EP2878818B1 - Permanent magnet linear piston pump - Google Patents
Permanent magnet linear piston pump Download PDFInfo
- Publication number
- EP2878818B1 EP2878818B1 EP12881862.2A EP12881862A EP2878818B1 EP 2878818 B1 EP2878818 B1 EP 2878818B1 EP 12881862 A EP12881862 A EP 12881862A EP 2878818 B1 EP2878818 B1 EP 2878818B1
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- EP
- European Patent Office
- Prior art keywords
- disposed
- piston
- mounting plate
- permanent magnet
- cylinder body
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B17/00—Pumps characterised by combination with, or adaptation to, specific driving engines or motors
- F04B17/03—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors
- F04B17/04—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors using solenoids
- F04B17/042—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors using solenoids the solenoid motor being separated from the fluid flow
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B17/00—Pumps characterised by combination with, or adaptation to, specific driving engines or motors
- F04B17/03—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors
- F04B17/04—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors using solenoids
- F04B17/042—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors using solenoids the solenoid motor being separated from the fluid flow
- F04B17/044—Pumps characterised by combination with, or adaptation to, specific driving engines or motors driven by electric motors using solenoids the solenoid motor being separated from the fluid flow using solenoids directly actuating the piston
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B53/00—Component parts, details or accessories not provided for in, or of interest apart from, groups F04B1/00 - F04B23/00 or F04B39/00 - F04B47/00
- F04B53/14—Pistons, piston-rods or piston-rod connections
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B53/00—Component parts, details or accessories not provided for in, or of interest apart from, groups F04B1/00 - F04B23/00 or F04B39/00 - F04B47/00
- F04B53/16—Casings; Cylinders; Cylinder liners or heads; Fluid connections
Definitions
- the present invention relates to a linear piston pump, and more particularly to a permanent magnet linear piston pump.
- the advantages of the magnetic-force linear piston pump contain a high operating pressure, a simple structure, a low consumption of energy and noises and a long durability. Therefore, it becomes more and more important and is applied to more and more applications.
- the mechanical movement and principle of the magnetic-force linear piston pump are similar to those of the plunger pump. Both of them take advantage of the relative reciprocating motion between the piston and the cylinder body to incur the variable capacity of the sealed piston cavity inside the pump, thereby inputting and outputting the fluid medium.
- a prior disclosure of CN1554868 as published on 2004/12/15 and named by "magnetic-force linear piston pump” discloses a magnetic-force linear piston pump which comprises a housing in which a cylinder body and a piston are disposed.
- the piston is disposed inside the cylinder body with an axial movable airtight fit.
- On the outer periphery of the cylinder body is an electromagnetic coil.
- the electromagnetic coil is fixed into the housing.
- the electromagnetic coil is connected to an oscillating power supply.
- a permanent magnet is further disposed on the outer periphery of the cylinder body.
- the permanent magnet and the cylinder body are connected and positioned.
- One end of the piston is fixed to the housing, and the other end thereof is disposed within an inner hole of the cylinder body.
- a fluid hole is disposed on the piston.
- a first unidirectional valve and a second unidirectional valve are relatively disposed in the fluid hole or in the inner cavity of the cylinder body, thereby constructing three opposite and independent cavities in sequence, namely a low-pressure cavity, a variable-capacity operating cavity and a high-pressure cavity.
- the low-pressure cavity is communicated with an inlet pipe.
- the high-pressure cavity is communicated with an outlet pipe.
- the electromagnetic coil is disposed inside the housing, the structure is unreasonable, which incurs an inconvenient installation.
- the electromagnetic coil and the permanent magnet are all set in the low-pressure cavity, so the sealing treatment to the electromagnetic coil and the permanent magnet is necessary, which incurs a complexity of the manufacture, high costs and hard promotions.
- KR 2010 0062665 A discloses a permanent magnet linear piston pump according to the preamble of claim 1.
- US 2002/0146334 A1 discloses a linear engine, comprising a tubular housing, axially spaced electromagnetic coils disposed around the tubular housing, a piston disposed within the tubular housing, the piston including magnetic elements, and a drive circuit electrically connected to the first and second electromagnetic coils for sequentially energizing the first and second electromagnetic coils to reciprocate the piston within the tubular housing.
- a magnetic sleeve is disposed within each coil, with the piston being arranged to pass through the magnetic sleeves during operation and the magnetic sleeves being separated by non magnetic material.
- the magnetic sleeves each form part of the tubular housing.
- Sealed bearings at each end of the piston define a sump for retaining lubricating oil within a reduced diameter portion of the piston.
- the sealed bearings each comprise axially spaced circumferentially extending ribs, adjacent ribs being separated by a gap for receiving a sealing element.
- the object of the present invention is to overcome the aforementioned problems and to provide a permanent magnet linear piston pump having a simple structure, more convenient manufacture and lower costs.
- the permanent magnet linear piston pump in accordance with the present invention is as defined in claim 1 and comprises a piston body, a cylinder body, a permanent magnet assembly and an electromagnetic coil.
- the cylinder body is in a shape of a polygonal prism, an interior of which arranges a piston cavity formed by an axial columnar accommodating cavity.
- the piston body is arranged in the piston cavity by a liquid sealing movable fit mode.
- a one-way inlet valve and a one-way outlet valve are disposed on an end face of the piston cavity opposite to an end face of a piston.
- a set of permanent magnet assembly is disposed on at least one side surface of the cylinder body.
- the permanent magnet assembly includes an inner mounting plate and an outer mounting plate disposed parallel to the side surface of the cylinder body.
- the inner plate and the outer mounting plate are made of a permeability magnetic material.
- An inner magnetic body and an outer magnetic body are respectively disposed on opposite surfaces of the inner mounting plate and the outer mounting plate.
- the inner magnetic body and the outer magnetic body are disposed oppositely and provide contrary magnetic poles at opposite faces thereof.
- a coil supporting member is disposed at an outside surface of the cylinder body.
- the electromagnetic coil is axially and distributively wound around the coil supporting member into a barrel shape.
