KR102669790B1 - Axial flux motor assembly with dual pump chamber - Google Patents

Abstract

The present invention has independent pump chambers at both ends of a core housing in which a single stator is built, and is provided with side housings that accommodate independently rotatable impellers, and each pump chamber is completely statorized by a support housing between the side housing and the core housing. About an axial magnetic flux motor assembly with a dual pump chamber, which has an airtight and watertight isolated structure and enables cost reduction through miniaturization, weight reduction, and component minimization by applying two water pumps to a single core housing. will be.

Description

Axial flux motor assembly with dual pump chamber {AXIAL FLUX MOTOR ASSEMBLY WITH DUAL PUMP CHAMBER}

The present invention relates to an axial magnetic flux motor assembly with a dual pump chamber, and more specifically, to achieve cost reduction through miniaturization, weight reduction, and component minimization by applying two water pumps to a single core housing. It relates to an axial flux motor assembly with a dual pump chamber.

An axial type motor includes a stator that forms a magnetic field and a rotor that can rotate with respect to the stator.

The stator includes a plurality of cores that are arranged at regular intervals along the circumferential direction and protrude at a certain height in the axial direction, and the cores are coupled in the axial direction to grooves formed in the stator body.

The rotor includes permanent magnets arranged at regular intervals along the circumferential direction, and rotates while forming a constant gap with the stator.

A planar motor generates rotational torque by changing the direction of the current flowing in the windings, creating a repulsive or attractive force between the core and the permanent magnet of the rotor.

Publication Patent No. 10-2015-0080843 discloses an “axial spoke type electric motor” (hereinafter referred to as prior art) that can increase power density by arranging a rotor core and a permanent magnet on the rotor and concentrating magnetic flux. there is.

However, in the prior art, manufacturing was difficult because each rotor core sandwiching a permanent magnet had to be manufactured in an arc shape, and assembly was difficult because a plurality of adjacent electrical steel plates were not fixed.

Accordingly, the contact surface with the permanent magnet is uneven, making assembly difficult, and there is a problem of deteriorating the performance of the manufactured electric motor.

Meanwhile, an axial flux motor (AFM) also reduces magnetic flux loss by placing magnets on both sides of the stator instead of only on one side.

The average efficiency of existing radial electric motors is less than 90%, but the average efficiency of AFM is expected to be around 91-96%.

However, although AFM has excellent performance, it faces many difficulties in development.

First of all, AFM may have lower strength because it does not have a stator yoke.

Therefore, it is necessary to design a stator with high strength that can firmly secure the stator.

Additionally, AFM has difficulty dissipating heat because the stator winding is surrounded by the rotor magnet.

Therefore, AFM must pay great attention to cooling design that can dissipate heat well.

Public Patent No. 10-2015-0080843

The present invention was invented to improve the above problems, and is an axis with a dual pump chamber that enables cost reduction through miniaturization, weight reduction, and component minimization by applying two water pumps to a single core housing. It is intended to provide a directional flux motor assembly.

In order to achieve the above object, the present invention includes a cylindrical yoke penetrating at both ends, a first coil wound in a first hook groove formed radially along one end surface of the yoke and an outer peripheral surface of one end of the yoke; , a core housing penetrating both ends in which a single stator including a second coil wound in a second hook groove formed radially along the other end surface of the yoke and the outer peripheral surface of the other end of the yoke is built into; A first side housing mounted on one end of the core housing and having a first pump chamber inside which a first impeller rotating by electromotive force induced with the stator is installed, and a first side housing mounted on the other end of the core housing and inside the A side unit including a second side housing having a second pump chamber in which a second impeller rotating by induced electromotive force with the stator is installed; and a first support housing that finishes the open side of the first side housing facing the open end side of the core housing and is mounted on the core housing to form the first pump chamber, and The first shaft supported by the support housing and mounted on the first impeller, and the open side of the second side housing facing the open other end surface of the core housing are closed and are mounted on the core housing to form the second side housing. Two axial pump chambers including a support isolation unit including a second support housing forming a pump chamber and a first shaft supported on the second support housing and mounted on a second impeller. We will be able to provide a flux motor assembly.

Here, the first shaft and the second shaft are disposed in a straight line with an imaginary line passing through both end surfaces of the yoke.

