UA111271C2 - TWO-CYLINDER SUPERVISOR DEVICE FOR MAGNETIC SEPARATION OF KAOLIN - Google Patents

Abstract

The two-cylinder superconducting magnetic separation device for kaolin contains a superconducting magnetic system, separation system and feed system. The superconducting magnet system contains a superconducting magnet; liquid helium is used to cool a superconducting magnet; and an iron shield that covers the outer surface of the superconducting magnet, the cavity of separation located in the iron shield in the axial direction. The separation system includes a bracket, two rollers of magnetic separation, which are both mounted on the bracket, which are respectively located on either side of the cavity of the separation, and can be alternately inserted into the cavity of the separation, the magnetic material placed in each roller magnetic separation, whenwhen to move the rollers of the magnetic separation to move back and forth; and closed magnetic circuits, each located at one end of each magnetic separation roller, which is located closer to the separation cavity. The feed system comprises a feed tank which is used to feed the separable suspension into magnetic separation rollers; and a reservoir for pumping water, which is used for introduction into the rollers of magnetic separation, and is used for their purification. A two-cylinder superconducting magnetic separation device achieves a continuous production mode and therefore increases production efficiency.

Description

is used to introduce the suspension to be separated into magnetic separation rollers; and a tank for pumping water, which is used to enter the magnetic separation rollers, and is used for their cleaning. The two-cylinder superconducting magnetic separation device achieves a continuous production mode, and therefore improves production efficiency. schi shi ni ysyukiEnyshY Manure: N che KE p nn sho i 1, kn nin ep dizhi

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0001) Application claims priority to Chinese Patent Application 201210065971.5 entitled “Double-cylinder superconducting device for magnetic separation of kaolin”, filed with the State Intellectual Property Office of China on Mar. 13, 2012, the full disclosure of which is incorporated herein by reference.

The field of technology to which the invention belongs

II0002| The present invention relates to the technical field of magnetic separation devices, and, in particular, relates to a two-cylinder superconducting device for magnetic separation of kaolin.

Technical level

И0О00ОЗ3| As a major producer of non-metallic minerals, China is rich in non-metallic minerals such as kaolin, salt and potassium feldspar, and quartz. Kaolin as a resource

China, plays a very important role in the world production of non-metallic minerals. However, most of these minerals contain harmful substances such as iron. In order to improve the quality of non-metallic minerals, the iron content should be reduced. Therefore, the removal of iron is a major problem in the purification process of non-metallic minerals. 0004) At present, the high gradient magnetic separator is generally used in this field to remove iron from non-metallic minerals by filling media such as magnetically conductive stainless steel sponge or steel screen as a separation medium in a magnetic field inside the solenoid. Such media, being magnetized to a saturated state, can generate magnetic fields with a high gradient and intensity and have a large absorption area, and thus a wide range of applications. 0005) In a conventional high-gradient magnetic separator, the ore slurry processing cycle includes the following four operating conditions: preparation, processing, cleaning, and waiting. Due to the waiting mode of operation, the operating ratio is only in the range of 7595 to 83 95, that is, the processing operation is intermittent production and has about 20 95 idle time, so the production efficiency is low. 0006) In addition, the magnetic field intensity of the high-gradient magnetic separator is difficult to increase, and it can only reach about 1.6 X 106A / m (corresponding to the magnetic induction intensity of 27), which is approximately equal to the saturation magnetic field of the iron core.

In this way, the range of separation is limited. In addition, to generate a 2T magnetic field, a high gradient magnetic separator requires about 260 kW of power supply, which is 60 95 mineral processing costs per ton, thus the energy consumption is high. Therefore, the traditional high-gradient magnetic separator cannot separate non-metallic mineral products with the required quality level, and also has a limited application range and increased cost. (0007| Thus, the technical problem that must be solved by specialists in this field of technology is to provide a two-cylinder superconducting magnetic device for separating kaolin, which can realize continuous production and further improve its efficiency.