- a barrel wall formed by the electromagnetic coil is disposed between the inner magnetic body and the outer magnetic body.
- An axial sliding slot is formed on the side surface of the cylinder body where the permanent magnet assembly is disposed.
- a connecting post is disposed on a side surface of the piston body in a radial direction to fit in with the sliding slot by a clearance fit mode.
- the connecting post penetrates through the sliding slot to be in connection with and in linkage with the inner mounting plate and the outer mounting plate.
- the present invention has the electromagnetic coil which is axially and distributively wound around the coil supporting member at the outside surface of the cylinder body and needs not subject the electromagnetic coil to a sealing treatment, which attains a simple structure, more convenient manufacture, lower costs, a reliable operation and convenient maintenance.
- two parts of the columnar accommodating cavity in the cylinder body are disposed symmetrically.
- the piston body is disposed at a middle portion of the columnar accommodating cavity.
- Two ends of the piston body are in cooperation with the two parts of the columnar accommodating cavity by the liquid sealing movable fit mode respectively, whereby the two parts of the columnar accommodating cavity are respectively defined as a first piston cavity and a second piston cavity, and the two ends of the piston body are respectively defined as a first piston body and a second piston body.
- a first one-way inlet valve and a first one-way outlet valve are disposed on an end face of the first piston cavity opposite to an end face of the first piston body.
- a second one-way inlet valve and a second one-way outlet valve are disposed on an end face of the second piston cavity opposite to an end face of the second piston body.
- a first inner magnetic body and a second inner magnetic body are respectively and symmetrically disposed at two ends of the inner mounting plate.
- a first outer magnetic body and a second outer magnetic body are respectively and symmetrically disposed at two ends of the outer mounting plate.
- a first electromagnetic coil and a second electromagnetic coil are respectively and correspondingly disposed on ribs at two sides of the cylinder body. Accordingly, the same cylinder body forms two permanent magnet linear piston pumps, and the piston body can be in the operating status during the reciprocating motion to attain the higher efficiency.
- one set of permanent magnet assembly is arranged at each side surface of the cylinder body, which allows the permanent magnet linear piston pump to have a greater power.
- the cylinder body includes a barrel unit and lids at two ends thereof. Sealing rings are respectively disposed between the lids at the two ends and two end faces of the barrel unit.
- the barrel unit and the lids at the two ends are connected with each other by a plurality of axial shanks and nuts around an outer periphery of the barrel unit.
- the shanks construct the coil supporting member. Accordingly, such arrangement designing the cylinder body and the coil supporting member attains a simple structure, a simple manufacturing technique and lower costs.
- ribs are disposed on edges of the cylinder body.
- the ribs construct the coil supporting member.
- the inner mounting plate and the inner magnetic body are disposed in a recess between the ribs at two sides of a same side surface of the cylinder body. Accordingly, such arrangement designing the cylinder body and the coil supporting member attains a simple structure, a simple manufacturing technique, a firm structure and high mechanical intensity.
- the cylinder body can be a prism having four to six sides, especially a quadrangular prism whose cross-section is in a rectangular shape, whereby the cylinder body in this shape is easier to be processed.
- the inner mounting plate and the outer mounting plate are made of a permeability magnetic material.
- a magnetizing coil is sleeved on the inner mounting plate or/and the outer mounting plate.
- a magnetic field line created by the magnetizing coil is formed in a closed annular shape along the inner mounting plate, the inner magnetic body, the outer magnetic body and the outer mounting plate. Accordingly, the magnetizing coil is sleeved on the inner mounting or/and the outer mounting plate, so an external magnetizing power supply in connection with the magnetizing coil magnetizes the inner magnetic body and the outer magnetic body to retrieve their intensity of magnetism when the intensity of magnetism of two magnetic bodies becomes lessened due to a long term of using the permanent magnet linear piston pump, thereby prolonging the duration of the permanent magnet linear piston pump.
- a permanent magnet linear piston pump 3 of the present invention comprises a piston body 1, a cylinder body 2, a permanent magnet assembly 6 and an electromagnetic coil 3.
- the cylinder body is in a shape of a polygonal prism, such as in a prism with four to six sides.
- a quadrangular prism is adopted.
- this preferred embodiment has a quadrangular cylinder body 2 whose cross-section is shaped by a rectangular contour.
- An interior of the cylinder 2 arranges a piston cavity 201 formed by an axial columnar accommodating cavity.
- the piston body 1 is arranged in the piston cavity 201 by a liquid sealing movable fit mode.
- a cross-section of one end of the piston body 1 can be the same as the cross-section of the piston cavity 201. This end is inserted into the piston cavity 201 by the liquid sealing movable fit mode.
- the piston body 1 is a prism whose cross-section is the same as the cross-section of the piston cavity 201.
- the end of the piston body 1 is inserted into the piston cavity 201 by the liquid sealing movable fit mode; preferably, the other end thereof can arrange a supporting structure having an orientation effect.
- a one-way inlet valve 4 and a one-way outlet valve 5 are disposed on an end face of the piston cavity 201 opposite to an end face of a piston.
- a set of permanent magnet assembly 6 is disposed on at least one side surface of the cylinder body 2.
- the permanent magnet assembly 6 includes an inner mounting plate 601 and an outer mounting plate 602 disposed parallel to the side surface of the cylinder body 2.
- An inner magnetic body 603 and an outer magnetic body 604 are respectively disposed on opposite surfaces of the inner mounting plate 601 and the outer mounting plate 602, whereby the permanent magnet linear piston pump has a greater power.
- One set of the permanent magnet assembly 6 is disposed on every side surface of the cylinder body 2.
- a coil supporting member is disposed at an outside surface of the cylinder body 2. The arrangement of the coil supporting member is to space the electromagnetic coil 3 and the outside surface of the cylinder body apart by a distance in order that the inner mounting plate 601 and the inner magnetic body 603 can be placed in this space.
- the electromagnetic coil 3 is axially and distributively wound around the coil supporting member into a barrel shape.