At this time, the rotation speed and output of the first impeller and the second impeller are controlled simultaneously or separately by a single controller provided on one side of the core housing, and the rotation speed of the first impeller and the second impeller are The outputs are the same or different, the area of the first hanging groove and the area of the second hanging groove are the same or different, and the number of turns of the first coil and the number of turns of the second coil are the same or different from each other. Do it as

In addition, the side unit is provided in the first side housing and communicates with the first pump chamber, and is disposed in a straight line with an imaginary line passing through both end surfaces of the first shaft, the second shaft, and the yoke. 1 pipe, a first port provided at the end of the first pipe, and a transport path for fluid provided in the first side housing and in communication with the first pump chamber, and discharged or introduced by the first impeller A second pipe providing a second port, a second port provided at the distal end of the second pipe, and a second port provided in the second side housing to communicate with the second pump chamber and simultaneously communicate with the second shaft, the first shaft, and the second pipe. A third pipe disposed in a straight line with an imaginary line passing through both end surfaces of the yoke, a third port provided at the distal end of the third pipe, and a third port provided in the second side housing and communicating with the second pump chamber. , characterized in that it further includes a fourth pipe providing a transfer path for fluid discharged or introduced by the second impeller, and a fourth port provided at the distal end of the fourth pipe.

In addition, the support isolation unit includes a first support groove recessed from the first support housing toward one end of the yoke, facing the open side of the first side housing, and the first support groove of the first support groove. A first bearing groove that is stepped in the center and recessed toward one end of the yoke and inserted into a core hole penetrating from one end of the yoke to the center of the other end of the yoke, and an open edge of one side of the first side housing. A first support flange formed along the edge of the first support groove is fixed to the first side flange formed along the open end edge of the core housing while abutting with the first side flange formed along the edge of the core housing. , a second support groove recessed from the second support housing toward the other end surface of the yoke, facing the open side of the second side housing, and a step of the yoke at the center of the second support groove. A second bearing groove that is recessed toward the other end surface and inserted into a core hole penetrating from the other end surface of the yoke to the center of one end surface, and a second side flange formed along the edge of one open side of the second side housing. It is in contact with and fixed to a second core flange formed along an edge of the open other end of the core housing, and further includes a second support flange formed along an edge of the second support groove, wherein the first The pump chamber is formed by the open side of the first side housing and the first support groove, and the second pump chamber is formed by the open side of the second side housing and the second support groove. , the first shaft is seated in the first support groove and supported for rotation, and the second shaft is seated in the second support groove and supported for rotation.

According to the present invention configured as described above, the following effects can be achieved.

First, the present invention has independent pump chambers at both ends of a core housing in which a single stator is built, and is provided with side housings that accommodate independently rotatable impellers, and each pump chamber is supported by a support housing between the side housing and the core housing. With a completely airtight and watertight isolated structure, two water pumps, i.e. impellers, are applied to a single core housing, so it will be able to achieve cost savings through miniaturization, weight reduction, and component minimization.

In addition, compared to the conventional radial flux motor, which requires installing magnetic flux motors corresponding to the number of pumps one by one in places where multiple pumps are needed in electric vehicles or environments where various pumps are needed, the axial magnetic flux according to the present invention In the case of motor assemblies, it will be possible to implement a pump system with high output and efficiency by efficiently using installation area and space in an environment that requires multiple pumps.

In addition, according to the present invention, there is a special advantage that two types of pumps can be connected to one core housing by controlling the rotation speed of the first impeller and the second impeller simultaneously or individually with a single controller.

In particular, according to the present invention, it is very useful in that even in an emergency situation where either the first impeller or the second impeller is inoperable, response to the emergency situation and recovery work can be performed while operating the other impeller.

In addition, according to the present invention, in some cases, the number of turns of the first coil and the second coil, the number of poles and magnetic force of the first permanent magnet assembly of the first impeller, and the number of poles and magnetic force of the second permanent magnet assembly of the second impeller are different from each other. By manufacturing it, it is a very useful invention in that it is possible to implement two motors or pump systems with different performances with a single stator.