Brief description of the invention 0008) In this regard, the purpose of this invention is to develop a two-cylinder superconducting magnetic separation device for kaolin, which can realize continuous production and further improve production efficiency.

I0009)| To achieve the above goal, this application offers the following technical solutions.

I0010)| The two-cylinder superconducting magnetic separation device for kaolin includes a superconducting magnetic system, a separation system and a feeding system, which are distinguished by the fact that the superconducting magnetic system includes: - a superconducting magnet; - liquid helium for cooling the superconducting magnet; and - an iron shield for covering a superconducting magnet, which is characterized by the fact that the separation cavity is located in the iron shield in its axial direction; the separation system includes: a bracket; - two magnetic rollers for separation, which are both located on two sides of the separation cavity, respectively, and made with the possibility of alternately entering the separation cavity, and the magnetic medium located in each of the magnetic separation rollers; - drive device designed to drive magnetic separation rollers for reciprocating movement; and - a closed magnetic circuit of the transmission device, located at each of the ends of the magnetic separation rollers close to the separation cavity; the supply system includes: bo - tank for supply of suspension, which must be separated on magnetic separation rollers; and

- a tank for injecting water into magnetic separation rollers for their cleaning.

I0011| Preferably, in the double cylinder of the superconducting magnetic separation device, the superconducting magnetic system further includes a refrigerator for cooling the superconducting magnet.

I0012| Preferably, in the double cylinder of the superconducting magnetic separation device, the superconducting magnetic system further includes a cooling shield to cover the superconducting magnet, and the cooling outlet of the refrigerating machine is located so that it passes through the cooling iron shield.

I0013| Preferably, in the double cylinder of the superconducting magnetic separation device, the superconducting magnetic system further includes a housing to cover the superconducting magnet, and the housing is located in a cooling shield, and the liquid helium and the cooling end of the refrigerator are both located in the housing, and the liquid helium circulates in a closed loop in the case

I0014| Preferably, in a double cylinder superconducting magnetic separation device, the superconducting magnetic system further includes a Dewar vessel to cover the housing. 0015) Preferably, in the double cylinder of the superconducting magnetic separation device, the two ends of the superconducting magnet are always connected to the positive pole and the negative pole of the external electrical network through the positive current lead and the negative current lead, respectively.

ІІ0016| Preferably, in the double cylinder of the superconducting magnetic separation device, the end of each of the magnetic separation rollers far from the separation cavity is connected to the bracket by means of an organ pipe, and the corrugated pipe is telescopic in the axial direction of the iron shield.

I0017| Preferably, in a double cylinder superconducting magnetic separation device, the drive device may be an electric motor or a hydraulic cylinder.

I0018| Preferably, in a double cylinder superconducting magnetic separation device, the magnetic carrier consists of steel wool and/or a steel screen.

I0019| Preferably, in the double cylinder superconducting magnetic separation device, the superconducting magnet may be a solenoidal electromagnetic superconducting magnet.

From I0020| The two-cylinder superconducting magnetic separation device for kaolin according to this application includes a superconducting magnetic system, a separation system, and a feeding system.

