KR0132908B1 - Magnetic warm water circulating pump with cover type bush bearing - Google Patents

Abstract

The present invention is surrounded by a pumping unit and a driving unit, the power is applied to the stator inside the drive unit is rotated as the rotor is installed on the rotor shaft, the rotor shaft and the drive magnet mounted on the rotor shaft is rotated, this As the driven magnet magnetically coupled to the driving magnet by rotation rotates, an impeller mounted inside the pumping part rotates to discharge hot water introduced into the pumping part through the inlet 19 through the outlet. In the magnetic type hot water circulation pump, a spiral groove in which a fluid flows on the outer circumferential surface thereof is formed in a circumferential direction, and a rotating shaft and an upper opening of the impeller, whose upper end is formed in a truncated or spherical shape, is blocked by a cover. While in point contact or surface contact with the tip of the rotating shaft at the central portion of the inner surface of the cover It relates to a magnetic type hot water circulation pump having a bushing bearing including a bushing bearing inserted in a state in which a gap is maintained between the rotating shaft and the sliding surface with the thrust bearing.

Description

Magnetic type hot water circulation pump with bushing bearing

1 is a longitudinal sectional view of a magnetic type hot water circulation pump having a flat plate type spacer plate.

2 is a longitudinal cross-sectional view of a magnetic pump having a bushing bearing in accordance with a first embodiment of the present invention.

3 is a schematic cross-sectional view illustrating the assembled state of the bushing bearing and the impeller rotating shaft according to the second embodiment of the present invention.

4 is a schematic cross-sectional view illustrating the assembled state of the bushing bearing and the impeller rotating shaft according to the third embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: hot water circulation pump 3: pumping part