Figure 1 shows the overall structure of an axial magnetic flux motor assembly with a dual pump chamber according to an embodiment of the present invention. Figure 1(a) is a perspective conceptual diagram showing the exterior, and Figure 1(b) is an internal view. Cross-sectional conceptual diagram showing the structure
Figure 2 is an exploded perspective conceptual diagram showing the overall coupling relationship of an axial flux motor assembly equipped with a dual pump chamber according to an embodiment of the present invention.
Figure 3 is a conceptual diagram showing the stator and internal structure of the core housing, which is a main part of the axial flux motor assembly with a dual pump chamber according to an embodiment of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms.

The examples herein are provided to make the disclosure of the present invention complete and to fully inform those skilled in the art of the scope of the invention.

And the present invention is only defined by the scope of the claims.

Accordingly, in some embodiments, well-known components, well-known operations and well-known techniques are not specifically described in order to avoid ambiguous interpretation of the present invention.

In addition, the same reference numerals refer to the same components throughout the specification, and the terms used (mentioned) in the specification are for explaining embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated in the phrase, and elements and operations referred to as 'including (or, including)' do not exclude the presence or addition of one or more other elements and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains.

Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings.

First, Figure 1 shows the overall structure of an axial magnetic flux motor assembly with a dual pump chamber according to an embodiment of the present invention, and Figure 1(a) is a perspective conceptual diagram showing the exterior. b) is a cross-sectional conceptual diagram showing the internal structure.

Figure 2 is an exploded perspective conceptual diagram showing the overall coupling relationship of an axial flux motor assembly with a dual pump chamber according to an embodiment of the present invention.

Figure 3 is a conceptual diagram showing the stator 101 and the internal structure of the core housing 100, which is a main part of the axial magnetic flux motor assembly with a dual pump chamber according to an embodiment of the present invention.

In the drawing, the unexplained code 150 indicates a connector connected to an external power source.

For reference, reference numerals not shown in FIGS. 2 and 3 refer to FIG. 1.

First, in the present invention, as shown in FIGS. 1 to 3, the side units 200 are largely connected to both ends of the core housing 100, and a support isolation unit ( 300), it can be seen that the structure is combined to be airtight and watertight.

First, the core housing 100 penetrating at both ends includes a yoke 130 penetrating at both ends of a cylindrical shape, and a first hook groove formed radially along one end surface of the yoke 130 and the outer peripheral surface of one end of the yoke 130 ( The first coil 110 wound around 131, and the second coil 120 wound around the second hanging groove 132 formed radially along the other end surface of the yoke 130 and the outer peripheral surface of the other end of the yoke 130. ) has a built-in single stator 101.

Additionally, the side unit 200 may largely include a first side housing 210 and a second side housing 220.

The first side housing 210 is mounted on one end of the core housing 100 and has a first pump chamber 201 inside which a first impeller 230 that rotates by induced electromotive force with the stator 101 is built. .

The second side housing 220 is mounted on the other end of the core housing 100 and has a second pump chamber 202 inside which a second impeller 240 that rotates by induced electromotive force with the stator 101 is embedded. .

The support isolation unit 300 may largely include a first support housing 310, a second support housing 320, a first shaft 330, and a second shaft 340.

The first support housing 310 finishes the open side of the first side housing 210 facing the open end surface of the core housing 100 and is mounted on the core housing 100 to form the first pump chamber. It forms (201).

The second support housing 320 closes the open surface of the second side housing 220 facing the open other end surface of the core housing 100 and is mounted on the core housing 100 to form a second pump chamber. (202) is formed.

The first shaft 330 is supported by the second support housing 320 and the first support housing 310 and is mounted on the first impeller 230.

The second shaft 340 is supported by the second support housing 320 and mounted on the second impeller 240.

The present invention can be applied to the above-mentioned embodiments, and of course, it is also possible to apply the following various embodiments.

First, the first shaft 330 and the second shaft 340 are arranged in a straight line with an imaginary line (ℓ, see Figure 3(b) below) passing through both end surfaces of the yoke 130 to improve space utilization and transport. This would be desirable in terms of efficiency due to minimizing the path of the fluids to be used.

Meanwhile, the side unit 200 is provided in the first side housing 210 and communicates with the first pump chamber 201, and is connected to both ends of the first shaft 330, the second shaft 340, and the yoke 130. A first pipe 211 disposed in a straight line with an imaginary line (ℓ) penetrating the surface may be further provided.