The superconducting magnetic system includes: a superconducting magnet; liquid helium for cooling the superconducting magnet and an iron shield for covering the superconducting magnet, in which the separation cavity is located in the axial direction of the iron shield. The separation system includes: a bracket, two magnetic separation rollers, both of which are located on the bracket and on two sides of the separation cavity, respectively, and are designed to be alternately inserted into the separation cavity, and a magnetic medium located in each of the magnetic separation rollers; a drive device designed to drive magnetic separation rollers for their reciprocating movement; and a magnetic closed loop device with feedback located on each of the magnetic separation rollers at the ends close to the separation cavity. The supply system includes: a tank for supplying the suspension to be separated to the magnetic separation rollers; and a water injection tank for injecting water into the magnetic separation rollers to clean them. 0021) In the double-cylinder superconducting magnetic separation device for kaolin according to this application, the closed-loop magnetic feedback device together with the iron shield form a protective housing, and the iron shield limits the magnetic field inside the separation cavity for slurry treatment, thereby collecting magnetic field lines and reducing scattering fields in the separation cavity. Thus, the magnetic field provided by the superconducting magnet is divided into two regions: the high magnetic field region in the separation cavity, which is designed to capture magnetic particles from the ore pulp in the magnetic medium, also referred to as the separation region; and a low magnetic field outside the iron shield that is configured to clean the magnetic particles, also referred to as the cleaning area. Since the two magnetic separation rollers are alternately introduced into the separation cavity during the operation of the double cylinder of the superconducting magnetic separation device, one of the magnetic separation rollers is in the cleaning area, that is, in the cleaning operation condition, when the other magnetic separation roller is in the separation area, that is, in conditions of the separation operation. (00221 In conclusion, during the operation of the double-cylinder superconducting magnetic separation device for kaolin according to the present application, there is no waiting operation for ore slurry processing, thereby ensuring continuous production and further improvement of production productivity. (0023) Second, in double cylinder of the superconducting magnetic kaolin separation device according to this application, the magnetic field intensity in the cleaning area is extremely low and can be below 5005, thus, the magnetic particles captured by the magnetic medium can be easily washed away, which shortens the cleaning time, that is, reduces the time delay operation and reduces the high-pressure water cleaning time, and at the same time reduces the frequency of magnetic media replacement, and extends the life of the magnetic media.Furthermore, since the cleaning area is close to the separation area, the moving distance of the magnetic separation roller from the separation area to area for cleaning is reduced , which further reduces unproductive time at work.

Brief description of the drawings (0024) To more clearly illustrate the implementation options of this application or technical solutions in the conventional technology, the drawings, the mentioned described variants of the conventional technology will be briefly described below. Obviously, these drawings in the following description illustrate only a few variants of implementation of this application, and for a person skilled in the art, other drawings can be obtained based on these drawings without any creative effort. 0025) Fig. 1 is a schematic view of the structure of a double cylinder of a superconducting magnetic device for separating kaolin according to an embodiment of this application; 0026) Fig. 2 is a cross-sectional view of a part of the structure of the magnetic separation roller on the left side during the cleaning operation under the conditions of a double cylinder of a superconducting magnetic device for separating kaolin according to an embodiment of this application; 00271 Fig. 3 is a cross-sectional view of a part of the structure of the magnetic roller of separation to the right of the cleaning operation under the conditions of a double cylinder of a superconducting magnetic device for separating kaolin according to an embodiment of this application; and 0028) Fig. 4 is a sectional view of a part of the structure of a superconducting magnetic system of a double cylinder of a superconducting magnetic separator according to an embodiment of this application.

Detailed description of the invention

From I0029| An embodiment of this application describes a two-cylinder superconducting magnetic kaolin separation device that can realize continuous production and further improve production efficiency. 0030) The technical solutions in the embodiments of the present application will be described clearly and fully hereinafter in conjunction with the drawings so that the objects, technical solutions and advantages of the embodiments of the present application will be more clear. Obviously, the described variants of implementation are only a part of the variants of implementation of these applications, and not completely all variants. Based on the embodiments of the present invention, all other embodiments performed by a person skilled in the art without any creative effort fall within the scope of this application. 0031) Reference is made to Fig. 1-4. Fig. 1 is a schematic view of the structure of a double cylinder of a superconducting magnetic device for separating kaolin according to an embodiment of this application; Fig. 2 is a cross-sectional view of a part of the structure of the magnetic separation roller on the left side during the cleaning operation under the conditions of a double cylinder of a superconducting magnetic device for separating kaolin according to an embodiment of this application; Fig. C is a cross-sectional view of a part of the structure of the magnetic separation roller on the right side during the cleaning operation under the conditions of a double cylinder of a superconducting magnetic device for kaolin separation according to the embodiment of this application; and Fig. 4 is a cross-sectional view of part of the structure of the superconducting magnetic system of the two-cylinder superconducting magnetic separation device according to the embodiment of this application.

