DE29709007U1 - Magnetically connectable pump - Google Patents

Description

WIL H£ LM _# .&:»DA"ÜS:TER

PATENT ATTORNEY, DEALER OF PATENT ATTORNEYS

D-70174 STUTTGART HOSPI ¹ SAiSTfASSE 8 ^# * f ELECTRONIC (0711)228110 FAX (0711)2281122

Applicant: 21.05.1997

G12035/65a

Chen-Ta LIEU Dr.W/we

No. 490, Shui Yuan Rd.
Fengyuan City,
Taichung Hsien, Taiwan ROC

Magnetically coupled pump BACKGROUND OF THE INVENTION

1. Field of the invention

The present invention relates to a magnetically coupled pump and, in particular, to a magnetically coupled corrosion-resistant pump with a smaller space requirement and a higher structural strength.

2. Description of the state of the art

A conventional corrosion-resistant pump typically has a design as shown in Fig. 4. The pump consists of a front housing 80 and a rear housing 90. A motor 91 is disposed in the rear housing 90. The motor 91 has an output shaft 92 having a first end extending into the front housing 91. An isolating member 81 has a first end with cup-shaped flanges 810 attached to the front end of the front housing 80 and a second end extending into the front housing 80. The isolating member 80 also receives an axle 82 on which a sleeve 820 is mounted. A drum 83, which is made of corrosion-resistant

material and having an inner magnet rotor 830 is further arranged around the sleeve 820. An impeller 831 is fixed to the front end of the drum 83. By this arrangement, the impeller 831 is driven to feed liquid when the drum 83 is rotated. In addition, a support frame 84 is provided between the front housing 80 and the insulating member 81. A bottom of this support frame 84 is connected to the drive shaft 92 extending from the rear housing 90. An outer magnet rotor 85 corresponding to the inner magnet rotor 830 is arranged inside the support frame 84. With this arrangement, the output shaft 92 and thereby the support frame 84 are driven to rotate in the same direction when the motor 91 rotates. Since the inner magnet rotor 830 and the outer magnet rotor 85 have the same number of magnetic poles, the drum 83 is driven according to the principle of "N" and "S" pole attraction. In this way, the pump impeller 831 is then driven to convey liquid in the direction of the arrow shown in Fig. 4.

However, the corrosion-resistant pump mentioned above has several disadvantages. Since the insulating member 81 has a first end located at the front end of the front housing 80 and a second end extending into the front housing 80, the connection X between the insulating member 80 and the cup-shaped flanges 810 may cause gaps to form due to a large rotation caused by the rotation of the pump. These gaps may in turn cause the liquid pumped by the impeller 831 to enter the front housing 80 and the rear housing 90 and affect the motor 91. In addition, various parts provided in the conventional pumps, such as the inner and outer magnet rotors 830, 85, the support frame 84, contribute to an unnecessarily large volume of the pump. Finally, if the flow (the rotation speed) of the pump is to be controlled, it will be necessary for the pump to be equipped with an additional speed control device.

This equipment not only increases the cost of the product but also the volume of the pump.

The present invention provides an improved magnetically coupled pump that reduces and/or avoids the noted problems.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a magnetically coupled pump with a smaller footprint and improved strength. Another object of the invention is to provide a magnetically coupled pump provided with a mounted control box in which a circuit for controlling the liquid flow is housed.

According to one aspect of the present invention, the magnetically coupled pump comprises a cylindrical housing, a cylindrical insulating member within the housing, a drum and a stator. The cylindrical housing has a rear cover and a control housing. The cylindrical insulating member with a U-shaped longitudinal section has a cup-shaped flange at one end which is connected to the housing and a recess at its rear end for receiving a Hall element and an inner axis. This axis is provided with a sleeve mounted on it in a central region, the drum in turn is arranged around the sleeve of the cylindrical insulating body. The drum accommodates a ring magnet rotor and a circular magnet. The magnetization direction of the magnet causes an angle of 90 ° on the magnet rotor. The stator is arranged around the cylindrical insulating body. The stator has coils with at least two poles. In accordance with another aspect of the invention, the housing has a front cover defining an inlet and an outlet, and a flow passage between the inlet and outlet.

In accordance with another aspect of the invention, the cylindrical insulating member further includes a protective casing on an outer side of the magnet and the Hall element to prevent interference resulting from magnetization of the coils.

In accordance with another aspect of the invention, a plurality of switches are arranged in the control unit of the housing, each of which is connected to the stator coils, and a power supply is provided to drive the magnet rotor. Other objects, advantages and novel features of the invention will become more apparent from the following detailed description which is given with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a longitudinal section through a magnetically coupled pump according to the invention,

Figs. 2 and 3 are cross-sectional views showing the control circuit arrangement of the magnetically coupled pump according to the invention and

Fig. 4 is a longitudinal section through a conventional, corrosion-resistant pump.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

According to Fig. 1, the magnetically coupled pump has the
Invention a cylindrical housing 10. The cylindrical housing
10 has a rear cover 11 and a control box
12 on the rear side. The cylindrical housing
10 further has a front cover 13, which has a
Inlet 131, an outlet 132 and a flow path {not

marked) between the inlet 131 and the outlet 132.

A cylindrical insulating member 20 with a U-shaped longitudinal cross section is arranged in the housing 10. The cylindrical insulating member 20 has a cup-shaped flange 21 at one end which can be screwed to the front end of the housing 10.