Additionally, the side unit 200 may further include a first port 213 provided at the distal end of the first pipe 211.

In addition, the side unit 200 is provided in the first side housing 210 and communicates with the first pump chamber 201, and provides a transfer path for fluid discharged or introduced by the first impeller 230. A second pipe 212 may be further provided.

Additionally, the side unit 200 may further include a second port 214 provided at the distal end of the second pipe 212.

In addition, the side unit 200 is provided in the second side housing 220 and communicates with the second pump chamber 202, and is connected to both ends of the second shaft 340, the first shaft 330, and the yoke 130. A third pipe 221 disposed in a straight line with an imaginary line (ℓ) penetrating the surface may be further provided.

Additionally, the side unit 200 may further include a third port 223 provided at the distal end of the third pipe 221.

In addition, the side unit 200 is provided in the second side housing 220 and communicates with the second pump chamber 202, and provides a transfer path for fluid discharged or introduced by the second impeller 240. A fourth pipe 222 may be further provided.

In addition, the side unit 200 may further include a fourth port 224 provided at the distal end of the fourth pipe 222.

Meanwhile, the first impeller 230 is seated on the first impeller seating step 215, which is stepped and recessed in a portion connected to the first pipe 211 at the center of one open side of the first side housing 210. It may be provided with a ring-shaped first entrance sleeve 231 that is rotationally supported.

And, the first impeller 230 may be provided with a first entry sleeve 231 and a first base plate 232 built into the first side housing 210.

In addition, the first impeller 230 is radially disposed outside the edge of the first access hole 233 penetrating the first base plate 232 to communicate with the first access sleeve 231 and the first base plate ( It may be provided with a plurality of first blades 234 fixed to 232).

In addition, the first impeller 230 is disposed spaced apart from the first base plate 232 and includes a first cover plate 235 with a plurality of first blades 234 formed between the first base plate 232 and the first impeller 230. can be provided.

And, the first impeller 230 extends along the edge of the first communication hole 236 that penetrates the first cover plate 235 and faces the first access hole 233, and is connected to one end of the core housing 100. It may be provided with a first cover sleeve 237 that protrudes toward the negative side and through which the first shaft 330 is inserted.

In addition, the first impeller 230 includes a plurality of first permanent magnet assemblies 238 formed in a fan shape that are radially arranged along the outer peripheral surface of the first cover sleeve 237 and seated on the first cover plate 235. It may be available.

Meanwhile, the second impeller 240 is seated on the second impeller seating step 225, which is stepped and recessed in a portion connected to the third pipe 221 at the center of one open side of the second side housing 220. It may be provided with a ring-shaped second entrance/exit sleeve 241 that is rotationally supported.

And, the second impeller 240 may be provided with a second entrance sleeve 241 and a second base plate 242 built into the second side housing 220.

And, the second impeller 240 is radially disposed outside the edge of the second entrance hole 243 penetrating the second base plate 242 in communication with the second entrance sleeve 241 and is connected to the second base plate ( It may be provided with a plurality of second blades 244 fixed to 242).

In addition, the second impeller 240 is disposed spaced apart from the second base plate 242 and includes a second cover plate 245 with a plurality of second blades 244 formed between the second base plate 242 and the second impeller 240. can be provided.

And, the second impeller 240 extends along the edge of the second communication hole 246 that penetrates the second cover plate 245 and faces the second access hole 243, and is connected to one end of the core housing 100. It may be provided with a second cover sleeve 247 that protrudes toward the negative side and through which the second shaft 340 is inserted.

In addition, the second impeller 240 includes a plurality of second permanent magnet assemblies 248 formed in a fan shape that are radially disposed along the outer peripheral surface of the second cover sleeve 247 and are seated on the second cover plate 245. It may be available.

Meanwhile, the support isolation unit 300 has a first support groove that is recessed from the first support housing 310 toward one end of the yoke 130 to face the open side of the first side housing 210. (311) may be further provided.

In addition, the support isolation unit 300 is formed to be stepped in the center of the first support groove 311, recessed toward the one end surface of the yoke 130, and penetrates from the one end surface of the yoke 130 to the center of the other end surface. A first bearing groove 312 inserted into the core hole 133 may be further provided.

