Flow Sensor and Manufacturing Method Thereof

1 . A flow sensor comprising a housing to receive an auxiliary channel having an opening through which a fluid to be measured is taken in; a flow rate detection section disposed within the auxiliary channel to measure a flow rate of the fluid to be measured; electronic parts isolated from the auxiliary channel to drive the flow rate detection section within a circuit chamber; and a resinous cover bonded to the housing to air-tightly seal the circuit chamber from a surrounding atmosphere, wherein the flow rate detection section provided on a tip end of a circuit package is protruded into the auxiliary channel so as to be received in the flow sensor; a protrusion section which is formed on the housing to constitute the auxiliary channel with the cover therebetween and a bonding section formed on an inner surface of the cover are laser welded to each other; a protrusion is formed on each end of the bonding section of the cover; and a height of the protrusion on the side of the auxiliary channel is made higher than that of the protrusion on an opposite side to the auxiliary channel. 2 . The flow sensor according to claim 1 , wherein a width of the bonding section formed on the cover is formed larger by a width over which burrs of a fused resin are formed than an upper surface width of a protrusion formed on the housing. 3 . The flow sensor according to claim 1 , wherein an incident laser beam spot diameter is larger than the upper surface width of the protrusion formed on the housing. 4 . The flow sensor according to claim 1 , wherein an inclination is provided on a side surface of at least a part of the protrusion section formed on the housing. 5 . The flow sensor according to claim 4 , wherein an inclination angle of the protrusion section formed on the housing is made larger than an inclination angle of a protrusion section formed on the cover on the side of the auxiliary channel. 6 . The flow sensor according to claim 4 , wherein the inclination angle of the protrusion section formed on the housing is made smaller than the inclination angle of the protrusion section formed on the cover on an opposite side to the auxiliary channel. 7 . The flow sensor according to claim 1 , wherein minute irregularities are formed on a side surface of the protrusion section provided on an end portion of the bonding section of the cover. 8 . The flow sensor according to claim 1 , wherein regarding the protrusion section which is formed on each end of the bonding section of the cover and bonded to the protrusion section of the housing which lies in a position where the auxiliary channel is distanced away from the circuit chamber, a height of the protrusion on the side of the auxiliary channel is made larger than a height of the protrusion on an inner side of the circuit chamber. 9 . The flow sensor according to claim 1 , wherein regarding the protrusion section which is formed on each end of the bonding section of the cover and bonded to the protrusion section of the housing lying in a periphery of the circuit chamber, a height of the protrusion on the inner side of the circuit chamber is made larger than a height of a protrusion on an outer side of the circuit chamber. 10 . The flow sensor according to claim 1 , wherein a percentage in content by which glass fibers are added to a thermoplastic resin from which the cover is made is smaller than a percentage in content by which glass fibers are added to a thermoplastic material from which the housing is made. 11 . The flow sensor according to claim 1 , wherein a crystallization of the thermoplastic resin from which the housing is made is larger than that of the thermoplastic resin from which the cover is made. 12 . The flow sensor according to claim 1 , wherein an elastic modulus of the thermoplastic resin from which the housing is made is larger than that of the thermoplastic resin from which the cover is made. 13 . A manufacturing method of a flow sensor comprises the steps of forming a first protrusion section to seal a circuit chamber through a resinous cover and a second protrusion section for connection to constitute an auxiliary channel with the resinous cover therebetween in a housing in which an auxiliary channel groove provided with an opening through which a fluid to be measured is taken in is formed and which receives a flow rate detection section disposed within the auxiliary channel to measure a flow rate of the fluid to be measured and electronic parts isolated from the auxiliary channel to drive the flow rate detection section in the circuit chamber; forming on the resinous cover bonding sections to be bonded to the first and second protrusion sections formed on the housing as well as forming a third protrusion section on each end of the bonding section to be bonded to the second protrusion section, wherein the third protrusion section is formed such that a height of a protrusion formed on a side of the auxiliary channel is made higher than that of a protrusion formed on an opposite side to the auxiliary channel; overlapping the housing in which the respective electronic parts are received and the cover over one another with aligned in position; pressure is applied to the overlapped housing and cover; irradiating a laser beam onto the cover so as to firstly make an interval between the first protrusion section and the corresponding bonding section laser-welded and then to make an interval between the second protrusion section and the corresponding bonding section laser-welded, thereby the cover being bonded to the housing. 14 . The manufacturing method of a flow sensor according to claim 13 , further comprising the steps of overlapping the housing in which the respective electronic parts are received and the cover over one another with aligned in position; pressure is applied to the overlapped housing and cover; irradiating a laser beam onto the cover so as to firstly make an interval between the second protrusion section and the corresponding bonding section laser-welded and then to make an interval between the first protrusion section and the corresponding bonding section laser-welded, thereby the cover being bonded to the housing.