:30)	(90:10)
Ni—Cu	Ni—Cr	Cu	Good	8300	0.48	60000
(70:30)	(20:80)

	TABLE 1-4
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Ni—Cu	Ni—Cr	Ni—Cu	Good	8200	0.48	80000
(70:30)	(20:80)	(10:80)
Ni—Cu	Ni—Cr	Ag	Good	8200	0.48	60000
(70:30)	(20:80)
Ni—Cu	Ni—Cr	Au	Good	8200	0.48	60000
(70:30)	(20:80)
Ni—Cu	Fe—Cr	Cu	Good	8200	0.48	60000
(70:30)	(83:17)
Ni—Cu	Fe—Cr	Ni—Cu	Good	8200	0.48	60000
(70:30)	(83:17)	(70:30)
Ni—Cu	Fe—Cr	Ni—Cu	Good	8200	0.48	60000
(70:30)	(83:17)	(10:90)
Ni—Cu	Fe—Cr	Ag	Good	8200	0.48	60000
(70:30)	(83:17)
Ni—Cu	Fe—Cr	Au	Good	8200	0.48	60000
(70:30)	(83:17)
Ni—Cu	Co—Cr	Cu	Good	8200	0.48	60000
(70:30)	(50:50)
Ni—Cu	Co—Cr	Ni—Cu	Good	8200	0.48	60000
(70:30)	(50:50)	(70:30)
Ni—Cu	Co—Cr	Ni—Cu	Good	8300	0.48	60000
(70:30)	(50:50)	(10:90)
Ni—Cu	Co—Cr	Ag	Good	8300	0.48	60000
(70:30)	(50:50)
Ni—Cu	Co—Cr	Au	Good	8300	0.48	60000
(70:30)	(50:50)
Ni—Cu	Ti	Cu	Good	8300	0.53	60000
(70:30)
Ni—Cu	Ti	Ni—Cu	Good	8300	0.53	60000
(70:30)		(70:30)
Ni—Cu	Ti	Ni—Cu	Good	8300	0.53	60000
(70:30)		(10:90)
Ni—Cu	Ti	Ag	Good	8300	0.53	60000
(70:30)
Ni—Cu	Ti	Au	Good	8300	0.53	60000
(70:30)
Ni—Cu	Zn	Cu	Good	8300	0.55	60000
(70:30)

	TABLE 1-5
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Ni—Cu	Zn	Ni—Cu	Good	8300	0.55	60000
(70:30)		(70:30)	Good	8300	0.55	60000
Ni—Cu	Zn	Ni—Cu	Good	8300	0.55	60000
(70:30)		(10:90)
Ni—Cu	Zn	Ag	Good	8300	0.55	60000
(70:30)
Ni—Cu	Zn	Au	Good	8300	0.55	60000
(70:30)
Ni—Cu	Al	Cu	Good	8300	0.53	60000
(70:30)
Ni—Cu	Al	Ni—Cu	Good	8300	0.53	60000
(70:30)		(70:30)
Ni—Cu	Al	Ni—Cu	Good	8300	0.53	60000
(70:30)		(10:90)
Ni—Cu	Al	Ag	Good	8300	0.53	60000
(70:30)
Ni—Cu	Al	Au	Good	8300	0.53	60000
(70:30)
Ni—Cu	W	Cu	Good	8300	0.51	60000
(70:30)
Ni—Cu	W	Ni—Cu	Good	8300	0.51	60000
(70:30)		(70:30)
Ni—Cu	W	Ni—Cu	Good	8300	0.51	60000
(70:30)		(10:90)
Ni—Cu	W	Ag	Good	8300	0.51	60000
(70:30)
Ni—Cu	W	Au	Good	8300	0.51	60000
(70:30)
Ni—Cu	V	Cu	Good	8300	0.51	60000
(70:30)
Ni—Cu	V	Ni—Cu	Good	8300	0.51	60000
(70:30)		(70:30)
Ni—Cu	V	Ni—Cu	Good	8300	0.51	60000
(70:30)		(10:90)
Ni—Cu	V	Ag	Good	8300	0.51	60000
(70:30)
Ni—Cu	V	Au	Good	8300	0.51	60000
(70:30)