And, the support isolation unit 300 abuts with the first side flange 216 formed along the open edge of one side of the first side housing 210 and at the same time touches the open edge of one end of the core housing 100. It may further include a first support flange 313 formed along the edge of the first support groove 311, which is fixed in contact with the first core flange 161 formed along the first core flange 161.

In addition, the support isolation unit 300 has a second support groove that is recessed from the second support housing 320 to the other end surface of the yoke 130 to face the open side of the second side housing 220. (321) may be further provided.

And, the support isolation unit 300 is formed to be stepped in the center of the second support groove 321, recessed toward the other end surface of the yoke 130, and penetrates from the other end surface of the yoke 130 to the center of one end surface. A second bearing groove 322 inserted into the core hole 133 may be further provided.

And, the support isolation unit 300 comes into contact with the second side flange 226 formed along the open edge of one side of the second side housing 220 and at the same time touches the edge of the other open end of the core housing 100. It may further include a second support flange 323 formed along the edge of the second support groove 321, which is fixed in contact with the second core flange 162 formed along the second core flange 162.

Here, the first pump chamber 201 is formed by the open side of the first side housing 210 and the first support groove 311, and the second pump chamber 202 is formed by the second side housing 220. It can be seen that it is formed by the open one side and the second support groove 321.

At this time, it can also be seen that the first shaft 330 is seated in the first support groove 311 and supported for rotation, and the second shaft 340 is seated in the second support groove 321 and supported for rotation.

In addition, the first support flange 313 between the first side flange 216 and the first core flange 161 is integrally and fixedly coupled to each other by a plurality of fasteners 400, and the second side flange 226 and the second support flange 323 between the second core flange 162 are integrally and fixedly coupled to each other by a plurality of fasteners 400.

Meanwhile, in the present invention, the size and area of the first hanging groove 131 and the second hanging groove 132 formed on the yoke 130 are shown to be uniform and the same, but it is not necessarily limited to this structure. .

That is, the rotation speed and output of the first impeller 230 and the second impeller 240 can be controlled simultaneously or separately by a single controller provided on one side of the core housing 100.

Here, the rotation speed and output of the first impeller 230 and the second impeller 240 may be controlled to be the same or different from each other.

At this time, the area of the first hanging groove 131 and the area of the second hanging groove 132 are the same or different, and the number of turns of the first coil 110 and the number of turns of the second coil 120 are the same or different. Of course, it can be formed and manufactured differently.

Meanwhile, the yoke ( The distance d1 from one end edge of the yoke 130 and the distance d2 from the virtual plane to the other end edge of the yoke 130 may be manufactured to be the same or different as shown in FIG. 3(a).

That is, when d1 is greater than d2, the number of turns of the first coil 110 increases compared to the number of turns of the second coil 120, so the output of the first impeller 230 is greater than that of the second impeller 240. It will be possible to implement large pump systems.

In addition, when d2 is greater than d1, the number of turns of the second coil 120 increases compared to the number of turns of the first coil 110, so the output of the second impeller 240 is greater than that of the first impeller 230. It will be possible to implement large pump systems.

In addition, in the present invention, as shown, a partition recognition groove 140 recessed along the outer peripheral surface of the core housing 100 may be further provided.

Here, as shown in FIG. 3(b), the distance d3 from one edge of the division recognition groove 140 to one edge of the core housing 100 and the distance d3 from the other edge of the division recognition groove 140 to the core housing 100 The distance (d4) to the edge of the other end of ) may be the same or manufactured differently.

At this time, when d3 is greater than d4, as in the case where d1 is greater than d2, the number of turns of the first coil 110 is greater than the number of turns of the second coil 120, that is, the yoke (d1 is greater than d2) Since 130) is built-in, it will be possible to implement a pump system in which the output of the first impeller 230 is greater than that of the second impeller 240.

In addition, when d4 is greater than d3, as in the case where d2 is greater than d1, the number of turns of the second coil 120 is greater than the number of turns of the first coil 110, that is, the yoke (d2 is greater than d1) Since 130) is built-in, it will be possible to implement a pump system in which the output of the second impeller 240 is greater than that of the first impeller 230.

