DE2409659A1 - ELECTROMAGNETIC DRIVEN SELF-PRIMING PUMP - Google Patents

Description

LM 2785

O ¹ DeIl Manufacturing, Inc. Saginaw, Michigan / USA

Electromagnetically driven, self-priming pump

The invention relates to an electromagnetically driven automatically aspirating fluid pump with two reciprocating pump piston which, when subjected to a magnetic field, magnetized and are moved towards each _t, and which are moved apart by a resilient means in response to movement of the pistons against each other Stores energy.

The invention provides an electromagnetically driven, self-priming pump with two magnetizable Liquid pumping pistons created which, depending on a magnetic field to which they are exposed, are moved against each other.

Furthermore, the invention provides an electromagnetically driven, self-priming pump with two axially aligned pump plunger created alternately in

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opposite directions are magnetized, so that each time they are magnetized, they are against each other ' be attracted.

In addition, the invention provides an automatically priming, Electromagnetically driven fluid pump created that has an axial pump cylinder an inlet and an outlet, two axially aligned pump pistons which are axially opposed to each other in the cylinder and movable away from each other to move fluid downstream from the inlet to the outlet, each the piston has a magnetizable portion, and has a circumferential sealing flange that seals the cylinder wall when the piston is moved downstream, however is moved radially to pass the fluid as the piston is moved upstream.

The invention also creates an automatically priming, electromagnetically driven pump, the two aligned pump pistons with magnetizable. Sections, a magnetic field generating coil, driven by an electrical AC power source is energized to alternate the magnetizable sections at opposite half-periods to magnetize the alternating current in opposite directions, and has an elastic device, which is responsive to movement of the sections in opposite directions to move them in an opposite direction to move so that the pumping frequency is twice the AC frequency.

An electromagnetically driven liquid pump according to the invention can thus consist of a pump cylinder with a liquid channel which has a liquid inlet and having a liquid outlet, two on a magnetic field appealing liquid pump parts, which are in the channel

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are movable between distant positions and near positions to pump liquid from inlet to outlet, one electromagnetic coil for generating a magnetic flux alternately increasing and decreasing density in the channel to bring the liquid pump parts to one of the distant and close positions when the flux density increases, and to bring the movement of the piston parts to the other of the near and far positions when the flux density decreases, and an energy-storing elastic device that acts on the movement of the liquid pump parts in one of the near and distant positions responds to the piston parts in the other of the near and distant To move positions when the magnetic flux density decreases.

The invention is explained below with reference to FIGS. 1 to 6 for example described. It shows:

Figure 1 is a vertical section of an electromagnetic driven liquid pump according to the invention along the line 1-1 in Fig. 2,

Figure 2 is a cross-section of the pump along line 2-2 in Fig. 1, and

Figure 3 to 6 vertical sections from which various Positions of the two fluid pump pistons emerge during a pumping cycle.

A self-priming electromagnetic pump according to the invention is indicated generally at 10 and has an annular, generally rectangular magnetic core 12, the two upper and lower legs 14 and 16 and end legs 18 and 20 which form a continuous, closed path for magnetic flux. The iron core 12 can expediently consist of several stacked layers of magnetizable material, to decrease the hysteresis loss.

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Two openings 22 are in the upper and lower magnetic core legs 14 and 16 are provided to receive a vertical pump cylinder 24 having a liquid channel 26 which has a lower inlet end 28 immersed in water or other fluid to be pumped dips, as well as an outlet upper end 30. The cylinder 24 is made of a non-magnetic material such as glass.

An upper and a lower pump piston 32 and 34, respectively, are arranged in the liquid channel 26. The pump piston 32 • has a cylindrical, magnetizable core 36, e.g. Iron connected, for example, to a soft lining 38 of elastic material, which is axially in Direction of flow below the flange 40 ends, which normally expands radially outward and lies against the cylinder wall 24 in a sealing manner, but radially is movable inwardly to the position shown in Fig. 5 to allow fluid to pass through. Water W passes axially pressed on the elastic liner 38 in the direction of arrow b (Fig. 5) in a manner described later. When the sealing flange 40 on the cylinder wall 24 engages, the piston 32 moves axially in the direction of arrow j downwards (FIGS. 1 and 6) to the outlet 30.

The resilient liner 38 has an integral end wall 48 with an additional flange 46 on the opposite one or upstream end of the piston 32, which is extends axially downward and normally expands radially outward and engages cylinder wall 24, but is movable radially inward when the piston 32 moves upstream to the position shown in Fig. 1, so that the water W can move between the flange 46 and the wall 24 in the direction of arrow b (FIG. 5). Of the Flange 46 acts in addition to causing a pumping action as it moves downstream towards the outlet

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lasses 30 moved, also for centering the piston 32 in the cylinder 24. The liner end wall 48 acts as an energy retentive, resilient cap that the lower end wall of the upper piston core 36 and which has a protrusion 48a for a purpose to be described.