A rear end of the insulating member 20 abuts against the rear cover 11 of the cylindrical housing 10 so that a bolt 14 can connect the rear cover 11 to the insulating member 20. Since the front and rear ends of the cylindrical insulating member 20 are firmly connected to the housing 10, the pump can withstand strong vibrations resulting from its rotation. In addition, an axle 22 is provided in the cylindrical insulating member 20. This axle 20 has an axle sleeve 220 arranged in a central region. Both ends of the sleeves 220 are secured by a spacer ring 221 and a gasket 222, respectively. The cylindrical insulating member also has a recess 201 suitably arranged at the rear end to receive a Hall element 202 provided to sense the change in magnetic polarization in the insulating member 20. Furthermore, a housing 203 is provided at the rear end of the insulating member 20 in order to "avoid" interference with the Hall element 202 resulting from the magnetization of the coils.

A drum 30 is arranged around the sleeve 220 of the axis 22 of the cylindrical insulating member 20. The drum 30 is made of corrosion-resistant material and accommodates a circular magnet rotor 31 and a circular magnet 32. The magnetizing direction of the magnet 32 causes an angle of 90° on the magnet rotor 31. The drum 30 is further provided with a pump wheel 34 at the front end for conveying liquid. The pump wheel 34 is at a front end of the axis

22 by means of a front arm 23 which is provided to limit the movement of the pump wheel 34.

In addition, a stator 40 is arranged around the cylindrical insulating member 20. The stator 40 has coils with at least two poles 41, 42.

The mode of operation of the magnetically coupled pump is now described with reference to Fig. 2.

For the purpose of illustration, a magnetically coupled pump is provided which has coils with two poles. In practice, however, coils with multiple poles, ie more than three poles, are to be provided in order to provide stable operation. Fig. 2 shows the control arrangement of the magnetically coupled pump according to the invention. A control circuit in the control box 12 consists of a first switch 121, a second switch 122 and a power supply (not shown). The first switch 121 and the second switch 122 are connected to the coils 41, 42 of the stator 40, the Hall element 202 and the power supply, respectively. As mentioned above, the Hall element 202 detects the polarization variation of the magnet rotor 31 by the magnet 32 of the insulating member 20. When the magnet 32 is close to the Hall element 202, the magnetic flux through the Hall element 202 is at its maximum. Since one pole of the magnet 32 detected by the Hall element 202 is S, the α end of the Hall element 202 of Fig. 2 is caused to output a large voltage to rotate the first switch 121. The coil 41 is therefore magnetized and forms an "S" pole to attract an "N ^n" pole of the magnetic rotor 31 of the drum 30. The drum 30 then rotates through an angle to cause the magnet 32 to move away from the Hall element 202. At this time, there is no magnetic flux through the Hall element 202, so that no Hall voltage is generated at the A and B outputs, and the two coils 41, 42 do not become effective. The inertial rotation of the

However, drum 30 causes the "N ^w pole of magnet 32 to now come close to Hall element 202, as shown in Fig. 3. In this case, the magnetic flux through Hall element 202 is significantly increased so that the B terminal of Fig. 2 outputs a large voltage to turn on second switch 122. This magnetizes coil 42 and forms a "S ^u pole to attract the "N" pole of magnet rotor 31, thus driving drum 30 to rotate continuously.

The magnetically coupled pump according to the invention is therefore designed to alternately carry out the above-mentioned operations in order to rotate the magnetic rotor 30 of the drum 30 and in this way also to drive the pump wheel 34 which pumps liquid through the front cover 13 of the housing.

The rotation speed of the magnetic rotor 31 can also be controlled by adjusting the power supply at the control box. If the power supplied to the control box 12 is high, then the rotation speed of the magnetic rotor 31 will also increase as the current increases. On the other hand, if the power supplied to the control unit 12 is small, the rotation speed of the magnetic rotor 31 will decrease as the current decreases. The magnetic coupling can therefore adjust the rotation speed very easily without an additional control device. The space required for the pump can therefore be reduced.

Claims (4)

Protection claims 1. Magnetically coupled pump with a cylindrical housing with a rear cover and a control box, a cylindrical insulating member with a U-shaped longitudinal cross-section within the housing (10), this insulating member having a bowl-shaped flange (21) at the front end to come into contact with the housing (10), a recess (201) at the rear end for receiving a Hall element (202), an axle (22) which is provided with a sleeve (220) in its central region, a drum (30) which is arranged around the sleeve (220) of the cylindrical insulating member (20) and which has a circular magnet rotor (31) and a circular magnet (32), wherein the magnetization direction of the magnet on the magnet rotor causes an angular movement of 90° and wherein a stator is arranged around the cylindrical insulating member (20) which has coils (41, 42) with at least two poles. 2. Magnetically coupled pump according to claim 1, wherein the housing (10) has a front cover (13) which forms an inlet (131), an outlet (132) and a flow path between the inlet and the outlet. 3. Magnetically coupled pump according to claim 1, wherein the cylindrical insulating member (20) has a housing (203) in the region of the outside of the magnet (32) and the Hall element (202) in order to avoid interference resulting from the magnetization of the coils. 4. Magnetically coupled pump according to claim 1, wherein the control box (12) of the housing (10) is provided with a plurality of switches (121, 122), and each switch is connected to the stator coil (41, 42) and a power supply, respectively, to drive the magnetic rotor.