I0032| The two-cylinder superconducting magnetic separation device for kaolin according to an embodiment of this application includes a superconducting magnetic system, a separation system, and a feeding system. The superconducting magnetic system includes a superconducting magnet 1, liquid helium 2 for cooling the superconducting magnet 1, and an iron shield 11 to cover the superconducting magnet 1, and a separation cavity in the axial direction of the iron shield 11.

The system includes a bracket 9, two magnetic separation rollers 10 located on the bracket 9, a drive device 13 for actuating the magnetic separation rollers 10 for their reciprocating movement, a device 14 of a closed magnetic circuit connection, in which two magnetic rollers separations 10 are located on two sides of the separation cavity, respectively, and can be alternately introduced into the separation cavity, a magnetic carrier located in each of the magnetic rollers of the separation 10, a device 14 of a closed magnetic circuit connection,

located at each end of the magnetic separation rollers 10 near the separation cavity. The supply system includes a tank for supplying the suspension 7 to be separated in the magnetic separation rollers 10, and a water injection tank 8 for pumping water into the magnetic separation rollers 10 for their cleaning. 00331 The function of the closed magnetic circuit communication device 14 will be described as follows. To allow the magnetic separation rollers 10 to move in the separation cavity, a passage in the iron shield 11 must be located, and in this case, the magnetic field created by the superconducting magnet 1 cannot be fully utilized. In the case where the closed magnetic circuit communication device 14 is provided, the magnetic circuit can be formed by the interacting devices 14 and the iron shield 11, which covers the magnetic lines of force generated by the superconducting magnet 1 inside the iron shield 11, thus the magnetic energy can be fully utilized and the efficiency of superconducting magnet 1 is maximized.

I0034| A superconducting magnet using superconducting conductors as excitation coils can maintain a superconducting state under a high magnetic field, so the superconducting magnet can conduct a very large current, that is, have a high current density, and must meet the requirements of high field intensity, high uniformity, or high gradient. An additional current source is provided to supply power to the superconducting magnet, and thus increasing or decreasing the magnetic field is convenient and safe. In principle, a closed loop superconducting circuit can also be used and operated with a superconducting switch. A stable low temperature is necessary for the normal operation of a superconducting magnet.

I0035| In the double cylinder superconducting magnetic separation device for kaolin according to this embodiment, the closed magnetic circuit communication devices 14 together with the iron shield 11 form a protective case, and the iron shield 11 limits the magnetic field inside the separation cavity for slurry treatment, thereby collecting the magnetic lines of force and reducing the scattering field in the separation cavity. Thus, the magnetic field provided by the superconducting magnet 1 is divided into two regions: the region of high magnetic field in the separation cavity, which is made with the possibility of capturing magnetic particles in the suspension of the raw material together with the magnetic medium, and is also referred to as the region

From separation; and the region of low magnetic field outside the iron shield, which is designed with the possibility of cleaning magnetic particles and is also referred to as the cleaning area. Since the two magnetic separation rollers 10 alternately enter the separation cavity during the operation of the double cylinder of the superconducting magnetic separation device, one of the magnetic separation rollers 10 is in the cleaning area, that is, under the conditions of the cleaning operation, when the other of the magnetic separation rollers 10 is located in the separation area, that is, in the conditions of the separation operation. 0036) As shown in Fig. 2, which is a sectional view of part of the structure of the magnetic roller separation on the left side under cleaning conditions, and the magnetic roller 10 on the right side is currently under separation conditions. In this case, the magnetic separation roller 10 on the left side is located in the low magnetic field area outside the iron shield 11, the magnetic field strength in the low magnetic field area is below 5005, and the magnetic particles captured on the magnetic carrier inside the magnetic separation roller 10 can be easily washed away by injecting water into the magnetic separation roller 10 through the water injection tank 8. At the same time, the magnetic separation roller 10 on the right side is in the region of high magnetic field in the separation cavity inside the iron shield 11, and the sludge to be separated is fed into the magnetic separation roller 10 on the right side through the supply tank 7 and the magnetic particles in suspension are absorbed on the magnetic carrier, and then the magnetic separation roller 10 on the right side waits for the next cleaning operation.