- the cylinder body 2 can include a barrel unit and lids at two ends thereof. Sealing rings are respectively disposed between the lids at the two ends and two end faces of the barrel unit.
- the barrel unit and the lids at the two ends are connected with each other by a plurality of axial shanks and nuts around an outer periphery of the barrel unit.
- the shanks are located at every edge of the cylinder body 2.
- the shanks construct the coil supporting member.
- the cylinder body 2 and the coil supporting member of this arrangement are simple in structure and easier to manufacture and have lower costs although the mechanical intensity may be relatively lower. As shown in Fig.
- ribs 202 are disposed on every edge of the cylinder body 2.
- the ribs 202 construct the coil supporting member.
- the ribs 202 can be extended throughout the full edge or extended to the part of the two ends where the electromagnetic coil 3 is wound.
- the ribs 202 are disposed to allow the surface of the cylinder body 2 to have a sufficient space where the inner mounting plate 601 and the inner magnetic body 603 are placed.
- the inner mounting plate 601 and the inner magnetic body 603 are disposed in a recess between the ribs 202 at two sides of a same side surface of the cylinder body 2.
- the inner magnetic body 603 and the outer magnetic body 604 are disposed oppositely and provide contrary magnetic poles at opposite faces thereof.
- An interstice is formed between the inner magnetic body 603 and the outer magnetic body 604.
- the interstice can be lessened possibly to satisfy the coiling of the electromagnetic coil 3.
- the electromagnetic coil 3 is axially and distributively wound around the ribs 202 of every edge into a barrel type. Alternatively, it can be wound around the ribs 202 on which a pad or a bracket is disposed in advance.
- the electromagnetic coil 3 is disposed between the inner magnetic body 603 and the outer magnetic body 604.
- the side surface of the cylinder body 2 where the permanent magnet assembly 6 is disposed forms an axial sliding slot 203.
- a length of the sliding slot 203 is equal to a designed stroke length of the piston body 1.
- a connecting post 101 is disposed on a side surface of the piston body 1 in a radial direction to fit in with the sliding slot 203 by a clearance fit mode.
- the connecting post 101 penetrates through the sliding slot 203 to be connected to the inner mounting plate 601 and the outer mounting plate 602, thereby forming a linkage.
- through holes are respectively formed on the inner mounting plate 601 and the outer mounting plate 602 to fit in with the connecting post 101 by a clearance fit mode.
- the connecting post 101 penetrates through the sliding slot 203 and the through holes of the inner mounting plate 601 and the outer mounting plate 602 to be in connection with and in linkage with the inner mounting plate 601 and the outer mounting plate 602.
- the piston body 1 is in the operating state during the reciprocating motion.
- two permanent magnet linear piston pumps are formed in the same cylinder body 2. Referring to Figs. 5-7 , two parts of the columnar accommodating cavity in the cylinder body 2 are disposed symmetrically.
- the piston body 1 is a prism whose cross-section is the same as the cross-section of the piston cavity 201.
- the piston body 1 is disposed at a middle portion of the columnar accommodating cavity.
- Two ends of the piston body 1 are in cooperation with the two parts of the columnar accommodating cavity by the liquid sealing movable fit mode respectively, whereby the two parts of the columnar accommodating cavity are respectively defined as a first piston cavity 2011 and a second piston cavity 2012, and the two ends of the piston body 1 are respectively defined as a first piston body 1a and a second piston body 1b.
- a first one-way inlet valve 4a and a first one-way outlet valve 5a are disposed on an end face of the first piston cavity 2011 opposite to an end face of the first piston body 1a.
- a second one-way inlet valve 4b and a second one-way outlet valve 5b are disposed on an end face of the second piston cavity 2012 opposite to an end face of the second piston body 1b.
- the permanent magnet assembly 6, as shown in Figs. 7-9 includes an inner mounting plate 601 and an outer mounting plate 602 disposed parallel to the side surface of the cylinder body 2.
- a first inner magnetic body 603a and a second inner magnetic body 603b are respectively and symmetrically disposed at two opposite end faces of the inner mounting plate 601.
- a first outer magnetic body 604a and a second outer magnetic body 604b are respectively and symmetrically disposed at two ends of the outer mounting plate 602.
- a first electromagnetic coil 3a and a second electromagnetic coil 3b are respectively and correspondingly disposed on ribs 202 at two sides of the cylinder body 2.
- the inner mounting plate 601 and the inner magnetic body 603 are disposed in a recess between the ribs 202 at two sides of the same side surface of the cylinder body 2.
- the first inner magnetic body 603a and the first outer magnetic body 604a at the two ends are disposed oppositely and provide contrary magnetic poles at opposite faces thereof.
- the second inner magnetic body 603b and the second outer magnetic body 604b at the two ends are disposed oppositely and provide contrary magnetic poles at opposite faces thereof.
- Interstices are respectively formed between the first inner magnetic body 603a and the first outer magnetic body 604a and between the second inner magnetic body 603b and the second outer magnetic body 604b. The interstice can be lessened possibly to satisfy the coiling of the electromagnetic coil 3.
- the electromagnetic coil 3 is axially and distributively wound around the ribs 202 of every edge of the two ends of the cylinder body 2 into a barrel type. Alternatively, it can be wound around the ribs 202 on which a pad or a bracket is disposed in advance.
- the electromagnetic coils 3 are respectively disposed between the first inner magnetic body 603a and the first outer magnetic body 604a and between the second inner magnetic body 603b and the second outer magnetic body 604b.
- the side surface of the cylinder body 2 where the permanent magnet assembly 6 is disposed forms an axial sliding slot 203.
- four permanent magnet assemblies 6 are respectively set on four side surfaces of the cylinder body 2, with four sliding slots 203 formed on the four side surfaces of the cylinder body 2 respectively.
- a length of the sliding slot 203 is equal to a designed stroke length of the piston body 1.
- Four connecting posts 101 are respectively disposed on four sides of the piston body 1 in a radial direction to fit in with the sliding slots 203 by a clearance fit mode.
- the connecting posts 101 penetrate through the sliding slots 203 to be connected to the inner mounting plate 601 and the outer mounting plate 602, thereby forming a linkage.
