Mounting structure and mounting method of cryocooler

What is claimed is: 1. A mounting structure for mounting a cold head of a cryocooler on a vacuum vessel, where the cold head has a cold head-side cooling stage and a cold head-side flange, the mounting structure comprising: a cold head accommodation sleeve that is installed in the vacuum vessel so as to form an airtight region, isolated from an ambient environment, between the cold head and the cold head accommodation sleeve, and which includes a sleeve-side cooling stage which comes into thermal contact with the cold head-side cooling stage by coming into physical contact with the cold head-side cooling stage, and a sleeve-side flange to be coupled to the cold head-side flange, an inter-flange distance adjustment mechanism configured to adjust a distance between the sleeve-side flange and the cold head-side flange so that the cold head-side cooling stage and the sleeve-side cooling stage are physically brought into contact with each other or brought into a contactless state therebetween, while maintaining isolation of the airtight region from the ambient environment, and a flange fastening mechanism configured to fasten the cold head-side flange to the sleeve-side flange so that the cold head-side cooling stage is pressed against the sleeve-side cooling stage with a pressing contact pressure designated to bring the cold head-side cooling stage and the sleeve-side cooling stage into thermal contact with each other under thermal resistance equal to or smaller than a threshold. 2. The mounting structure according to claim 1 , further comprising: a cold head-side temperature sensor that measures a temperature of the cold head-side cooling stage; and a sleeve-side temperature sensor that measures a temperature of the sleeve-side cooling stage, wherein the cold head-side flange is fastened to the sleeve-side flange by the flange fastening mechanism so that a temperature difference between a measurement temperature of the cold head-side cooling stage and a measurement temperature of the sleeve-side cooling stage falls within a predetermined temperature difference corresponding to the threshold. 3. The mounting structure according to claim 1 , wherein the inter-flange distance adjustment mechanism includes a lift-up bolt hole formed in the cold head-side flange and a lift-up bolt screwed into the lift-up bolt hole, and wherein the inter-flange distance adjustment mechanism is configured to raise and lower the cold head-side flange to and from the sleeve-side flange by rotating the lift-up bolt in a state where the lift-up bolt butts against the sleeve-side flange. 4. The mounting structure according to claim 1 , wherein the cold head-side cooling stage includes a cold head-side heat transfer block formed of a heat conductive material, wherein the sleeve-side cooling stage includes a sleeve-side heat transfer block formed of a heat conductive material, and wherein the cold head-side cooling stage and the sleeve-side cooling stage are brought into thermal contact with each other by direct physical contact between the cold head-side heat transfer block and the sleeve-side heat transfer block. 5. The mounting structure according to claim 1 , wherein the cold head is a two-stage cold head, and the cold head accommodation sleeve is a two-stage sleeve, and wherein the flange fastening mechanism is configured to fasten the cold head-side flange to the sleeve-side flange so that a cold head-side second cooling stage is pressed against a sleeve-side second cooling stage with the pressing contact pressure designated to bring the cold head-side second cooling stage and the sleeve-side second cooling stage into thermal contact with each other under the thermal resistance equal to or smaller than the threshold. 6. The mounting structure according to claim 5 , wherein a cold head-side first cooling stage and a sleeve-side first cooling stage come into thermal contact with each other via a heat transfer spring mechanism. 7. A mounting method of mounting a cold head of a cryocooler on a vacuum vessel via a cold head accommodation sleeve, where the cold head has a cold head-side cooling stage and a cold head-side flange, and the cold head accommodation sleeve has a sleeve-side cooling stage which comes into thermal contact with the cold head-side cooling stage by coming into physical contact with the cold head-side cooling stage, and a sleeve-side flange to be coupled to the cold head-side flange, and the cold head accommodation sleeve is installed in the vacuum vessel so as to form an airtight region isolated from an ambient environment between the cold head and the cold head accommodation sleeve, the method comprising: adjusting a distance between the sleeve-side flange and the cold head-side flange so that the cold head-side cooling stage and the sleeve-side cooling stage are physically brought into contact with each other, while isolation of the airtight region from the ambient environment is maintained, and fastening the cold head-side flange to the sleeve-side flange so that the cold head-side cooling stage is pressed against the sleeve-side cooling stage with a pressing contact pressure designated to bring the cold head-side cooling stage and the sleeve-side cooling stage into thermal contact with each other under thermal resistance equal to or smaller than a threshold. 8. The mounting method according to claim 7 , further comprising: measuring a temperature of the cold head-side cooling stage; and measuring a temperature of the sleeve-side cooling stage, wherein the cold head-side flange is fastened to the sleeve-side flange by the flange fastening mechanism so that a temperature difference between the measured temperature of the cold head-side cooling stage and the measured temperature of the sleeve-side cooling stage falls within a predetermined temperature difference corresponding to the threshold.