5 driving part 7 stator

9: rotor shaft 11: rotor

13: driving magnet 15: driven magnet

17: impeller 19: inlet

21 outlet 22 gap plate

23: rotating shaft 25: bushing bearing,

27: cover 29,31: sliding surface

33: spiral groove

The present invention relates to a magnetic type hot water circulating pump having a bushing bearing. More specifically, the present invention relates to a magnetic hot water circulation pump that acts between the bushing bearing and the thrust bearing at the start of the pump by maximally reducing the contact area between the bushing bearing and the thrust bearing of the pump. Magnetic pump with cover-type bushing bearing designed to improve the pump efficiency by preventing the temperature rise by laying a spiral groove on the circumferential surface of the impeller rotating shaft portion inserted into the bushing bearing while reducing the frictional force It is about. Generally, there are various types of hot water circulation pumps which are configured to circulate hot water by force, and one of them may be a magnetic type centrifugal hot water circulation pump. This magnetic type hot water circulation pump, shown at 101 in FIG. 1, is composed of an upper pumping part 103 and a lower driving part 105. As shown in FIG. When power is applied to the stator 109 incorporated in the drive unit 105, the rotor 113 mounted on the rotor shaft 111 rotates. As a result, when the rotor shaft 111 rotates, the driving magnets 115 arranged on the rotor shaft 111 interlock to rotate. The rotation torque is transmitted to the Middle East magnet 117 which is magnetically coupled to the magnet 115 with the spacer plate 107 interposed therebetween by the rotation of the driving magnet 115 so that the Middle East magnet embedded in the pumping part 103 is provided. 117 and the impeller 119 on the top of the magnet 117 is rotated. The circulating water, ie, hot water, introduced into the pumping part 103 through the inlet 121 by the rotation of the impeller 119 is subjected to centrifugal force to impinge the outer wall of the pumping part 103 to form an internal pressure. Due to the pressure difference caused by the flow from the high pressure to the low pressure region is discharged through the outlet 123. Here, the impeller 119 does not generate a thrust when the pump 101 is first started. Therefore, since the impeller 119 does not have a lift force, the side surfaces of the bushing bearing 127 and the top surface of the thrust bearing 129 are subjected to surface contact by receiving the excessive force in the perpendicular direction due to the magnetic force of the magnetic couplings 115 and 117. The frictional force on the hibernating surface 131 causes a problem of starting, and in order to solve the problem of starting, the condenser or the number of windings of the sub-coil is increased or excessive condenser is increased to increase the starting torque of the motor of the pump driving unit 105. The design has to be reduced, resulting in a reduction in the efficiency of the motor and pump. Accordingly, attempts have been made to solve the problems caused by such conventional magnetic pumps with flat bearings, and the present invention has been devised to solve these problems. Therefore, an object of the present invention is to cover the opening of one of the open bushing bearings in order to reduce the excessive frictional force acting on the sliding surface where the side of the bushing bearing and the upper surface of the thrust bearing contact when the pump is started, to make a cover, and to the end of the impeller shaft. To minimize the loss of pumping power due to friction by reducing the frictional area by inducing a conical or spherical shape so that only a very small portion of the inner surface of the cover is in surface contact or contact. Therefore, in order to achieve the above object, the present invention is surrounded by a pumping part and a driving part, and the rotor is built on the rotor shaft by applying power to the stator inside the driving part, so that the rotor shaft and the upper end of the rotor shaft are rotated. As the mounted driving magnet rotates, and the driven magnet magnetically coupled to the driving magnet rotates by the rotation, the impeller mounted inside the pumping part rotates to receive hot water introduced into the pumping part through the inlet. In the magnetic type hot water circulation pump configured to discharge through an outlet, a rotating shaft and an upper opening of the impeller in which a helical groove through which a fluid flows on the outer circumferential surface thereof is formed in a circumferential direction, and an upper end thereof is formed in a truncated cone or spherical shape. Is blocked by the cover and the rotation axis at the central portion of the inner surface of the cover It is to provide a magnetic type hot water circulation pump having a cover-type bushing bearing including a bushing bearing inserted in a state in which a clearance is maintained between the rotating shaft and the sliding surface of the thrust bearing while being in contact with a tip or a check tip. . Hereinafter, a hot water circulation pump according to an embodiment of the present invention with reference to the accompanying drawings in more detail. As shown in FIG. 3, the magnetic hot water circulation pump 1 is largely surrounded by the pumping unit 3 and the driving unit 5. When the power is applied to the stator 7 inside the driving unit 5, the rotor shaft ( The rotor 11 built in 9) rotates. When the rotor shaft 9 rotates as the rotor 11 rotates, the driving magnet 13 mounted on the upper end of the rotor shaft 9 rotates, and the driven magnet is magnetically coupled to the driving magnet 13. 15 also rotates together. Accordingly, when the impeller 17 mounted above the driven magnet rotates inside the pumping unit 3, the circulating water, that is, hot water, flows into the pumping unit 3 through the inlet 19. The introduced hot water forms an internal pressure by colliding with the outer wall of the pumping unit 3 by centrifugal force, and flows from the high pressure to the low pressure region by the pressure difference generated by the pressure and is discharged through the outlet 21. Here, the lid 27 is formed by blocking the upper opening of the bushing bearing 25 that radially slides the rotary shaft 23 of the ceramic impeller 17 insert-injected into the spacer 22. And a clearance gap is formed in the sliding surface 29 which the lower side surface of the bushing bearing 25 and the upper surface of the thrust bearing 26 abut, and the sliding surface 31 which the inner peripheral wall surface of the bushing bearing 25 and the outer peripheral surface of the rotating shaft 23 contact. The hot water flows through the gap, and the upper end of the rotating shaft 23 is truncated or spherical so that the rotating shaft 23 is supported by the bushing bearing 25. The point contact or the point contact with the center of the surface, therefore, even when the impeller 17 does not generate a thrust due to rotation when the pump 1 is started and does not have ascending force, the magnetic force of the magnetic couplings 13 and 15 The frictional force acting on the sliding surface 29 where the side surface of the bushing bearing 25 and the upper surface of the thrust bearing 26 are in contact with each other becomes significantly small, however, in the closed space formed by the bushing bearing 25. Frictional heat In order to suppress the occurrence, a spiral groove 33 in which a fluid can flow on the outer circumferential surface of the rotating shaft 23 is formed in the circumferential direction and is excessively introduced by the hot water flowing into the sliding surface 29 and passing through the groove 33. In addition, the rotational shaft 23 is prevented from oscillating to the left and right in the bushing bearing 25 by the dynamic pressure formed by the fluid passing through the groove 29 formed in the circumferential direction. By maintaining the pressure in the circumferential direction of the rotating shaft 23 uniformly to be self-aligning, it is possible to maintain a close gap between the rotating shaft 23 and the bushing bearing 25. After the pump 1 is started, the impeller 17 When it starts to operate normally, the magnetic force by the magnetic couplings 13 and 15 is mostly canceled by the thrust of the impeller 17, so that the contact due to the point contact or the surface contact of the tip of the rotating shaft 23 and the bushing bearing 25 is performed. There is no need to worry about concentration of power, as shown in Figures 3 and 4, which illustrate other embodiments of the present invention, in the second embodiment shown in Figure 3 the same as in the first embodiment. The rotary shaft 223 is bushed bearing in a state in which the machined rotary shaft 223 is driven into the impeller 217 and assembled by insert-inserting the bushing bearing 225 into the spacer plate 235 so that the cover 227 faces downward. Insert it into (225). In the third embodiment shown in FIG. 4, the upper end of the rotating shaft 323 is conical and at the same time as the tip of the bushing bearing 325 at the center of the inner surface of the cover 327 of the bushing bearing 325. The conical sheet 337 of the shape is squared so as to mate with each other when the rotating shaft 323 is inserted into the bushing bearing 325. Thus, the rotary shaft 323 and the bushing bearing 325 at the same time and the point contact and the surface contact at the same time as the rotary groove 333 as well as the helical groove 333 as in the first embodiment, not only by the conical seat surface 337 And to automatically adjust the center of the bushing bearing 325. Therefore, according to the present invention, by reducing the contact area between the bushing bearing and the thrust bearing of the pump as much as possible, the friction force acting between the bushing bearing and the thrust bearing when the pump is started to be maximized to increase the starting torque of the pump motor at the pump starting. There is no fear that the efficiency of the motor and pump will be reduced since there will be no, and ultimately, the performance of the pump will be improved. The present invention as described above is capable of various modifications and changes by those skilled in the art through the detailed description and drawings of the invention within the scope without departing from the spirit and scope described in the appended claims. Will do.