For example, if the fluid passing through the first pump chamber 201 and the fluid passing through the second pump chamber 202 are different depending on the viscosity or the presence of foreign substances, the first pump chamber 201 and the second pump It will be necessary to control the flow rate and transfer speed of the fluid flowing into and out of the chamber 202 differently.

In this case, the first impeller 230 and the second impeller 240 can be controlled simultaneously or individually with a single controller (hereinafter not shown), as well as the control of the first impeller 230 and the second impeller 240. By controlling the rotation speed or output differently, it will be possible to make it function as two different types of pumps.

In addition, when the two pump chambers 201 and 202 are controlled by this single controller, in terms of functional safety, even if either the first impeller 230 or the second impeller 240 becomes inoperable, the other one Through its operation, it will be possible to secure time to overcome and respond to emergency situations as well as repair and inspection time.

In this respect, the yoke is produced by having different windings of the first coil 110 and the second coil 120, and the formation size and area of the first hanging groove 131 and the second hanging groove 132 being different from each other. When using (130), it is also possible to implement a pump system with different performance by independently applying the electromagnetic performance of the first coil 110 side and the second coil 120 side.

Hereinafter, we will look at the operation and effect of the axial magnetic flux motor assembly equipped with a dual pump chamber according to a preferred embodiment of the present invention as follows.

First, the present invention has independent first and second pump chambers (201, 202) at both ends of the core housing (100) in which a single stator (101) is built, and independently rotatable first and second impellers (230, 240). ) is provided with first and second side housings (210, 220) in which Since the structure is completely airtight and watertight isolated by the 1 and 2 support housings 310 and 320, two water pumps, that is, the first and second impellers 230 and 240, are applied to the single core housing 100. It will be able to have the special advantage of being able to achieve cost reduction through miniaturization, weight reduction, and component minimization.

In addition, compared to the conventional radial flux motor, which requires installing magnetic flux motors corresponding to the number of pumps one by one in places where multiple pumps are needed in electric vehicles or environments where various pumps are needed, the axial magnetic flux according to the present invention In the case of motor assemblies, it will be possible to implement a pump system with high output and efficiency by efficiently using installation area and space in an environment that requires multiple pumps.

And, according to the present invention, the rotation speed of the first impeller 230 and the second impeller 240 can be controlled simultaneously or individually with a single controller to connect two types of pumps to one core housing 100. There is a special advantage that it can be done.

In particular, according to the present invention, even in an emergency situation in which either the first impeller 230 or the second impeller 240 is inoperable, response and recovery work for the emergency situation can be performed while operating the remaining one. Very useful.

In addition, according to the present invention, in some cases, the number of turns of the first coil 110 and the second coil 120, the number of poles and magnetic force of the first permanent magnet assembly 238 of the first impeller 230, and the second impeller ( This is a very useful invention in that it is possible to implement two motors or pump systems with different performances with a single stator 101 by manufacturing the number of poles and magnetic force of the second permanent magnet assembly 248 of 240) differently.

As described above, the basic purpose of the present invention is to provide an axial magnetic flux motor assembly with a dual pump chamber that enables cost reduction through miniaturization, weight reduction, and component minimization by applying two water pumps to a single core housing. You can see that it is being done with a technical mindset.

And, of course, many other modifications and applications are possible for those skilled in the art within the scope of the basic technical idea of the present invention.

100...Core housing
101...Stater
110...first coil
120...second coil
130...York
131...1st hanging groove
132...2nd hanging groove
133...Core hole
140...Division Awareness Home
150...connector
161...First core flange
162...Second core flange
200...side unit
201...1st pump chamber
202...2nd pump chamber
210...First side housing
211...1st pipe
212...2nd pipe
213...1st port
214...2nd port
215...First impeller seating step
216...First side flange
220...second side housing
221...Third pipe
222...4th pipe
223...3rd port
224...4th port
225...Second impeller seating step
226...2nd side flange
230...First impeller
231...First entrance sleeve
232...First base plate
233...1st entrance hall
234...1st blade
235...First cover plate
236...1st communication hole
237...First cover sleeve
238...First permanent magnet assembly
240...2nd impeller
241...Second entrance sleeve
242...second base plate
243...2nd entrance hall
244...2nd blade
245...2nd cover plate
246...2nd communication hole
247...Second cover sleeve
248...Second permanent magnet assembly
300...support isolation unit
310...First support housing
311...First support groove
312...1st bearing groove
313...First support flange
320...second support housing
321...2nd support groove
322...2nd bearing groove
323...second support flange
330...First shaft
340...2nd shaft
400... fastener
ℓ...imaginary line