- this preferred embodiment forms through holes which are respectively formed on the inner mounting plate 601 and the outer mounting plate 602 to fit in with the connecting post 101 by a clearance fit mode.
- the connecting posts 101 penetrate through the sliding slots 203 and the through holes of the inner mounting plate 601 and the outer mounting plate 602 to be in connection with and in linkage with the inner mounting plate 601 and the outer mounting plate 602.
- the permanent magnet linear piston pump of the present invention can be magnetized.
- the remaining structure of the magnetizing permanent magnet linear piston pump is the same as the first and the second preferred embodiments.
- the inner mounting plate 601 and the outer mounting plate 602 are made of a permeability magnetic material.
- a magnetizing coil 7 is sleeved on the inner mounting plate 601 or the outer mounting plate 602.
- the magnetizing coil 7 of this embodiment is sleeved on the inner mounting plate 601 and the outer mounting plate 602.
- the magnetizing coil 7 can be wound around a coil frame 8 of a " " shape at first. Then, the inner mounting plate 601 or the outer mounting plate 602 can penetrate through the center of the coil frame 8. The coil frame 8 is fixed onto the cylinder body 2. A magnetic field line created by the magnetizing coil 7 is formed in a closed annular shape along the inner mounting plate 601, the inner magnetic body 603, the outer magnetic body 604 and the outer mounting plate 602.
- the one-way inlet valve 4 and the one-way outlet valve 5 can be designed by using a diaphragm structure or by disposing a steel ball and a compression spring in the valve cavity. These arrangements can all satisfy the requirements.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Fluid Mechanics (AREA)
- Electromagnetic Pumps, Or The Like (AREA)
- Reciprocating Pumps (AREA)
Description
- The present invention relates to a linear piston pump, and more particularly to a permanent magnet linear piston pump.
- The advantages of the magnetic-force linear piston pump contain a high operating pressure, a simple structure, a low consumption of energy and noises and a long durability. Therefore, it becomes more and more important and is applied to more and more applications. The mechanical movement and principle of the magnetic-force linear piston pump are similar to those of the plunger pump. Both of them take advantage of the relative reciprocating motion between the piston and the cylinder body to incur the variable capacity of the sealed piston cavity inside the pump, thereby inputting and outputting the fluid medium. A prior disclosure of
CN1554868 as published on 2004/12/15 and named by "magnetic-force linear piston pump" discloses a magnetic-force linear piston pump which comprises a housing in which a cylinder body and a piston are disposed. The piston is disposed inside the cylinder body with an axial movable airtight fit. On the outer periphery of the cylinder body is an electromagnetic coil. The electromagnetic coil is fixed into the housing. The electromagnetic coil is connected to an oscillating power supply. A permanent magnet is further disposed on the outer periphery of the cylinder body. The permanent magnet and the cylinder body are connected and positioned. One end of the piston is fixed to the housing, and the other end thereof is disposed within an inner hole of the cylinder body. A fluid hole is disposed on the piston. A first unidirectional valve and a second unidirectional valve are relatively disposed in the fluid hole or in the inner cavity of the cylinder body, thereby constructing three opposite and independent cavities in sequence, namely a low-pressure cavity, a variable-capacity operating cavity and a high-pressure cavity. The low-pressure cavity is communicated with an inlet pipe. The high-pressure cavity is communicated with an outlet pipe. However, since the electromagnetic coil is disposed inside the housing, the structure is unreasonable, which incurs an inconvenient installation. Furthermore, the electromagnetic coil and the permanent magnet are all set in the low-pressure cavity, so the sealing treatment to the electromagnetic coil and the permanent magnet is necessary, which incurs a complexity of the manufacture, high costs and hard promotions. -
KR 2010 0062665 A claim 1. -
US 2002/0146334 A1 discloses a linear engine, comprising a tubular housing, axially spaced electromagnetic coils disposed around the tubular housing, a piston disposed within the tubular housing, the piston including magnetic elements, and a drive circuit electrically connected to the first and second electromagnetic coils for sequentially energizing the first and second electromagnetic coils to reciprocate the piston within the tubular housing. A magnetic sleeve is disposed within each coil, with the piston being arranged to pass through the magnetic sleeves during operation and the magnetic sleeves being separated by non magnetic material. The magnetic sleeves each form part of the tubular housing. Sealed bearings at each end of the piston define a sump for retaining lubricating oil within a reduced diameter portion of the piston. The sealed bearings each comprise axially spaced circumferentially extending ribs, adjacent ribs being separated by a gap for receiving a sealing element. - The object of the present invention is to overcome the aforementioned problems and to provide a permanent magnet linear piston pump having a simple structure, more convenient manufacture and lower costs.
- The permanent magnet linear piston pump in accordance with the present invention is as defined in
claim 1 and comprises a piston body, a cylinder body, a permanent magnet assembly and an electromagnetic coil. The cylinder body is in a shape of a polygonal prism, an interior of which arranges a piston cavity formed by an axial columnar accommodating cavity. The piston body is arranged in the piston cavity by a liquid sealing movable fit mode. A one-way inlet valve and a one-way outlet valve are disposed on an end face of the piston cavity opposite to an end face of a piston. A set of permanent magnet assembly is disposed on at least one side surface of the cylinder body. The permanent magnet assembly includes an inner mounting plate and an outer mounting plate disposed parallel to the side surface of the cylinder body. The inner plate and the outer mounting plate are made of a permeability magnetic material. An inner magnetic body and an outer magnetic body are respectively disposed on opposite surfaces of the inner mounting plate and the outer mounting plate. The inner magnetic body and the outer magnetic body are disposed oppositely and provide contrary magnetic poles at opposite faces thereof. A coil supporting member is disposed at an outside surface of the cylinder body. The electromagnetic coil is axially and distributively wound around the coil supporting member into a barrel shape. A barrel wall formed by the electromagnetic coil is disposed between the inner magnetic body and the outer magnetic body. An axial sliding slot is formed on the side surface of the cylinder body where the permanent magnet assembly is disposed. A connecting post is disposed on a side surface of the piston body in a radial direction to fit in with the sliding slot by a clearance fit mode. The connecting post penetrates through the sliding slot to be in connection with and in linkage with the inner mounting plate and the outer mounting plate. - By comparison with the prior technique, the present invention has the electromagnetic coil which is axially and distributively wound around the coil supporting member at the outside surface of the cylinder body and needs not subject the electromagnetic coil to a sealing treatment, which attains a simple structure, more convenient manufacture, lower costs, a reliable operation and convenient maintenance.
