Device and method for simulating layered stratum containing natural gas hydrates

What is claimed is: 1. A device for simulating a layered stratum containing natural gas hydrates, comprising a reactor, wherein the reactor comprises an upper cover, a lower cover, and a reactor body, wherein the upper cover and the lower cover are sealably attached to two ends of the reactor body to form a closed chamber; a temperature gradient simulator is disposed inside the reactor; an overlying pressure layer, a superstratum layer, a hydrate layer and a substratum layer are sequentially formed throughout an inside of the closed chamber from the upper cover to the lower cover, wherein each layer of the overlying pressure layer, the superstratum layer, the hydrate layer and the substratum layer is respectively filled with different kinds of porous media and fluids and the each layer is provided with a stratal-fluid annular container; the stratal-fluid annular container of the each layer has an outer periphery contacting an inner surface of the reactor body, and an inner periphery contacting the porous media and the fluids of the each layer through a porous plate; the stratal-fluid annular container of the each layer is communicated with a fluid replenishing module respectively, wherein the stratal-fluid annular container of the overlying pressure layer is communicated with an overlying pressure layer fluid replenishing module, the stratal-fluid annular container of the superstratum layer is communicated with a superstratum layer fluid replenishing module, the stratal-fluid annular container of the hydrate layer is communicated with a hydrate layer fluid replenishing module, and the stratal-fluid annular container of the substratum layer is communicated with a substratum layer fluid replenishing module; the reactor is provided with a gas inlet for introducing a methane gas into the closed chamber and a fluid inlet for introducing a fluid into the closed chamber; and a central exploitation wellbore penetrating a center of the reactor is disposed from the upper cover to the lower cover. 2. The device according to claim 1 , wherein each fluid replenishing module comprises a replenishing stratal fluid container, a fluid replenishing constant-flow pump, and a pipeline pressure sensor, wherein the replenishing stratal fluid container is communicated with the stratal-fluid annular container of the each layer through a pipeline provided with a detachable joint and a stratal fluid replenishing valve; and the pipeline pressure sensor is configured to turn on the fluid replenishing constant-flow pump when a pressure inside the stratal-fluid annular container of the each layer is lower than a predetermined value, and turn off the fluid replenishing constant-flow pump when the pressure inside the stratal-fluid annular container of the each layer reaches the predetermined value. 3. The device according to claim 2 , wherein a scale is provided inside the reactor along a height direction of the reactor, and the scale is configured to measure a thickness of the each layer. 4. The device according to claim 1 , wherein the replenishing stratal fluid container of the each fluid replenishing module is filled with a stratal fluid, provided with a cover, and placed on a weighing machine. 5. The device according to claim 4 , wherein a scale is provided inside the reactor along a height direction of the reactor, and the scale is configured to measure a thickness of the each layer. 6. The device according to claim 1 , wherein a scale is provided inside the reactor along a height direction of the reactor, and the scale is configured to measure a thickness of the each layer. 7. The device according to claim 1 , wherein the temperature gradient simulator comprises an upper circulation coil and a lower circulation coil; wherein the upper circulation coil and the lower circulation coil are respectively disposed at an upper end and a lower end inside the reactor body; the upper circulation coil and the lower circulation coil are respectively provided with an independent heat exchange device to realize a circulation of a heat transfer medium in the upper circulation coil and the lower circulation coil; N temperature control pipes are spacedly provided inside the reactor body and between the upper circulation coil and the lower circulation coil, and configured to form a vertical temperature gradient in the reactor body, wherein N is a positive integer; each of the N temperature control pipes is also provided with an independent heat exchange device to realize a circulation of a heat transfer medium in the each of the N temperature control pipes. 8. The device according to claim 7 , wherein the N temperature control pipes are equally spaced from bottom to top and a constant temperature difference is given between the N temperature control pipes, wherein the constant temperature difference is expressed as: ΔT=(T 1 −T 2 )/(N+1), wherein T 2 represents a temperature of the lower circulation coil, and T 1 represents a temperature of the upper circulation coil. 9. The device according to claim 8 , wherein temperature sensors are provided inside the reactor body and configured to monitor the temperature of the upper circulation coil, the temperature of the lower circulation coil and temperatures of the N temperature control pipes and transmit monitored temperature data to a regulator; and the regulator is configured to regulate an operation of the first heat exchange device and an operation of the second heat exchange device according to the monitored temperature data in real time to maintain the vertical temperature gradient in the reactor body stable. 10. A method for simulating a layered stratum containing natural gas hydrates by using the device according to claim 1 , comprising the following steps: filling the reactor with the porous media and introducing the methane gas and the fluids into the rector according to required compositions of the superstratum layer, the hydrate layer and the substratum layer, reserving a space for the overlying pressure layer, and then sealing the reactor; checking a gas tightness of the reactor; reducing a temperature inside the reactor to a simulated stratal temperature; setting a predetermined value for turning on a fluid replenishing constant-flow pump, wherein the predetermined value for the overlying pressure layer is set to a value simulating an overlying pressure at seafloor; monitoring a pressure inside the reactor; when the pressure inside the reactor is stable, conducting a simulation of a natural gas hydrate exploitation process, wherein during the simulation, a water-gas-sand mixture is continuously produced from the central exploitation wellbore and a pressure at the each layer in the reactor reduces; when the pressure at a layer of the each layer is lower than the predetermined value, turning on the fluid replenishing constant-flow pump to replenish the stratal-fluid annular container with a stratal fluid, wherein the stratal fluid flows to the layer through the porous plate, and when the pressure at the layer reaches the predetermined value, turning off the fluid replenishing constant-flow pump; recording a mass change of the stratal fluid during the simulation to obtain a replenishing amount of the stratal fluid.