Divisible experimental device and method for sand production and sand control during natural gas hydrate exploitation

What is claimed is: 1. A divisible device for a simulation experiment of sand production and sand control in natural gas hydrate exploitation, comprising a reactor system, a feeding system, a separation and measurement system, a water-bath jacket system, a support and safety system, and a software recording and analyzing system; wherein the feeding system is configured to introduce gas, liquid, and sands into the reactor system to allow formation of natural gas hydrates in the reactor system; the reactor system is disposed in the water-bath jacket system, and the water-bath jacket system is configured to regulate a temperature inside the reactor system for simulating an ambient temperature of a natural gas hydrate reservoir; the support and safety system comprises a base, wherein the water-bath jacket system is vertically or horizontally fixable on the base for simulating the sand production and sand control by sand control screens at various positions in the natural gas hydrate reservoir; the base is provided with a data collecting module, wherein the data collecting module collects data from the reactor system during a simulated exploitation by a plurality of sensors; the separation and measurement system is connected to a production outlet of the reactor system for simulating a inflow of a gas-liquid-sand mixture during the simulated exploitation; the separation and measurement system is configured to separate and measure the gas-liquid-sand mixture, and send measurement data to the data collecting module; the software recording and analyzing system is communicatingly connected with the data collecting module; the reactor system comprises first reactor units, second reactor units, third reactor units, ball valves, meshes, and caps; each of the first reactor units comprises a cylindrical casing with a first end being open and a second end being closed; each of the second reactor units and the third reactor units comprises a cylindrical casing with both ends being open; the cylindrical casing of each of the first reactor units, the second reactor units, and the third reactor units is provided with holes for disposing sensors; the first reactor units, the second reactor units, and the third reactor units are each provided with a pressure relief opening and a liquid discharging opening; the first reactor units and the third reactor units are each further provided with a sand inlet, a water inlet, a methane inlet, a production outlet, and a sight opening; the caps are each provided with a production outlet; and the first reactor units, the second reactor units, the third reactor units, the ball valves, the meshes, and the caps are configured to be combined in a plurality of ways to allow the reactor system to carry out the simulation experiment with either zero, one, or two view zones, with either one or two wells, and with the sand control screens being disposed at various positions in the natural gas hydrate reservoir. 2. The divisible device of claim 1 , wherein, the first reactor units and the third reactor units are further provided with moveable pistons, the second end of each of the first reactor units and the cylindrical casing of each of the third reactor units is provided with a nitrogen inlet configured to introduce nitrogen gas to drive the moveable pistons move toward the ends where materials are fed, wherein, each of the first reactor units is provided with one movable piston, wherein the one movable piston is movable toward the first end of the first reactor unit during operation, and each of the third reactor units is provided with two movable pistons, wherein the two movable pistons are each moveable toward either end of the third reactor unit during operation. 3. The divisible device of claim 2 , wherein, the reactor system is configured to carry out the simulation experiment with no view zone and one well, by assembling in an order of first reactor unit, ball valve, mesh, second reactor unit, mesh, and cap, wherein the first reactor unit is configured to simulate a hydrate zone, the combination of ball valve, mesh, second reactor unit, and mesh is configured to simulate a sand control screen zone, and the cap is configured to simulate a sand production outlet; wherein the reactor system being vertically assembled with the cap being disposed at bottom allows to carry out the simulation experiment with the sand control screens being disposed below the natural gas hydrate reservoir; or the reactor system being horizontally assembled allows to carry out the simulation experiment with the sand control screens being disposed laterally to the natural gas hydrate reservoir; or the reactor system being vertically assembled with the cap being disposed at top allows to carry out the simulation experiment with the sand control screens being disposed above the natural gas hydrate reservoir. 4. The divisible device of claim 3 , wherein, the caps are hemispherical caps when the reactor system is vertically assembled, or the caps are flat caps when the reactor system is horizontally assembled; a combination of one third reactor unit and one cap is equivalent to one first reactor unit. 5. The divisible device of claim 2 , wherein, the reactor system is configured to carry out the simulation experiment with no view zone and two wells, by assembling in an order of cap, mesh, second reactor unit, mesh, ball valve, third reactor unit, ball valve, mesh, second reactor unit, mesh, and cap, wherein the third reactor unit is configured to simulate a hydrate zone, each combination of ball valve, mesh, second reactor unit, and mesh is configured to simulate a sand control screen zone, and each cap is configured to simulate a sand production outlet; wherein the reactor system being vertically assembled allows to carry out the simulation experiment with the sand control screens being disposed above and below the natural gas hydrate reservoir; or the reactor system being horizontally assembled allows to carry out the simulation experiment with the sand control screens being disposed laterally to the natural gas hydrate reservoir. 6. The divisible device of claim 5 , wherein, the caps are hemispherical caps when the reactor system is vertically assembled, or the caps are flat caps when the reactor system is horizontally assembled; a combination of one third reactor unit and one cap is equivalent to one first reactor unit. 7. The divisible device of claim 2 , wherein, the reactor system is configured to carry out the simulation experiment with one view zone and one well, by assembling in an order of first reactor unit, ball valve, mesh, second reactor unit, mesh, and first reactor unit, wherein the first reactor unit adjacent to the ball valve is configured to simulate a hydrate zone, the combination of ball valve, mesh, second reactor unit, and mesh is configured to simulate a sand control screen zone, and the first reactor unit far away from the ball valve is configured to simulate the view zone and a sand production outlet; wherein the reactor system being vertically assembled with the ball valve being disposed at an upper side allows to carry out the simulation experiment with the sand control screens being disposed below the natural gas hydrate reservoir, wherein, the first reactor unit far away from the ball valve is equivalent to a combination of one third reactor unit and one cap; or the reactor system being vertically assembled with the ball valve being disposed at a lower side allows to carry out the simulation experiment with the sand control screens being disposed above the natural gas hydrate reservoir; or the reactor system being horizontally assembled allows to carry out the simulation experiment with the sand control screens being disposed laterally to the natural gas hyd