Portable efficient magnetic solid phase extraction device and extraction method thereof

What is claimed is: 1. A portable efficient magnetic solid phase extraction device, characterized in that: the device mainly comprises a contact reaction chamber ( 1 ), a circulating water inlet ( 2 ), a clear water basin ( 3 ), a three-way valve c( 4 ), a water delivery pipe a- 1 ( 5 - 1 ), a water delivery pipe a- 2 ( 5 - 2 ), a circulating pump ( 6 ), a circulating water outlet ( 7 ), a solid phase extractant collecting tank ( 8 ), a magnetic holder ( 9 ), an electromagnet ( 10 ), a solid-liquid separation area ( 11 ), a water outlet ( 12 ), a three-way valve d( 13 ), a water delivery pipe b- 1 ( 14 - 1 ), a water delivery pipe b- 2 ( 14 - 2 ), a drain pipe ( 15 ), a drain valve ( 16 ), a wall sprinkling water inlet ( 17 ), and a wall sprinkling pipe ( 18 ), wherein, the circulating water inlet ( 2 ) and the circulating water outlet ( 7 ) are respectively located at the upper part and lower part of the contact reaction chamber ( 1 ); the circulating water inlet ( 2 ) is connected to the three-way valve c( 4 ) via the water delivery pipe a- 1 ( 5 - 1 ); the circulating water outlet ( 7 ) is connected to the three-way valve c( 4 ) via a pipe; the clear water basin ( 3 ) is connected to the pipe between the circulating water outlet ( 7 ) and the three-way valve c( 4 ) via a pipe; the lower part of the contact reaction chamber ( 1 ) is connected to the solid-liquid separation area ( 11 ) via the water outlet ( 12 ); the solid phase extractant collecting tank ( 8 ), the electromagnet ( 10 ), and the magnetic holder ( 9 ) are sequentially disposed at the lower part of the solid-liquid separation area ( 11 ); the solid phase extractant collecting tank ( 8 ) is connected to the drain valve ( 16 ) via a pipe; the drain valve ( 16 ) is connected to the drain pipe ( 15 ); the sprinkling pipe ( 18 ) is located at the upper part inside the contact reaction chamber ( 1 ), and is connected to the wall sprinkling water inlet ( 17 ); the wall sprinkling water inlet ( 17 ) is connected to the three-way valve d( 13 ) via the water delivery pipe b- 1 ( 14 - 1 ); the three-way valve d( 13 ) is connected to the pipe between the solid phase extractant collecting tank ( 8 ) and the drain valve ( 16 ) via a pipe; the three-way valve d( 13 ) is connected to the circulating pump ( 6 ) via the water delivery pipe b- 2 ( 14 - 2 ); the circulating pump ( 6 ) is connected to three-way valve c( 4 ) via the water delivery pipe a- 2 ( 5 - 2 ); and the entire device is automatically controlled by a circuit. 2. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the contact reaction chamber ( 1 ) is made from stainless steel, and is in a conical shape; the circulating water inlet ( 2 ) is located 5-8 cm away from the upper edge of the contact reaction chamber ( 1 ); the diameters of the circulating water outlet ( 7 ) and the circulating water inlet ( 2 ) are 2-5 cm. 3. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the circulating pump ( 6 ) is located at the lower part of the device, and has a pump discharge rate of 16 L/min and a lift of 6 m; water enters the water delivery pipe a- 2 ( 5 - 2 ) from the circulating water inlet ( 2 ), flows through the circulating pump ( 6 ), and is sprayed upwards from the circulating water outlet ( 7 ) to perform hydraulic stir for 5-30 min. 4. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the solid phase extractant collecting tank ( 8 ), the magnetic holder ( 9 ), the electromagnet ( 10 ), and the solid-liquid separation area ( 11 ) are located 5-10 cm under the water outlet ( 12 ) of the contact reaction chamber ( 1 ); the magnetic holder ( 9 ) is located undermost; the electromagnet ( 10 ) and the solid phase extractant collecting tank ( 8 ) are sequentially disposed on the magnetic holder ( 9 ), the three of which closely press against each other. 5. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the solid-liquid separation area ( 11 ) is in an obconical shape, and has a diameter of 8-12 cm. 6. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the electromagnet ( 10 ) is in a circular shape, and has a diameter of 8-12 cm and a magnetic field strength of 300-1000 Gs. 7. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the solid phase extractant collecting tank ( 8 ) is in a downwards protruding dish shape; and the left side of the solid phase extractant collecting tank ( 8 ) is higher than the right side with a height difference of 1-2 cm. 8. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: an auxiliary wall sprinkling water inlet ( 17 ) is located 2-4 cm away from the upper edge of the contact reaction chamber ( 1 ); the wall sprinkling pipe ( 18 ) is located on a circumference as high as the wall sprinkling water inlet ( 17 ); and 6-10 number of sprinkler heads are uniformly distributed on the wall sprinkling pipe. 9. The portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the clear water basin ( 3 ) is located in front of the three-way valve c( 4 ), and has a volume of 100-300 mL. 10. An extraction method of the portable efficient magnetic solid phase extraction device as claimed in claim 1 , characterized in that: the method adopts the portable efficient magnetic solid phase extraction device, and comprises the steps of: (a) placing a to-be-treated water sample and a magnetic solid phase extractant in the contact reaction chamber ( 1 ), respectively; (b) setting the operating time and drain time of the circulating pump ( 6 ), switching on a power supply to start up the circulating pump ( 6 ), and enabling mixed solution to flow through the three-way valve c( 4 ) to fully and completely mix the magnetic solid phase extractant with the to-be-treated water sample, respectively; (c) closing the three-way valve c( 4 ), opening the water outlet ( 12 ) and the three-way valve d( 13 ), at the stage of collecting the solid phase extractant, in the solid-liquid separation area ( 11 ), collecting the solid phase extractant into the solid phase extractant collecting tank ( 8 ) under the action of the electromagnet ( 10 ), enabling the treated water sample to flow through the three-way valve d( 13 ) and arrive at the wall sprinkling pipe ( 18 ), and flushing a small amount of remaining solid phase extractant into the solid phase extractant collecting tank ( 8 ); (d) closing the three-way valve d( 13 ), opening the drain valve ( 16 ) to discharge the water sample, simultaneously opening the clear water basin ( 3 ) and the three-way valve c( 4 ), and utilizing clear water to flush the residual solid phase extractant in the pipe into the solid phase extractant collecting tank ( 8 ) for collection; and (e) after the collection is completed, removing the solid phase extractant collecting tank ( 8 ), taking out and storing the magnetic solid phase extractant for subsequent elution.