I0037| While the magnetic separation roller devices 10 on the left side are cleaned, the supply tank 7 starts to supply the slurry, and the drive device 13 drives the two magnetic separation rollers 10 to move to the right together. The closed magnetic circuit communication device 14 formed by the protective case together with the iron shield 11 is broken, and the magnetic separation roller 10 on the left side immediately enters the high magnetic field area to perform the separation operation, and the magnetic separation roller 10 on the right side enters into the weak magnetic field region to perform a cleaning operation to wash away the magnetic particles captured in the previous separation operation mode. Reference is made to fig. 3, which is a cross-sectional view of part of the structure of the magnetic separation roller 10 on the right side under the condition of the cleaning operation. 0038) In conclusion, during the operation of the double cylinder of the superconducting magnetic kaolin separation device according to this embodiment, there is no waiting state for sludge processing, thereby ensuring continuous production and further improving production efficiency.

I0039| Second, in the double cylinder superconducting magnetic kaolin separation device according to this embodiment, the magnetic field intensity in the cleaning area is extremely low and can be below 5005, thus the magnetic particles captured by the magnetic medium can be easily washed away, which reduces cleaning time, that is, it reduces the operating time and reduces the cleaning time with high-pressure water, and at the same time reduces the frequency of replacing the magnetic media, and extends the life of this magnetic media. In addition, since the cleaning area is located close to the separation area, the moving distance of the magnetic roller 10 from the separation area to the cleaning area is shortened, which further reduces the operation time. 00401 In addition, since the separation cavity is the inner space bounded by the iron shield 11, its magnetic field has high intensity and uniformity, which maximizes the use of the high background magnetic field generated by the superconducting magnet 1, and the superconducting magnet 1 can improve the quality of the concentrate and increase the processing capability. . At the same time, since the two magnetic separation rollers 10 move at the same time, the electric magnetic forces are balanced, which reduces the requirements for the drive device 13. 00411 In addition, during the operation of the double cylinder superconducting magnetic separation device, the resistance of the magnet in the superconducting state is close to zero, so there is almost no power consumption, and compared to a conventional magnetic separation device, the power consumption can be reduced to 1/20, thereby further reducing the power consumption and cost of the device. In addition, the intensity of the magnetic field can be greatly improved (can be higher than 6T), and small particles of weak magnetic materials can be separated, which extends the separation range; and at the same time, the diameter of the processing passage can be greater than 1 m, which can increase the device's manufacturing capabilities by 10 times.

I0042| Preferably, in the double cylinder of the superconducting magnetic separation device, according to the above-described embodiments, the superconducting magnetic system additionally includes a refrigerator 4 for cooling the superconducting magnet 1. The refrigerator 4 and liquid helium 2 form a resource for cooling the superconducting magnet 1, which