The lower pump piston 34 has a magnetisxerbaren, elongated central core 50, which with a similar Lining 52 is connected from elastic material. The liner 52 has an integral end portion 54 of the same energy-storing, elastic material which covers the upper or downstream end wall of the piston core 50, and a protrusion 54a for engaging the resilient protrusion 48a of the upper piston when the pistons 32 and 34 are moved against each other in a manner to be described later. When the pistons are pulled against each other are, the elastic end portions 48 and 54 are compressed to store energy and after a predetermined deformation or compression, they move the pistons 32 and 34 apart, as also described later will. The upper resilient portion 54 has an integral, axially downstream flange 56 which is the same as the upper one Piston flange 40 is, and which normally expands radially outward and rests against the cylinder wall, however is deformable or radially inwardly movable to the water W between the flange 40 and the cylinder wall 24 to let through. The elastic liner 52 has a central flange at the axially lower end of the piston 34 58, which extends axially and normally expands radially outward and engages the cylindrical wall 24, to pump the water W upwards in the direction of arrow c (Fig. 1). The flange 58 is in the same way deformable inwards to allow the water W to pass through. A perforated, elastic support disc 60 with openings 61, which allows the upward flow of the water W is arranged in the lower end of the pump channel 26 in order to

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prevent the lower pump piston 34 from passing through the inlet end 28 of cylinder 2 4 drops when the pump is not in operation. The elastic material 48 and 54 may be suitable Way made of natural, vulcanized rubber or silicone rubber. The material can be chosen so that it has a spring constant which gives the optimum pumping force. Silicone rubber sold under the trademark "RTV-108" from General Electric Company, Schenectady, New York, displaced species has been found suitable for this purpose.

An electrically excitable, electromagnetic ring coil 62 surrounds the non-magnetic pump cylinder 24 and the pistons 32 and 34, which together form a central leg for the magnetic core 10. The coil 62 is via leads 64 connected to a source 66 for alternating current with a certain frequency of e.g. 60 Hz in order to produce a Generate alternating magnetic field in the pump channel 26. At the positive half cycle of the current the source 66 follows the magnetic flux generated by the coil 62 follows the path indicated by the arrow d in the direction of the arrows e. at the opposite or negative half cycle of the current from source 66 is followed by the flux generated by coil 62 opposite, dash-dotted path ο in the opposite, indicated by the arrow ρ path.

In operation, the pump inlet end 28 is immersed in the water W and the coil leads 64 are connected to the AC power source 66 connected. It is assumed that the pistons 62 and 64 initially in the dash-dotted lines in the separate positions shown in Fig. 1, and that the coil 62 initially from the positive half cycle of the current is energized so that the flux exiting coil 62 follows path d and energizes piston cores 36 and 50 such that that the lower end of the core 36 has a south pole and the upper end of the core 50 has an opposite pole and one, respectively

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North Pole has. The adjacent ends of the cores are thus attracted and the pistons 32 and 34 move against one another into the position shown in FIG. When the pistons 32 and 34 contact each other, the resilient end portions grip 48 and 54 come together and compress to store energy. When the excitation current is the first Half cycle decreases and the resulting flux decreases after a certain delay, overcomes the stored one Energy in the compressed, elastic material 48 and 54, the magnetic forces that the magnetic cores 36 and 50 tighten, and slide pistons 32 and 34 to the remote positions shown in Figure 4. When this happens, will a partial vacuum in the collapsible chamber 70 (Fig. 4) generated between the pistons 32 and 34. Because the pressure on the axially downstream sides of the lower piston flanges 56 and 58 is less than the pressure on the upstream side of the lower piston flanges the water W moves upward through the openings 61 in the support disk 60 axially past the flanges 56 in the direction of the arrow g in FIG. 4 into the chamber 70.

The electromagnetic coil 62 is then separated from the other Half cycle of the alternating current energized to create the flux on the path ρ and the cores 36 and 50 opposite to magnetize so that the lower end of the upper core 36 is now a north pole and the upper end of the core 50 is now a opposite pole and a south pole, respectively, so that the adjacent ends of cores 36 and 50 are attracted again and pistons 32 and 34 are brought together to the positions shown in FIG. 5 to reduce chamber 70 and fluid in chamber 70 upward past upper piston flanges 46 and 40 in FIG Direction of arrows b and h (Fig. 5) to press. The increasing pressure in the chamber 70 on the downstream Side of the upper piston flanges 46 and 40 is larger than

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the pressure on the upstream side of flanges 46 and 40 to force the fluid through. Of the from the fluid in chamber 70 toward the downstream side of lower piston flanges 46 and 58 The pressure exerted by the arrow i (FIG. 5) moves the flanges 56 and 58 radially outward so that these at sealingly engaging the cylinder 24 and preventing the water W in the chamber 70 from flowing to the inlet 28. The elastic parts 48 and 50 are pressed together again and those in the elastic, energy-storing Parts 48 and 50 of stored energy pushes the pistons into the remote positions shown in FIG. 6, so that the water W pushed back up past the lower piston flanges 56 and 58 in the direction of arrow g is and at the same time the fluid that has been forced out on the upper piston flange 40, in the direction of the arrow j (Fig. 6) to the outlet 30 is moved axially outward. The one from the expelled fluid Pressure exerted on the downstream side of the flanges 40 and 46 in the direction of arrow k pushes the flanges 40 and 46 radially outward, so that these engage sealingly on the wall 24 and the movement of the pushed out Prevent fluid to the inlet. The pistons 32 and 34 are so against each other and 120 times per minute moved away from each other so that the pumping frequency is twice the AC frequency.

