Flow sensor and method for producing resin structure

The invention claimed is: 1. A flow sensor comprising: a sub-passage constituting a measurement channel by taking in a measured fluid from an opening; a flow rate detector arranged inside the sub-passage to measure a flow rate of the measured fluid; a housing including a circuit chamber that is isolated from the sub-passage to house electronic components that drive the flow rate detector; and a resin cover joined to the housing to airtightly seal the sub-passage and the circuit chamber from an outside air, wherein a joining portion formed on the housing and a joining portion formed on an inner surface of the cover are joined by laser welding, a main material of the cover is a crystalline resin and contains at least one non-crystalline material and the cover is configured to undergo a change in color based on at least one of a temperature and an amount of elapsed time, and a degree of crystallinity of a crystalline resin constituting the main material of the cover opposite to a flow rate detector made of Si elements is made larger than a degree of crystallinity of a crystalline resin constituting a material of an other cover on a rear side. 2. The flow sensor according to claim 1 , wherein a resin material of a region of the joining portion formed on an inner surface of the cover and a neighboring portion has an average transmittance of 35% or more for light of a wavelength of 450 nm to 1100 nm. 3. The flow sensor according to claim 2 , wherein a color of the resin material of a region corresponding to the joining portion of the cover satisfies lightness L* <75 and chroma C*<10 in an L*a*b color system. 4. The flow sensor according to claim 3 , wherein a glass transition temperature of the material contained in the resin material of the cover is 80° C. to 120° C. 5. The flow sensor according to claim 1 , wherein a protruding portion formed on the housing and the joining portion formed on the inner surface of the cover are joined by using an adhesive, instead of the laser welding. 6. The flow sensor according to claim 1 , wherein a transmittance of the main material of the cover in a region of a neighboring portion of a joining portion to the housing is smaller than the transmittance of the main material of the cover in the region of the joining portion to the housing. 7. The flow sensor according to claim 1 , wherein a thickness of the cover of a region of a neighboring portion of a joining portion to the housing is larger than a thickness of the cover in a region of the joining portion to the housing. 8. The flow sensor according to claim 1 , wherein a gap is formed between the cover and the housing in a region of a neighboring portion of a joining portion of the cover and the housing. 9. The flow sensor according to claim 1 , wherein a glass transition temperature of a material contained in a resin material of the cover is made equal to or less than a glass transition temperature of a material contained in a resin material of the housing. 10. The flow sensor according to claim 1 , wherein a content of a glass material contained in the resin material of the cover is made equal to or less than a content of a glass material contained in the resin material of the housing. 11. The flow sensor according to claim 1 , wherein a degree of crystallinity of a crystalline resin constituting a material of the housing is larger than the degree of crystallinity of the crystalline resin constituting the main material of the cover. 12. The flow sensor according to claim 1 , wherein an elastic modulus of a material of the housing is larger than an elastic modulus of the main material of the cover. 13. The flow sensor according to claim 1 , wherein a plurality of covers constituting the sub-passage is included and at least a plurality of different materials is used. 14. The flow sensor according to claim 1 , wherein a glass transition temperature of a material contained in a material of a cover opposite to the flow rate detector made of Si elements is larger than a glass transition temperature of a material contained in a material of an other cover on a rear side. 15. A flow sensor comprising: a sub-passage constituting a measurement channel by taking in a measured fluid from an opening; a flow rate detector arranged inside the sub-passage to measure a flow rate of the measured fluid; a housing including a circuit chamber that is isolated from the sub-passage to house electronic components that drive the flow rate detector; and a resin cover joined to the housing to airtightly seal the sub-passage and the circuit chamber from an outside air, wherein a joining portion formed on the housing and a joining portion formed on an inner surface of the cover are joined by laser welding, a main material of the cover is a crystalline resin and contains at least one non-crystalline material and the cover is configured to undergo a change in color based on at least one of a temperature and an amount of elapsed time, and a glass transition temperature of a material contained in a material of a cover opposite to the flow rate detector made of Si elements is larger than a glass transition temperature of a material contained in a material of an other cover on a rear side.