Zo can maintain the superconducting magnet 1 in a stable working temperature, and this further improves the quality of work. 00431) In addition, in the double cylinder superconducting magnetic separation device according to the above-described embodiments, the superconducting magnetic system further includes a cooling shield 6 to cover the superconducting magnet 1, and the cooling end of the refrigerating machine 4 is located under the protection of the cooling shield b by passing through the iron shield 11. At this time, the refrigerating machine 4 is also used to cool the cooling shield b, which can reduce the heat radiation leakage of the room temperature. (0044) In order to further optimize the above-described embodiments, the superconducting magnetic system further includes a housing 5 to cover the superconducting magnet 1, and the housing 5 is located in the cooling shield 6, and the liquid helium 2 and the cooling end of the refrigerator 4 are both located in housing 5, and the liquid helium 2 circulates in a closed loop in the housing 5. At the same time, the cooling end of the refrigerator 4 recondenses the gaseous helium into a liquid flowing back into the housing 5 for continuous cooling of the superconducting magnet 1; and as shown in Fig.4, the arrow up refers to the direction of the flow of gaseous helium that evaporates from the liquid helium 2, and the arrow down refers to the direction of the flow of liquid that condenses from the gaseous helium. At the same time, liquid helium 2 circulates in a closed loop in housing 5 in such a way that helium will not evaporate into the environment with the help of a magnetic separator during normal operation, thereby avoiding the need for periodic replenishment of liquid helium, which further reduces the cost of operation .

II0045| In addition, in the double cylinder of the superconducting magnetic separation device according to the above-described embodiments, the superconducting magnetic system further includes a Dewar vessel C to cover the housing 5. The Dewar vessel C provides stable low temperature conditions for the superconducting magnet 1 and supports the magnet in the liquid temperature region helium, thus the magnet can maintain a superconducting state, which ensures its stable operation.

I0046| Preferably, in the double cylinder of the superconducting magnetic separation device according to the above-described embodiments, the two ends of the superconducting magnet 1 are always 60 connected to the positive pole and the negative pole of the external power source through the positive current conductor I and the negative current conductor II, respectively. During the operation of the double cylinder superconducting magnetic separation device, the superconducting magnet 1 is connected to the power source by the positive current conductor I and the negative current conductor Ii, and the connection is always maintained during operation and there is no superconducting switch, so the operating current can be adjusted , to increase, demagnetize and change the magnetic field intensity according to the practical properties of minerals so as to obtain a consistent magnetic field intensity, because the optimal separation effect can be realized, and the operation can be more flexible and simple, and easily controlled by field personnel. In addition, each of the positive current conductor 1 and the negative current conductor II are superconducting binary high-temperature conductors, thus, two stages of cooling are performed on two conductors in this embodiment, the first stage of cooling is carried out by the refrigerator 4, and the second the cooling step is carried out in liquid helium 2, thereby maintaining the two conductors at a superconducting temperature.

I0047| In addition, in the double cylinder of the superconducting magnetic separator according to the embodiments described above, one end far from the separation cavity of each of the magnetic separation rollers 10 is connected to the bracket 9 through the corrugated pipes 12, and the corrugated pipe 12 is telescopic in the axial direction iron shield 11. Thanks to the organ pipe 12, the magnetic separation roller 10 can have a sufficient amount of elongation so that it can move between the cleaning area and the separation area.

I0048| Corrugated pipe is a pipe for suction and transportation, and is especially suitable for the suction of solid materials such as powder and fiber, and gaseous and liquid media, and is often used for industrial dust removal and as a suction device for air conditioning and ventilation.

I0049| Corrugated pipe properties are described as follows. The corrugated pipe has a smooth inner part, which can optimize the flow of materials, and the corrugated pipe is telescopic, has good acid and alkaloid resistance, good chemical resistance, good anti-ultraviolet and ozone resistance, and the corrugated pipe has a small bending radius, thus, is not prone to bending and can prevent gas and liquid leakage.

From II0050| In the double cylinder of the superconducting magnetic separation device according to the above-described variants of implementation, the drive device 13 can be an electric motor, or a hydraulic cylinder, and can also be a gas cylinder, or another drive mechanism that can provide reciprocating movement of the magnetic separation rollers 10.

I0051) Preferably, in the double cylinder superconducting magnetic separators according to the above-described embodiments, the magnetic carriers include a steel sponge and/or a steel screen, and may also use pure electrical grade iron, Me10 steel as the magnetic medium, or use one or more sheets of pure iron of electrical grade, Me10 steel and steel screen, and there can also be a combination of substances from steel sponge and steel screen. Other magnetic materials may be selected according to the properties and size of the magnetic particles to be captured.