- Preferably, two parts of the columnar accommodating cavity in the cylinder body are disposed symmetrically. The piston body is disposed at a middle portion of the columnar accommodating cavity. Two ends of the piston body are in cooperation with the two parts of the columnar accommodating cavity by the liquid sealing movable fit mode respectively, whereby the two parts of the columnar accommodating cavity are respectively defined as a first piston cavity and a second piston cavity, and the two ends of the piston body are respectively defined as a first piston body and a second piston body. A first one-way inlet valve and a first one-way outlet valve are disposed on an end face of the first piston cavity opposite to an end face of the first piston body. A second one-way inlet valve and a second one-way outlet valve are disposed on an end face of the second piston cavity opposite to an end face of the second piston body. A first inner magnetic body and a second inner magnetic body are respectively and symmetrically disposed at two ends of the inner mounting plate. A first outer magnetic body and a second outer magnetic body are respectively and symmetrically disposed at two ends of the outer mounting plate. A first electromagnetic coil and a second electromagnetic coil are respectively and correspondingly disposed on ribs at two sides of the cylinder body. Accordingly, the same cylinder body forms two permanent magnet linear piston pumps, and the piston body can be in the operating status during the reciprocating motion to attain the higher efficiency.
- Preferably, one set of permanent magnet assembly is arranged at each side surface of the cylinder body, which allows the permanent magnet linear piston pump to have a greater power.
- Preferably, the cylinder body includes a barrel unit and lids at two ends thereof. Sealing rings are respectively disposed between the lids at the two ends and two end faces of the barrel unit. The barrel unit and the lids at the two ends are connected with each other by a plurality of axial shanks and nuts around an outer periphery of the barrel unit. The shanks construct the coil supporting member. Accordingly, such arrangement designing the cylinder body and the coil supporting member attains a simple structure, a simple manufacturing technique and lower costs.
- Preferably, ribs are disposed on edges of the cylinder body. The ribs construct the coil supporting member. The inner mounting plate and the inner magnetic body are disposed in a recess between the ribs at two sides of a same side surface of the cylinder body. Accordingly, such arrangement designing the cylinder body and the coil supporting member attains a simple structure, a simple manufacturing technique, a firm structure and high mechanical intensity.
- Preferably, the cylinder body can be a prism having four to six sides, especially a quadrangular prism whose cross-section is in a rectangular shape, whereby the cylinder body in this shape is easier to be processed.
- Preferably, the inner mounting plate and the outer mounting plate are made of a permeability magnetic material. A magnetizing coil is sleeved on the inner mounting plate or/and the outer mounting plate. A magnetic field line created by the magnetizing coil is formed in a closed annular shape along the inner mounting plate, the inner magnetic body, the outer magnetic body and the outer mounting plate. Accordingly, the magnetizing coil is sleeved on the inner mounting or/and the outer mounting plate, so an external magnetizing power supply in connection with the magnetizing coil magnetizes the inner magnetic body and the outer magnetic body to retrieve their intensity of magnetism when the intensity of magnetism of two magnetic bodies becomes lessened due to a long term of using the permanent magnet linear piston pump, thereby prolonging the duration of the permanent magnet linear piston pump.
- The present invention is further described upon reading following preferred embodiments in conjunction with the accompanying drawings.
-
- Fig. 1
- is a perspective view showing a first preferred embodiment of the present invention;
- Fig. 2
- is a cross-sectional view showing the interior of the first preferred embodiment of the present invention;
- Fig. 3
- is a perspective view showing the piston body of the first preferred embodiment of the present invention;
- Fig. 4
- is a perspective view showing the cylinder body of the first preferred embodiment of the present invention;
- Fig. 5
- is a perspective view showing a second preferred embodiment of the present invention;
- Fig. 6
- is an exploded view showing a part of the second preferred embodiment of the present invention;
- Fig. 7
- is a cross-sectional view showing the interior of the second preferred embodiment of the present invention;
- Fig. 8
- is an enlarged view showing the "I" part of
Fig. 7 ; - Fig. 9
- is an enlarged view showing the "II" part of
Fig. 7 ; - Fig. 10
- is a schematic view showing the piston body in combination with the cylinder body of the second preferred embodiment;
- Fig. 11
- is a perspective view showing the cylinder body of the second preferred embodiment;
- Fig. 12
- is a perspective view showing a third preferred embodiment;
- Fig. 13
- is an exploded view showing a part of the third preferred embodiment;
- Fig. 14
- is a cross-sectional view showing the interior of the third preferred embodiment;
- Fig. 15
- is an enlarged view showing the "III" part of
Fig. 14 ; and - Fig. 16
- is an enlarged view showing the "IV" part of
Fig. 14 . - Referring to
Fig. 1 andFig. 2 , a permanent magnetlinear piston pump 3 of the present invention comprises apiston body 1, acylinder body 2, apermanent magnet assembly 6 and anelectromagnetic coil 3. The cylinder body is in a shape of a polygonal prism, such as in a prism with four to six sides. Preferably, a quadrangular prism is adopted. As shown inFig. 4 , this preferred embodiment has aquadrangular cylinder body 2 whose cross-section is shaped by a rectangular contour. An interior of thecylinder 2 arranges apiston cavity 201 formed by an axial columnar accommodating cavity. Thepiston body 1 is arranged in thepiston cavity 201 by a liquid sealing movable fit mode. A cross-section of one end of thepiston body 1 can be the same as the cross-section of thepiston cavity 201. This end is inserted into thepiston cavity 201 by the liquid sealing movable fit mode. In this preferred embodiment, as shown inFig. 2 andFig. 