	TABLE 1-6
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Ni—Cu	Mo	Cu	Good	8300	0.51	60000
(70:30)
Ni—Cu	Mo	Ni—Cu	Good	8300	0.51	60000
(70:30)		(70:30)
Ni—Cu	Mo	Ni—Cu	Good	8300	0.51	60000
(70:30)		(10:90)
Ni—Cu	Mo	Ag	Good	8300	0.51	60000
(70:30)
Ni—Cu	Mo	Au	Good	8300	0.51	60000
(70:30)
Ni—Cu	Cr	Cu	Good	8250	0.45	70000
(10:90)
Ni—Cu	Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	Cr	(70:30)
Ni—Cu	Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)		(10:90)
Ni—Cu	Cr	Ag	Good	8250	0.45	70000
(10:90)
Ni—Cu	Cr	Au	Good	8250	0.45	70000
(10:90)
Ni—Cu	Ni—Cr	Cu	Good	8250	0.45	70000
(10:90)	(90:10)
Ni—Cu	Ni—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(90:10)	(70:30)
Ni—Cu	Ni—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(90:10)	(10:90)
Ni—Cu	Ni—Cr	Ag	Good	8250	0.45	70000
(10:90)	(90:10)
Ni—Cu	Ni—Cr	Au	Good	8250	0.45	70000
(10:90)	(90:10)
Ni—Cu	Ni—Cr	Cu	Good	8250	0.45	70000
(10:90)	(20:80)
Ni—Cu	Ni—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(20:80)	(70:30)
Ni—Cu	Ni—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(20:80)	(10:90)
Ni—Cu	Ni—Cr	Ag	Good	8250	0.45	70000
(10:90)	(20:80)

	TABLE 1-7
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Ni—Cu	Ni—Cr	Au	Good	8250	0.45	70000
(10:90)	(20:80)	Au	Good	8250	0.45	70000
Ni—Cu	Fe—Cr	Cu	Good	8250	0.45	70000
(10:90)	(83:17)
Ni—Cu	Fe—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(83:17)	(70:30)
Ni—Cu	Fe—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(83:17)	(10:90)
Ni—Cu	Fe—Cr	Ag	Good	8250	0.45	70000
(10:90)	(83:17)
Ni—Cu	Fe—Cr	Au	Good	8250	0.45	70000
(10:90)	(83:17)
Ni—Cu	Co—Cr	Cu	Good	8250	0.45	70000
(10:90)	(50:50)
Ni—Cu	Co—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(50:50)	(70:30)
Ni—Cu	Co—Cr	Ni—Cu	Good	8250	0.45	70000
(10:90)	(50:50)	(10:90)
Ni—Cu	Co—Cr	Ag	Good	8250	0.45	70000
(10:90)	(50:50)
Ni—Cu	Co—Cr	Au	Good	8250	0.45	70000
(10:90)	(50:50)
Ni—Cu	Ti	Cu	Good	8250	0.50	70000
(10:90)
Ni—Cu	Ti	Ni—Cu	Good	8250	0.50	70000
(10:90)		(70:30)
Ni—Cu	Ti	Ni—Cu	Good	8250	0.50	70000
(10:90)		(10:90)
Ni—Cu	Ti	Ag	Good	8250	0.50	70000
(10:90)
Ni—Cu	Ti	Au	Good	8250	0.50	70000
(10:90)
Ni—Cu	Zn	Cu	Good	8250	0.53	70000
(10:90)
Ni—Cu	Zn	Ni—Cu	Good	8250	0.53	70000
(10:90)		(70:30)
Ni—Cu	Zn	Ni—Cu	Good	8250	0.53	70000
(10:90)		(10:90)