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Claims (15)

Expectations Liquid pump driven by an electrical power source, consisting of a pump housing with a non-magnetizable, magnetic flux permeable, itself axially extending liquid channel with an inlet and an outlet, a liquid pumping mechanism with axially separated magnetizable parts which have magnetically opposed portions, wherein at least one of the parts designed for pumping liquid in a reciprocating stroke and for an axial pumping movement in the channel between a remote position in which the magnetizable parts axially apart to form a liquid receiving chamber therebetween for receiving liquid from the inlet, and is arranged in a less distant position in which the magnetizable parts act magnetically on one another, and an arrangement for cyclically moving at least one of the parts relative to the other, characterized in that that the arrangement has a magnetic field generating device (12, 62) which is connected to the source (66) is connected and continuously a magnetic field of predetermined frequency with half-periods of opposite Polarity generated by the opposing sections of the magnetizable parts (32, 34) while opposite Alternately magnetize half-periods so that the parts (32, 34) act magnetically on one another and at least one of the parts (32, 34) in the same direction during each half cycle of the magnetic field is moved. 2. Pump according to claim 1, characterized in that the magnetic field generating device is connected to an alternating current source (66) is connected. 409837/0318 3. Pump according to claim 1 / characterized in that the "'Magnetic field generating device consisting of a coil (62) for magnetizing the opposing sections of the parts (32, 34) so that they have opposite polarity and attract each other. 4. Pump according to claim 1, characterized by a pretensioning device, around one of the magnetizable parts at the end of each half cycle in its starting position bring back, the elastic means (48a, 54a), which as a function of the movement store energy of one part (32, 34) against the other. 5. Pump according to claim 1, characterized in that the magnetizable parts (32, 34) in dem.Kanal (26) axially are arranged in alignment, and that the magnetic field generating device has a coil (62) and a core (12) which magnetize the parts (32, 34) alternately opposite to the polarity of the opposite Reverse sections of the parts (32, 34). 6. Pump according to claim 1, characterized in that the Parts (32, 34) have valve-like formations (56, 58), which the fluid flow from the inlet (28) to the chamber (70) when the one part moves so that the parts come to the remote position, however, the reverse current is prevented when the part moves so that the parts (32, 34) in the less come remote position. 7. Pump according to claim 6, characterized in that circumferential seals (56, 58, 40, 48) are provided on the parts (32, 34) which engage the channel (26) in the radially outer state, and prevent the flow of fluid to the outlet (30), 409837/0318 and in. the radially inner state in which they are from the Channel (26) are removed allowing fluid flow to outlet (30). 8. Pump according to claim 7, characterized in that the seals (56, 58, 40, -48) protrude radially and themselves normally expand axially in a downstream direction. 9. Pump according to claim 8, characterized in that the seals from splashing on elastic sleeves (38) for the parts (32, 34) are made which do not magnetically shield the parts (32, 34). 10. Pump according to claim 9, characterized in that the flanges (56, 58, 40, 48) on the downstream and the upstream end of each part (32, 34) to achieve axial alignment. 11. Pump according to claim 6, characterized in that a deformable, elastic rubber element (48a, 54a) between the parts (32, 34) is provided to restore the remote arrangement of the parts (32, 34). 12. Pump according to claim 1, characterized in that the magnetizable parts (32, 34) consist of movable pistons exist in the channel (26), and that a formation (48a, 54a) is provided to one of the magnetizable parts (32, 34) to move back and to bring both parts (32, 34) into the starting position, which counteracts the two pistons and is arranged between them. " 13. Pump according to claim 6, characterized in that the elastic energy storage device for moving back the parts in the removed position from an elastic projection (48a, 54a) on at least one of the parts (32, 34) exists. 4 09837- / 0.318 - 1 9 - 14. Pump according to claim 13, characterized in that the elastic energy storage device consists of a central protrusion (48a, 54a) on each of the parts that adjoin each other attack and be deformed when the parts (32, 34) are moved against each other, and the parts (32, 34) resiliently move to the distant positions at the end of each half cycle. 15. Pump according to claim 1, characterized by a perforated stop device (60) in the channel (26) which limits axial movement of at least one of the pistons (34) in a direction away from one another. 409837/0318