3 , thepiston body 1 is a prism whose cross-section is the same as the cross-section of thepiston cavity 201. The end of thepiston body 1 is inserted into thepiston cavity 201 by the liquid sealing movable fit mode; preferably, the other end thereof can arrange a supporting structure having an orientation effect. A one-way inlet valve 4 and a one-way outlet valve 5 are disposed on an end face of thepiston cavity 201 opposite to an end face of a piston. A set ofpermanent magnet assembly 6 is disposed on at least one side surface of thecylinder body 2. Thepermanent magnet assembly 6 includes aninner mounting plate 601 and anouter mounting plate 602 disposed parallel to the side surface of thecylinder body 2. An innermagnetic body 603 and an outermagnetic body 604 are respectively disposed on opposite surfaces of theinner mounting plate 601 and the outer mountingplate 602, whereby the permanent magnet linear piston pump has a greater power. One set of thepermanent magnet assembly 6 is disposed on every side surface of thecylinder body 2. A coil supporting member is disposed at an outside surface of thecylinder body 2. The arrangement of the coil supporting member is to space theelectromagnetic coil 3 and the outside surface of the cylinder body apart by a distance in order that theinner mounting plate 601 and the innermagnetic body 603 can be placed in this space. Theelectromagnetic coil 3 is axially and distributively wound around the coil supporting member into a barrel shape. Herein, thecylinder body 2 can include a barrel unit and lids at two ends thereof. Sealing rings are respectively disposed between the lids at the two ends and two end faces of the barrel unit. The barrel unit and the lids at the two ends are connected with each other by a plurality of axial shanks and nuts around an outer periphery of the barrel unit. The shanks are located at every edge of thecylinder body 2. The shanks construct the coil supporting member. Thecylinder body 2 and the coil supporting member of this arrangement are simple in structure and easier to manufacture and have lower costs although the mechanical intensity may be relatively lower. As shown inFig. 4 , in this preferred embodiment,ribs 202 are disposed on every edge of thecylinder body 2. Theribs 202 construct the coil supporting member. Theribs 202 can be extended throughout the full edge or extended to the part of the two ends where theelectromagnetic coil 3 is wound. Theribs 202 are disposed to allow the surface of thecylinder body 2 to have a sufficient space where theinner mounting plate 601 and the innermagnetic body 603 are placed. Theinner mounting plate 601 and the innermagnetic body 603 are disposed in a recess between theribs 202 at two sides of a same side surface of thecylinder body 2. The innermagnetic body 603 and the outermagnetic body 604 are disposed oppositely and provide contrary magnetic poles at opposite faces thereof. An interstice is formed between the innermagnetic body 603 and the outermagnetic body 604. The interstice can be lessened possibly to satisfy the coiling of theelectromagnetic coil 3. Theelectromagnetic coil 3 is axially and distributively wound around theribs 202 of every edge into a barrel type. Alternatively, it can be wound around theribs 202 on which a pad or a bracket is disposed in advance. Theelectromagnetic coil 3 is disposed between the innermagnetic body 603 and the outermagnetic body 604. The side surface of thecylinder body 2 where thepermanent magnet assembly 6 is disposed forms an axial slidingslot 203. A length of the slidingslot 203 is equal to a designed stroke length of thepiston body 1. A connectingpost 101 is disposed on a side surface of thepiston body 1 in a radial direction to fit in with the slidingslot 203 by a clearance fit mode. The connectingpost 101 penetrates through the slidingslot 203 to be connected to theinner mounting plate 601 and the outer mountingplate 602, thereby forming a linkage. In this preferred embodiment, through holes are respectively formed on theinner mounting plate 601 and the outer mountingplate 602 to fit in with the connectingpost 101 by a clearance fit mode. The connectingpost 101 penetrates through the slidingslot 203 and the through holes of theinner mounting plate 601 and the outer mountingplate 602 to be in connection with and in linkage with theinner mounting plate 601 and the outer mountingplate 602. - To attain the higher efficiency of the permanent magnet linear piston pump, the
piston body 1 is in the operating state during the reciprocating motion. In the present invention, two permanent magnet linear piston pumps are formed in thesame cylinder body 2. Referring toFigs. 5-7 , two parts of the columnar accommodating cavity in thecylinder body 2 are disposed symmetrically. Thepiston body 1 is a prism whose cross-section is the same as the cross-section of thepiston cavity 201. Thepiston body 1 is disposed at a middle portion of the columnar accommodating cavity. Two ends of thepiston body 1 are in cooperation with the two parts of the columnar accommodating cavity by the liquid sealing movable fit mode respectively, whereby the two parts of the columnar accommodating cavity are respectively defined as afirst piston cavity 2011 and asecond piston cavity 2012, and the two ends of thepiston body 1 are respectively defined as a first piston body 1a and asecond piston body 1b. A first one-way inlet valve 4a and a first one-way outlet valve 5a are disposed on an end face of thefirst piston cavity 2011 opposite to an end face of the first piston body 1a. A second one-way inlet valve 4b and a second one-way outlet valve 5b are disposed on an end face of thesecond piston cavity 2012 opposite to an end face of thesecond piston body 1b. Likewise, thepermanent magnet assembly 6, as shown inFigs. 7-9 , includes aninner mounting plate 601 and anouter mounting plate 602 disposed parallel to the side surface of thecylinder body 2. A first innermagnetic body 603a and a second innermagnetic body 603b are respectively and symmetrically disposed at two opposite end faces of theinner mounting plate 601. A first outermagnetic body 604a and a second outermagnetic body 604b are respectively and symmetrically disposed at two ends of the outer mountingplate 602. A first electromagnetic coil 3a and a second electromagnetic coil 3b are respectively and correspondingly disposed onribs 202 at two sides of thecylinder body 2. Likewise, theinner mounting plate 601 and the innermagnetic body 603 are disposed in a recess between theribs 202 at two sides of the same side surface of thecylinder body 2. The first innermagnetic body 603a and the first outermagnetic body 604a at the two ends are disposed oppositely and provide contrary magnetic poles at opposite faces thereof. The second innermagnetic body 603b and the second outermagnetic body 604b at the two ends are disposed oppositely and provide contrary magnetic poles at opposite faces thereof. Interstices are respectively formed between the first innermagnetic body 603a and the first outermagnetic body 604a and between the second innermagnetic body 603b and the second outermagnetic body 604b. The interstice can be lessened possibly to satisfy the coiling of theelectromagnetic coil 3. Theelectromagnetic coil 3 is axially and distributively wound around theribs 202 of every edge of the two