Claims (3)

The rotor shaft is surrounded by the pumping section 3 and the driving section 5, and the power is applied to the stator 7 inside the driving section 5 to rotate the rotor 11 arranged on the rotor shaft 9. (9) and the drive magnet 13 mounted on the rotor shaft (9) is rotated, the rotation of the driven magnet (15) magnetically coupled to the drive magnet 13 by the rotation of the pumping portion ( 3) The magnetic type hot water circulation pump 1 is configured to discharge the hot water introduced into the pumping part 3 through the inlet port 19 by rotating the impeller 17 mounted therein. In the circumferential direction is formed a spiral groove 33 through which the fluid can flow on the outer circumferential surface of the rotary shaft 23, the upper opening of the impeller 17 is formed in the shape of a truncated cone or spherical shape. 27) blocked at the center of the inner surface of the lid 27 And a bushing bearing 25 which is inserted in a state in which a gap is maintained between the rotary shaft 23 and the sliding surfaces 31 and 29 with the thrust bearing 26 while being in point or surface contact with the tip of the shaft 23. Magnetic type hot water circulation pump having a cover-type bushing bearing, characterized in that. According to claim 1, The rotating shaft 223 is driven into the center of the impeller 217, the bushing bearing 225 is inserted into the center of the spacer plate 235 so that the cover 227 is directed downward Magnetic type hot water circulation pump having a cover-type bushing bearing, characterized in that coupled by. The top of the rotating shaft 323 is formed in a conical shape, the bushing bearing 325 is a conical shape corresponding to the front end of the bushing bearing 325 in the center position of the inner surface of the cover 327 Magnetic type hot water circulation pump with cover bushing bearing, characterized in that the seat (337) is laid out.