	TABLE 1-8
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Ni—Cu	Zn	Ag	Good	8250	0.53	70000
(10:90)
Ni—Cu	Zn	Au	Good	8250	0.53	70000
(10:90)
Ni—Cu	Al	Cu	Good	8250	0.51	70000
(10:90)
Ni—Cu	Al	Ni—Cu	Good	8250	0.51	70000
(10:90)		(70:30)
Ni—Cu	Al	Ni—Cu	Good	8250	0.51	70000
(10:90)		(10:90)
Ni—Cu	Al	Ag	Good	8250	0.51	70000
(10:90)
Ni—Cu	Al	Au	Good	8250	0.51	70000
(10:90)
Ni—Cu	W	Cu	Good	8250	0.49	70000
(10:90)
Ni—Cu	W	Ni—Cu	Good	8250	0.49	70000
(10:90)		(70:30)
Ni—Cu	W	Ni—Cu	Good	8250	0.49	70000
(10:90)		(10:90)
Ni—Cu	W	Ag	Good	8250	0.49	70000
(10:90)
Ni—Cu	W	Au	Good	8250	0.49	70000
(10:90)
Ni—Cu	V	Cu	Good	8250	0.49	70000
(10:90)
Ni—Cu	V	Ni—Cu	Good	8250	0.49	70000
(10:90)		(70:30)
Ni—Cu	V	Ni—Cu	Good	8250	0.49	70000
(10:90)		(10:90)
Ni—Cu	V	Ag	Good	8250	0.49	70000
(10:90)
Ni—Cu	V	Au	Good	8250	0.49	70000
(10:90)
Ni—Cu	Mo	Cu	Good	8250	0.49	70000
(10:90)
Ni—Cu	Mo	Ni—Cu	Good	8250	0.49	70000
(10:90)		(70:30)

	TABLE 1-9
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Ni—Cu	Mo	Ni—Cu	Good	8250	0.49	70000
(10:90)		(10:90)
Ni—Cu	Mo	Ag	Good	8250	0.49	70000
(10:90)
Ni—Cu	Mo	Au	Good	8250	0.49	70000
(10:90)
Zn	Cr	Cu	Good	8350	0.59	70000
Zn	Cr	Ni—Cu	Good	8350	0.59	70000
		(70:30)
Zn	Cr	Ni—Cu	Good	8350	0.59	70000
		(10:90)
Zn	Cr	Ag	Good	8350	0.59	70000
Zn	Cr	Au	Good	8350	0.59	70000
Zn	Ni—Cu	Cu	Good	8350	0.59	70000
	(10:90)
Zn	Ni—Cu	Ni—Cu	Good	8350	0.59	70000
	(10:90)	(70:30)
Zn	Ni—Cu	Ni—Cu	Good	8350	0.59	70000
	(10:90)	(10:90)
Zn	Ni—Cu	Ag	Good	8350	0.59	70000
	(10:90)
Zn	Ni—Cu	Au	Good	8350	0.59	70000
	(90:10)
Zn	Ni—Cr	Cu	Good	8350	0.59	70000
	(20:80)
Zn	—Cr	Ni—Cu	Good	8350	0.59	70000
	(20:80)	(70:30)
Zn	Ni—Cr	Ni—Cu	Good	8350	0.59	70000
	(20:80)	(10:90)
Zn	Ni—Cr	Ag	Good	8350	0.59	70000
	(20:80)
Zn	Ni—Cr	Au	Good	8350	0.59	70000
	(20:80)
Zn	Fe—Cr	Cu	Good	8350	0.59	70000
	(83:17)
Zn	Fe—Cr	Ni—Cu	Good	8350	0.59	70000
	(83:17)	(70:30)

	TABLE 1-10
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Zn	Fe—Cr	Ni—Cu	Good	8350	0.59	40000
	(83:17)	(10:90)
Zn	Fe—Cr	Ag	Good	8350	0.59	40000
	(83:17)
Zn	Fe—Cr	Au	Good	8350	0.59	40000
	(83:17)
Zn	Co—Cr	Cu	Good	8350	0.59	40000
	(50:50)
Zn	Co—Cr	Ni—Cu	Good	8350	0.59	40000
	(50:50)	(70:30)
Zn	Co—Cr	Ni—Cu	Good	8350	0.59	40000
	(50:50)	(10:90)
Zn	Co—Cr	Ag	Good	8350	0.59	40000
	(50:50)
Zn	Co—Cr	Au	Good	8350	0.59	40000
	(50:50)
Zn	Ti	Cu	Good	8350	0.65	40000
Zn	Ti	Ni—Cr	Good	8350	0.65	40000
		(70:30)
Zn	Ti	Ni—Cu	Good	8350	0.65	40000
		(10:90)
Zn	Ti	Ag	Good	8350	0.65	40000
Zn	Ti	Au	Good	8350	0.65	40000
Zn	Zn	Cu	Good	8350	0.63	40000
Zn	Zn	Ni—Cu	Good	8350	0.63	40000
		(70:30)
Zn	Zn	Ni—Cu	Good	8350	0.63	40000
		(10:90)
Zn	Zn	Ag	Good	8350	0.63	40000
Zn	Zn	Au	Good	8350	0.63	40000
Zn	Al	Cu	Good	8350	0.63	40000
Zn	AI	Ni—Cu	Good	8350	0.63	40000
		(70:30)
Zn	Al	Ni—Cu	Good	8350	0.63	40000
		(10:90)
Zn	Al	Ag	Good	8350	0.63	40000
Zn	Al	Au	Good	8350	0.63	40000
Zn	W	Cu	Good	8350	0.63	40000