ends of thecylinder body 2 into a barrel type. Alternatively, it can be wound around theribs 202 on which a pad or a bracket is disposed in advance. Theelectromagnetic coils 3 are respectively disposed between the first innermagnetic body 603a and the first outermagnetic body 604a and between the second innermagnetic body 603b and the second outermagnetic body 604b. The side surface of thecylinder body 2 where thepermanent magnet assembly 6 is disposed forms an axial slidingslot 203. In this preferred embodiment, fourpermanent magnet assemblies 6 are respectively set on four side surfaces of thecylinder body 2, with four slidingslots 203 formed on the four side surfaces of thecylinder body 2 respectively. A length of the slidingslot 203 is equal to a designed stroke length of thepiston body 1. Four connectingposts 101 are respectively disposed on four sides of thepiston body 1 in a radial direction to fit in with the slidingslots 203 by a clearance fit mode. The connectingposts 101 penetrate through the slidingslots 203 to be connected to theinner mounting plate 601 and the outer mountingplate 602, thereby forming a linkage. Referring toFigs. 5-6 , this preferred embodiment forms through holes which are respectively formed on theinner mounting plate 601 and the outer mountingplate 602 to fit in with the connectingpost 101 by a clearance fit mode. The connectingposts 101 penetrate through the slidingslots 203 and the through holes of theinner mounting plate 601 and the outer mountingplate 602 to be in connection with and in linkage with theinner mounting plate 601 and the outer mountingplate 602. - To retrieve the intensity of magnetism of the inner
magnetic body 603 and the outermagnetic body 604 by magnetizing and to prolong the duration of the permanent magnet linear piston pump, the permanent magnet linear piston pump of the present invention can be magnetized. Referring toFigs. 12-16 , the remaining structure of the magnetizing permanent magnet linear piston pump is the same as the first and the second preferred embodiments. Differently, theinner mounting plate 601 and the outer mountingplate 602 are made of a permeability magnetic material. A magnetizingcoil 7 is sleeved on theinner mounting plate 601 or the outer mountingplate 602. To enhance the intensity of the recharging magnetic field, the magnetizingcoil 7 of this embodiment is sleeved on theinner mounting plate 601 and the outer mountingplate 602. The magnetizingcoil 7 can be wound around acoil frame 8 of a "" shape at first. Then, theinner mounting plate 601 or the outer mountingplate 602 can penetrate through the center of thecoil frame 8. Thecoil frame 8 is fixed onto thecylinder body 2. A magnetic field line created by the magnetizingcoil 7 is formed in a closed annular shape along theinner mounting plate 601, the innermagnetic body 603, the outermagnetic body 604 and the outer mountingplate 602. - From the above preferred embodiments, the one-
way inlet valve 4 and the one-way outlet valve 5 can be designed by using a diaphragm structure or by disposing a steel ball and a compression spring in the valve cavity. These arrangements can all satisfy the requirements.
Claims (8)
- A permanent magnet linear piston pump comprising a piston body (1), a cylinder body (2), a permanent magnet assembly (6) and an electromagnetic coil (3);wherein a piston cavity (201) is formed in said cylinder body (2) by an axial columnar accommodating cavity, said piston body (1) being disposed in said piston cavity (201) by a liquid sealing movable fit mode, a one-way inlet valve (4) and a one-way outlet valve (5) being disposed on an end face of said piston cavity (201) opposite to an end face of a piston, a coil supporting member being disposed at an outside surface of said cylinder body (2), said electromagnetic coil (3) being axially and distributively wound around said coil supporting member into a barrel shape, an axial sliding slot (203) being formed on said side surface of said cylinder body (2) where said permanent magnet assembly (6) is disposed, a connecting post (101) being radially disposed on a side surface of said piston body (1) to fit in with said sliding slot (203) by a clearance fit mode, said connecting post (101) penetrating through said sliding slot (203),characterized in that the permanent magnet assembly (6) is disposed on at least one side surface of said cylinder body (2), said permanent magnet assembly (6) including an inner mounting plate (601) and an outer mounting plate (602) disposed parallel to said side surface of said cylinder body (2), said inner mounting plate (601) and said outer mounting plate (602) being made of a permeability magnetic material, an inner magnetic body (603) and an outer magnetic body (604) being respectively disposed on opposite surfaces of said inner mounting plate (601) and said outer mounting plate (602), said inner magnetic body (603) and said outer magnetic body (604) being disposed oppositely and providing contrary magnetic poles at opposite faces thereof, , a barrel wall formed by said electromagnetic coil (3) being disposed between said inner magnetic body (603) and said outer magnetic body (604), said connecting post (101) is in connection with and in linkage with said inner mounting plate (601) and said outer mounting plate (602).
- The permanent magnet linear piston pump according to claim 1, wherein two parts of said columnar accommodating cavity in said cylinder body (2) are disposed symmetrically, said piston body (1) being disposed at a middle portion of said columnar accommodating cavity, two ends of said piston body (1) being in cooperation with said two parts of said columnar accommodating cavity by said liquid sealing movable fit mode respectively, whereby said two parts of said columnar accommodating cavity are respectively defined as a first piston cavity (2011) and a second piston cavity (2012) and said two ends of said piston body are respectively defined as a first piston body (1a) and a second piston body (1b), a first one-way inlet valve (4a) and a first one-way outlet valve (5a) being disposed on an end face of said first piston cavity (2011) opposite to an end face of said first piston body (1a), a second one-way inlet valve (4b) and a second one-way outlet valve (5b) being disposed on an end face of said second piston cavity (2012) opposite to an end face of said second piston body (1b), a first inner magnetic body (603a) and a second inner magnetic body (603b) being respectively and symmetrically disposed at two ends of said inner mounting plate (601), a first outer magnetic body (604a) and a second outer magnetic body (604b) being respectively and symmetrically disposed at two ends of said outer mounting plate (602), a first electromagnetic coil (3a) and a second electromagnetic coil (3b) being respectively and correspondingly disposed on ribs (202) at two sides of said cylinder body (2).