І0052| In order to further optimize the above-described embodiments, in the double cylinder of the superconducting magnetic separation device according to the above-described embodiments, the superconducting magnet 1 may be an electromagnetic solenoidal superconducting magnet. The background magnetic field that is generated by the superconducting magnet solenoid has an intensity much higher than that of a conventional permanent magnet, an electromagnet, and thus can provide a relatively high magnetic force that is able to process extremely small particles, thereby giving a high separation effect . 0053) The above description is only a preferred embodiment of this application. It should be noted that for one skilled in the art, some of the modifications and improvements may be made to this application without departing from the spirit of the application, and these modifications and improvements are also considered to be within the scope of the application.

Claims (10)

FORMULA OF THE INVENTION 1. A two-cylinder superconducting magnetic separation device for kaolin, including a superconducting magnetic system, a separation system, and a feed system, characterized in that the superconducting magnetic system includes: a superconducting magnet (1); liquid helium (2) for cooling the superconducting magnet (1); and an iron shield (11) for covering the superconducting magnet (1), which is characterized in that the separation cavity is located in the iron shield (11) in the axial direction of the iron shield (11); the separation system includes: bracket (9); two magnetic separation rollers (10), which are both located on two sides of the separation cavity, respectively, and configured to alternately enter the separation cavity, and a magnetic carrier placed in each of the magnetic separation rollers (10), and the end of each of magnetic separation rollers, distant from the separation cavity, connected to the bracket; drive device (13), designed to drive magnetic separation rollers (10) to alternate movement; and the device (14) of the connection of the closed magnetic circuit, which is located at each of the ends of the magnetic separation rollers (10), close to the separation cavity; supply system, which includes: suspension supply tank (7), which must be separated on magnetic separation rollers (10); and a water injection tank (8) for pumping water into the magnetic separation rollers (10) for their cleaning. 2. The two-cylinder superconducting magnetic separation device according to claim 1, characterized in that the superconducting magnetic system additionally includes a refrigerator (4) for cooling the superconducting magnet (1). 3. The two-cylinder superconducting magnetic separation device according to claim 2, which is characterized by the fact that the superconducting magnetic system additionally includes a cooling shield (b) to cover the superconducting magnet (1), and the cooling end of the refrigerating machine (4) is made in the cooling shield (6), passing through the iron shield (11). 4. The two-cylinder superconducting magnetic separation device according to item C, characterized in that the superconducting magnetic system additionally includes a housing (5) for covering the superconducting magnet (1), and the housing (5) is in the cooling shield (6), and liquid helium (2) and the cooling end of the refrigerating machine (4), both located in the housing (5), and the liquid helium (2) circulates in a closed loop in the housing (5). 5. A two-cylinder superconducting magnetic separation device according to claim 4, which is characterized in that the superconducting magnetic system additionally contains a Dewar vessel (3) to cover the body (5). 6. The two-cylinder superconducting magnetic separation device according to claim 1, in which the two ends of the superconducting magnet (1) are always connected to the positive pole and the negative pole of the external power source through the positive current conductor (I) and the negative current conductor (II), respectively. 7. The two-cylinder superconducting magnetic separation device according to claim 1, which is characterized in that the end of each of the magnetic separation rollers (10), remote from the separation cavity, is connected to the bracket (9) through a corrugated pipe (12), and the corrugated pipe ( 12) is telescopic in the axial direction of the iron shield (11). 8. A two-cylinder superconducting magnetic separation device according to claim 1, which is characterized in that the drive device (13) is an electric motor or a hydraulic cylinder. 9. A two-cylinder superconducting magnetic separation device according to any of claims 1-8, characterized in that the magnetic medium contains a steel sponge and/or a steel screen. 10. A two-cylinder superconducting magnetic separation device according to any one of claims 1-8, characterized in that the superconducting magnet (1) is an electromagnetic superconducting magnet.