SWRO and MCDI coupled seawater desalination device system with energy recovery

What is claimed is: 1. A seawater reverse osmosis (SWRO) and membrane capacitive deionization (MCDI) coupled seawater desalination device system with energy recovery, characterized in that the SWRO and MCDI coupled seawater desalination device system with energy recovery comprises a pre-filtering unit, an SWRO treatment unit, an MCDI treatment unit, and a post-filtering unit, wherein the SWRO treatment unit comprises a seawater desalination water passage comprising a high-pressure pump and an RO primary desalination equipment, and a self-pressurization energy recovery device, pretreated seawater obtained after raw seawater being treated by the pre-filtering unit is connected to the RO primary desalination equipment through the high-pressure pump, the pretreated seawater is desalinated in a high-concentration section in the RO primary desalination equipment to obtain high-pressure concentrated seawater and primary fresh seawater, the high-pressure concentrated seawater flows into the self-pressurization energy recovery device to pressurize the pretreated seawater flowing into the self-pressurization energy recovery device, so that the pretreated seawater is pressurized to a pressure required by the RO primary desalination equipment, the high-pressure concentrated seawater is discharged after depressurized, and the pretreated seawater is connected to the RO primary desalination equipment after pressurized to realize continuous water passage desalination and continuous recovery of high-pressure brine energy; and the MCDI treatment unit comprises an MCDI assembly A, an MCDI assembly B, and an MCDI assembly C arranged in parallel, the MCDI assembly A desalinates the primary fresh seawater in a low-concentration section to obtain secondary fresh seawater, the MCDI assembly B desorbs the pretreated seawater and charges the MCDI assembly C at the same time, wastewater is discharged after the desorption by the MCDI assembly B, the MCDI assembly A, the MCDI assembly B, and the MCDI assembly C work sequentially and alternately to realize continuous water passage desalination and continuous recovery of energy released during the desorption by the MCDI assembly, and the secondary fresh seawater is connected to the post-filtering unit to be treated to obtain direct-drinking fresh water, wherein the self-pressurization energy recovery device in the SWRO treatment unit comprises: a reversing valve, a center valve block, a pilot valve, a hydraulic cylinder A, and a hydraulic cylinder B; for the center valve block, two side walls of the center valve block are connected with the hydraulic cylinder A and the hydraulic cylinder B respectively, a piston assembly is provided in the hydraulic cylinder A and the hydraulic cylinder B, a piston rod hole is formed in the center valve block, two ends of a piston rod of the piston assembly extend into the hydraulic cylinder A and the hydraulic cylinder B respectively, a rod body of the piston rod penetrates through the piston rod hole, a pilot valve channel is arranged in a lower part of the center valve block and configured to place the pilot valve, a reversing valve channel is arranged in an upper part of the center valve block and configured to place the reversing valve, and a plurality of flow passages are arranged in the center valve block; for the hydraulic cylinder A and the hydraulic cylinder B, the hydraulic cylinder A and the hydraulic cylinder B are divided into six chambers by the piston assembly, the piston assembly sequentially divides the hydraulic cylinder A into a seawater chamber A, a transition chamber A, and a concentrated water chamber A from left to right, the piston assembly sequentially divides the hydraulic cylinder B into a seawater chamber B, a transition chamber B, and a concentrated water chamber B from right to left, and a cross sectional area of the seawater chambers is smaller than a cross sectional area of the concentrated water chambers; for the pilot valve, the pilot valve is located between the concentrated water chamber A and the concentrated water chamber B, two ends of a valve rod of the pilot valve extend to the concentrated water chamber A and the concentrated water chamber B respectively, five holes are formed in the pilot valve channel, namely, an outflow hole I, an inflow/outflow hole II, an inflow hole III, an inflow/outflow hole IV, and an outflow hole V from left to right, the outflow hole I is communicated with a discharged seawater outlet end to form a ninth channel, the outflow hole V is communicated with the discharged seawater outlet end to form a tenth channel, and the inflow hole III is communicated with a seawater inlet end to form a first channel; for the reversing valve, a seawater hole I, a concentrated water hole II, a concentrated water hole III, a concentrated water hole IV, a concentrated water hole V, a concentrated water hole VI, and a seawater hole VII are formed in the reversing valve channel from left to right respectively, the seawater hole I is communicated with the inflow/outflow hole II of the pilot valve to form a second channel, the seawater hole VII is communicated with the inflow/outflow hole IV of the pilot valve to form a third channel, the concentrated water hole II and a depressurized concentrated seawater outlet form a seventh channel, the concentrated water hole VI and the depressurized concentrated seawater outlet form an eighth channel, the concentrated water hole III is communicated with the concentrated water chamber A to form a fourth channel, the concentrated water hole V is communicated with the concentrated water chamber B to form a fifth channel, and the concentrated water hole IV is communicated with a high-pressure concentrated seawater inlet end to form a sixth channel; for a check valve A, a check valve B, a check valve C, and a check valve D, a rectangular flow passage is formed in the center valve block, the check valve A, the check valve B, the check valve D, and the check valve C are sequentially arranged at four top corners of the rectangular flow passage counterclockwise, the seawater chamber A is communicated with the check valve A and the check valve C through a flow passage, and the seawater chamber B is communicated with the check valve B and the check valve D through a flow passage, wherein a thrust required for pushing the check valve A and the check valve B open is smaller than a thrust required for pushing the check valve C and the check valve D open, the pretreated seawater flows to the seawater chamber A from the check valve A, the high-pressure seawater of the seawater chamber A flows to the check valve C and makes the check valve C opened and the check valve A closed, the pretreated seawater flows to the seawater chamber B from the check valve B, and the high-pressure seawater of the seawater chamber B flows to the check valve D and makes the check valve D opened and the check valve B closed; and the high-pressure concentrated seawater controls the movement of the piston assembly, when the piston assembly moves to a position close to a limit position, the pilot valve is pushed to move, the pilot valve controls the reversing valve to be reversed, the reversing valve also moves accordingly, purpose of alternately pressurizing and depressurizing the hydraulic cylinder A and the hydraulic cylinder B is achieved, the check valve A and the check valve B control the inflow of the low-pressure raw seawater, and the check valve C and the check valve D control the outflow of the pressurized seawater. 2. The SWRO and MCDI coupled seawater desalination device system with energy recovery according to claim 1 , characterized in that the pre-filtering unit comprises a raw water pump, a multi-medium filter, and a micro-filter sequentially connected through a pipeline, and the raw seawater is treated by the raw water pump, the multi-medium filter, and the micro-filter to obtain the