Ultrasonic transmission/reception unit, manufacturing method of ultrasonic transmission/reception unit, and ultrasonic flow meter device

The invention claimed is: 1. An ultrasonic transmission/reception unit comprising: a metal plate; an acoustic matching member fastened to a first main surface of the metal plate; a piezoelectric substrate fastened to a second main surface of the metal plate such that the piezoelectric substrate corresponds to a portion of the metal plate to which the acoustic matching member is fastened; a first lead wire connected to an end portion of the piezoelectric substrate which is more distant from the metal plate, to supply a voltage applied to the piezoelectric substrate; a second lead wire connected to the metal plate, to supply the voltage applied to the piezoelectric substrate; and a vibration suppression member containing a thermoplastic resin as a major component, the vibration suppression member being configured to cover, in a unitary manner, the second main surface of the metal plate, except for a portion of the second main surface to which the piezoelectric substrate is fastened, a surface of the piezoelectric substrate, an end surface of the metal plate, an outer peripheral portion of the first main surface of the metal plate, the first lead wire, and the second lead wire wherein the vibration suppression member contacts no portion of the acoustic matching member directly; wherein the metal plate has a flat plate shape and houses no piezoelectric substrate. 2. The ultrasonic transmission/reception unit according to claim 1 , wherein the metal plate has a flanged metal container shape, including a tubular peripheral portion, an end wall portion closing one end of the peripheral portion, and a flange portion formed at the other end of the peripheral wall portion; wherein the acoustic matching member is fastened to an outer surface of the end wall portion; wherein the piezoelectric substrate is fastened to an inner surface of the end wall portion such that the piezoelectric substrate is located in an inner space of the tubular peripheral wall portion; wherein the second lead wire is connected to the metal plate; and wherein the vibration suppression member is filled in the inner space of the tubular peripheral portion such that the vibration suppression member covers the surface of the piezoelectric substrate, the first lead wire and the second lead wire, and has a unitary structure to cover an inner surface of the flange portion, an outer peripheral surface of the flange portion, an outer surface of the flange portion, and an outer surface of the peripheral wall portion. 3. The ultrasonic transmission/reception unit according to claim 1 , wherein the piezoelectric substrate has a groove extending in a thickness direction of the metal plate, and the vibration suppression member is filled into the groove. 4. The ultrasonic transmission/reception unit according to claim 1 , wherein the vibration suppression member has a protruding portion protruding in a direction from a base end of the acoustic matching member toward a tip end of the acoustic matching member, in a portion covering the first main surface of the metal plate. 5. The ultrasonic transmission/reception unit according to claim 1 , wherein the vibration suppression member has a gap between the vibration suppression member and an outer peripheral surface of the acoustic matching member. 6. A method of manufacturing an ultrasonic transmission/reception unit, comprising the steps of: creating an assembly structure including a metal plate, an acoustic matching member fastened to a first main surface of the metal plate, a piezoelectric substrate fastened to a second main surface of the metal plate such that the piezoelectric substrate corresponds to a portion of the metal plate to which the acoustic matching member is fastened, a first lead wire connected to an end portion of the piezoelectric substrate which is more distant from the metal plate, to supply a voltage applied to the piezoelectric substrate, and a second lead wire connected to the metal plate, to supply the voltage applied to the piezoelectric substrate; and after accommodating the assembly structure into a die, forming a vibration suppression member which is made of a thermoplastic resin and is a single member made of a continuous material, by injecting the thermoplastic resin into the die such that the vibration suppression member covers, in a unitary manner, the second main surface of the metal plate, except for a portion of the second main surface to which the piezoelectric substrate is fastened, a surface of the piezoelectric substrate, an end surface of the metal plate, an outer peripheral portion of the first main surface of the metal plate, the first lead wire, and the second lead wire and such that the vibration suppression member contacts no portion of the acoustic matching member directly; wherein the metal plate has a flat plate shape and houses no piezoelectric substrate. 7. The method of manufacturing the ultrasonic transmission/reception unit according to claim 6 , wherein in the step of forming the vibration suppression member, the assembly structure is accommodated into an inner space of the die such that the first main surface of the metal plate faces downward and a portion of the first main surface which is around the acoustic matching member is supported by an annular support portion of the die; and wherein the vibration suppression member is formed with a gap between the vibration suppression member and an outer peripheral surface of the acoustic matching member by injecting the thermoplastic resin into a region in the inner space of the die, which region is located outward relative to the annular support portion. 8. An ultrasonic flow meter device comprising: a pair of ultrasonic transmission/reception units each of which is recited in claim 1 , the pair of ultrasonic transmission/reception units being configured to mutually transmit and receive an ultrasonic pulse; a fluid passage to which the pair of ultrasonic transmission/reception units are attached such that the pair of ultrasonic transmission/reception units are apart from each other; a propagation time measuring section for measuring time for which the ultrasonic pulse propagates between the pair of ultrasonic transmission/reception units; and a calculating section for calculating a flow of a measurement target fluid based on the time measured by the propagation time measuring section.