Claims (5)

A yoke penetrating at both ends in a cylindrical shape, a first coil wound in a first hook groove formed radially along one end surface of the yoke and an outer peripheral surface of one end of the yoke, the other end surface of the yoke, and a second coil of the yoke. A core housing penetrating at both ends and incorporating a single stator including a second coil wound in a second hook groove formed radially along the outer peripheral surface of the end;
A first side housing mounted on one end of the core housing and having a first pump chamber inside which a first impeller rotating by electromotive force induced with the stator is installed, and a first side housing mounted on the other end of the core housing and inside the A side unit including a second side housing having a second pump chamber in which a second impeller rotating by induced electromotive force with the stator is installed; and
a first support housing that finishes the open side of the first side housing facing the open end side of the core housing and is mounted on the core housing to form the first pump chamber; and The first shaft supported by the housing and mounted on the first impeller, and the open side of the second side housing facing the open other end surface of the core housing are closed, and the second side housing is mounted on the core housing. A support isolation unit comprising a second support housing forming a pump chamber and a second shaft supported on the second support housing and mounted on the second impeller,
The first shaft and the second shaft are arranged in a straight line with an imaginary line (ℓ, see FIG. 3(b)) passing through both end surfaces of the yoke,
The rotation speed and output of the first impeller and the second impeller are controlled simultaneously or separately by a single controller provided on one side of the core housing, and the rotation speed and output of the first impeller and the second impeller are The area of the first hanging groove and the area of the second hanging groove are the same or different from each other, the number of turns of the first coil and the number of turns of the second coil are the same or different from each other,
The side unit is provided in the first side housing and communicates with the first pump chamber, and at the same time, an imaginary line (ℓ, Figure 3(b)) passes through both end surfaces of the first shaft, the second shaft, and the yoke. (reference), a first pipe arranged in a straight line, a first port provided at the distal end of the first pipe, and a first port provided in the first side housing and in communication with the first pump chamber by the first impeller. A second pipe that provides a transfer path for fluid to be discharged or introduced, a second port provided at the distal end of the second pipe, and provided in the second side housing to communicate with the second pump chamber and at the same time to communicate with the second pump chamber. A third pipe disposed in a straight line with the shaft and an imaginary line (ℓ, see FIG. 3(b)) passing through both end surfaces of the first shaft and the yoke, and a third port provided at the distal end of the third pipe. and a fourth pipe provided in the second side housing, communicating with the second pump chamber and providing a transfer path for fluid discharged or introduced by the second impeller, and provided at the distal end of the fourth pipe. It further includes a fourth port,
The support isolation unit includes a first support groove recessed from the first support housing toward one end of the yoke, facing the open side of the first side housing, and at the center of the first support groove. A first bearing groove that is stepped and recessed toward one end of the yoke and inserted into a core hole penetrating from one end of the yoke to the center of the other end of the yoke, along an open edge of one side of the first side housing. A first support flange formed along the edge of the first support groove to be in contact with and fixed to the first core flange formed along the open one end edge of the core housing while abutting the formed first side flange, and 2 A second support groove recessed from the second support housing toward the other end surface of the yoke, facing the open side of the side housing, and the other end surface of the yoke stepped at the center of the second support groove. A second bearing groove is recessed on the side and inserted into a core hole penetrating from the other end surface of the yoke to the center of one end surface, and is in contact with a second side flange formed along an open edge of one side of the second side housing. At the same time, it further includes a second support flange formed along the edge of the second support groove and fixed to and in contact with a second core flange formed along the open edge of the other end of the core housing,
The first pump chamber is formed by the open side of the first side housing and the first support groove, and the second pump chamber is formed by the open side of the second side housing and the second support groove. It is formed by, wherein the first shaft is seated in the first support groove and supported for rotation, and the second shaft is seated in the second support groove and supported for rotation. An axial magnetic flux having a dual pump chamber. motor assembly. delete delete delete delete