	TABLE 1-11
	Electrical Characteristic
Electrode	Wetting			Insulation
First	Second	Third	Property		Dielectric	Resistance
Layer	Layer	Layer	of Solder	ε	Loss (%)	(MΩ)
Zn	W	Ni—Cu	Good	8350	0.63	40000
		(70:30)
Zn	W	Ni—Cu	Good	8350	0.63	40000
		(10:90)
Zn	W	Ag	Good	8350	0.63	40000
Zn	W	Au	Good	8350	0.63	40000
Zn	V	Cu	Good	8350	0.63	40000
Zn	V	Ni—Cu	Good	8350	0.63	40000
		(70:30)
Zn	V	Ni—Cu	Good	8350	0.63	40000
		(10:90)
Zn	V	Ag	Good	8350	0.63	40000
Zn	V	Au	Good	8350	0.63	40000
Zn	Mo	Cu	Good	8350	0.63	40000
Zn	Mo	Ni—Cu	Good	8350	0.63	40000
		(70:30)
Zn	Mo	Ni—Cu	Good	8350	0.63	40000
		(10:90)
Zn	Mo	Ag	Good	8350	0.63	40000
Zn	Mo	Au	Good	8350	0.63	40000

As is understood from the tables, the electrodes 5 a and 5 b have a good soldering performance, and have excellent values of the dielectric constant 6 , dielectric loss and insulation resistance so that the effect of the present invention is significant.

As is clear by the above description and in accordance with the present invention, since the dry plated electrode on the surface of the ceramic element assembly is structured by a first layer made of any one or more of Cu, Ni-Cu alloy and Zn, a second layer provided on a surface of the first layer and made of a material different from the material of the first layer and further any one or more of Cr, Ni-Cr alloy, Fe-Cr alloy, Co-Cr alloy, Ti, Zn, Al, W, V and Mo, and a third layer provided on a surface of the second layer and made of any one or more of Cu, Ni-Cu alloy, Ag and Au, a ceramic capacitor having improved electrode soldering performance, little or no diffusion of solder even under a high temperature environment and a reduced characteristic deterioration can be obtained.

Although the present invention has been described in relation to particular embodiments thereof, many other variations and modifications and other uses will become apparent to those skilled in the art.

Claims

1. A method of manufacturing a ceramic plate capacitor comprising:heating a ceramic element plate assembly to a temperature equal to or less than about 150 degrees centigrade and forming by dry plating a first layer of at least one material selected from the group consisting of Cu, Ni-Cu alloy and Zn on a surface of said heated ceramic element assembly; forming by dry plating on a surface of the first layer, a second layer of material different from the material of said first layer, said second layer being at least one member selected from the group consisting of Cr, Ni-Cr alloy, Fe-Cr alloy, Co-Cr alloy, Ti, Zn, Al, W, V and Mo; and forming by dry plating on a surface of said second layer, a third layer which is least one member selected from the group consisting of Cu, Ni-Cu alloy, Ag and Au.

2. A method of manufacturing a ceramic plate capacitor as recited in claim 1, wherein said first layer is Cu.

3. A method of manufacturing a ceramic plate capacitor as recited in claim 1, wherein said first layer is Ni-Cu alloy.

4. A method of manufacturing a ceramic plate capacitor as recited in claim 1, wherein said first layer is Zn.

5. A method of manufacturing a ceramic plate capacitor as recited in claim 1, wherein the said first layer is formed to a thickness of at least about 500 angstroms, said second layer is formed to a thickness of at least about 100 angstroms and said third layer is formed to at thickness of at least about 500 angstroms.