- The permanent magnet linear piston pump according to claim 1, wherein one set of permanent magnet assembly (6) is arranged at each side surface of said cylinder body (2).
- The permanent magnet linear piston pump according to claim 1, wherein ribs (202) are disposed on edges of said cylinder body (2), said ribs (202) constructing said coil supporting member, said inner mounting plate (601) and said inner magnetic body (603) being disposed in a recess between said ribs (202) at two sides of a same side surface of said cylinder body (2).
- The permanent magnet linear piston pump according to claim 1, wherein said cylinder body (2) includes a barrel unit and lids at two ends thereof, sealing rings being respectively disposed between said lids at said two ends and two end faces of said barrel unit, said barrel unit and said lids at said two ends being connected with each other by a plurality of axial shanks and nuts around an outer periphery of said barrel unit, said shanks constructing said coil supporting member.
- The permanent magnet linear piston pump according to claim 1, wherein said cylinder body (2) is a prism having four to six sides.
- The permanent magnet linear piston pump according to claim 1, wherein said cylinder body (2) is a quadrangular prism, a cross-section of which is in a rectangular shape.
- The permanent magnet linear piston pump according to claim 1, wherein said inner mounting plate (601) and said outer mounting plate (602) are made of a permeability magnetic material, a magnetizing coil (7) being sleeved on said inner mounting plate (601) or/and said outer mounting plate (602), a magnetic field line created by said magnetizing coil (7) being formed in a closed annular shape along said inner mounting plate (601), said inner magnetic body (603), said outer magnetic body (604) and said outer mounting plate (602).
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201220368590XU CN202789501U (en) | 2012-07-27 | 2012-07-27 | Permanent magnet linear piston pump |
PCT/CN2012/082961 WO2014015566A1 (en) | 2012-07-27 | 2012-10-15 | Permanent magnet linear piston pump |
Publications (3)
Publication Number | Publication Date |
---|---|
EP2878818A1 EP2878818A1 (en) | 2015-06-03 |
EP2878818A4 EP2878818A4 (en) | 2016-05-11 |
EP2878818B1 true EP2878818B1 (en) | 2017-08-16 |
Family
ID=47816772
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP12881862.2A Active EP2878818B1 (en) | 2012-07-27 | 2012-10-15 | Permanent magnet linear piston pump |
Country Status (5)
Country | Link |
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US (1) | US20150125321A1 (en) |
EP (1) | EP2878818B1 (en) |
CN (1) | CN202789501U (en) |
ES (1) | ES2644928T3 (en) |
WO (1) | WO2014015566A1 (en) |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102748277B (en) * | 2012-07-27 | 2015-04-15 | 徐荣兰 | Permanent magnet linear piston pump |
Family Cites Families (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4375941A (en) * | 1978-03-20 | 1983-03-08 | Child Frank W | Method and apparatus for pumping blood |
DE2903817A1 (en) * | 1979-02-01 | 1980-08-07 | Siegfried Dr Ing Kofink | Electromagnetic pump for fluids - has pumping piston fixed to magnetic armature driven by linear motor outside paramagnetic casing of pump |
US4541787A (en) * | 1982-02-22 | 1985-09-17 | Energy 76, Inc. | Electromagnetic reciprocating pump and motor means |
CN2048903U (en) * | 1989-06-28 | 1989-12-06 | 孔昭琛 | Electricity controlling magnetic pump |
US6068588A (en) * | 1999-01-07 | 2000-05-30 | International Business Machines Corporation | Counterbalanced pump |
US6468057B1 (en) * | 1999-09-13 | 2002-10-22 | Douglas S. Beck | Free piston pump |
US6290640B1 (en) * | 1999-11-02 | 2001-09-18 | International Business Machines Corporation | Uncoupled rotary linear pump |
CA2335899A1 (en) * | 2001-01-26 | 2002-07-26 | Mohammed Mali | Integrated linear motor-driven compressor with lubricant sump |
CN1554868A (en) * | 2003-12-23 | 2004-12-15 | 俞国淼 | Magnetic linear piston pump |
US7721685B2 (en) * | 2006-07-07 | 2010-05-25 | Jeffrey Page | Rotary cylindrical power device |
CN101240793B (en) * | 2008-03-14 | 2011-04-27 | 刘新春 | Linear motor double cylinder compression pump |
KR20100062665A (en) * | 2008-12-02 | 2010-06-10 | 엘지전자 주식회사 | Refrigerator |
CN102748277B (en) * | 2012-07-27 | 2015-04-15 | 徐荣兰 | Permanent magnet linear piston pump |
-
2012
- 2012-07-27 CN CN201220368590XU patent/CN202789501U/en not_active Expired - Lifetime
- 2012-10-15 EP EP12881862.2A patent/EP2878818B1/en active Active
- 2012-10-15 ES ES12881862.2T patent/ES2644928T3/en active Active
- 2012-10-15 WO PCT/CN2012/082961 patent/WO2014015566A1/en active Application Filing
- 2012-10-15 US US14/389,651 patent/US20150125321A1/en not_active Abandoned
Non-Patent Citations (1)
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None * |
Also Published As
Publication number | Publication date |
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EP2878818A4 (en) | 2016-05-11 |
ES2644928T3 (en) | 2017-12-01 |
US20150125321A1 (en) | 2015-05-07 |
EP2878818A1 (en) | 2015-06-03 |
CN202789501U (en) | 2013-03-13 |
WO2014015566A1 (en) | 2014-01-30 |
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