Method for assembling a water pump

Abstract

Method to assemble a water pump with an impeller driven by an electrical machine comprising a housing cap and a volute with an inlet and an outlet and a boot hosting a stator and a rotor of the electrical machine and an electronic board mounted at the side apart from the impeller and covered by the cap housing, the boot having a radial extending rim comprising at least slots defined by the following steps: connecting the volute to the boot by inserting axial hooks in the boot's slots, twisting the volute versus the boot to fix the axial hooks, inserting radial hooks of the cap housing in the same slots.

Claims

1. A method to assemble a water pump with an impeller driven by an electrical machine comprising a housing cap and a volute with an inlet and an outlet and a boot hosting a stator and a rotor of the electrical machine and an electronic board mounted at the side apart from the impeller and covered by the cap housing, the boot having a radial extending rim comprising at least slots and lugs formed as walls at least partially surrounding the slots at an outside circumference of the rim and at end faces of the slots defined by the following steps: Connecting the volute to the boot by inserting axial hooks in the boot's slots, wherein the axial hooks are guided and restricted from moving radially outward by the lugs, Twisting the volute versus the boot to fix the axial hooks, and Inserting radial hooks of the cap housing in the same slots.

2. The method according to claim 1, wherein the axial hooks are each an axial L-formed hook, and the axial L-formed hooks are fixed with the smaller arms of the L to the rim of the boot.

3. The method according to claim 1, wherein the axial hooks are guided by the lugs surrounding the slots.

4. The method according to claim 1, wherein the axial hooks are each an axial L-formed hook, and the twisting is in direction of the opening of the smaller arms of the axial L-formed hooks.

5. The method according to claim 1, wherein the radial hooks are guided by lugs surrounding the slots and the axial hooks.

6. The method according to claim 1, wherein the broadness of the axial hooks and the radial hooks are together as broad as the slot.

7. The method according to claim 1, wherein the stator includes a stator stack, wire and pins and the stator stack is over molded with a first plastic material and at least the stator stack, wires and pins are over molded with a second plastic material to form a cylindrical ring and a heat sink that seals a cylindrical opening of the boot before assembly to the other parts.

Description

DRAWINGS

(1) The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.

(2) The disclosure is described in the figures and the following description.

(3) FIG. 1 shows a water pump as in state of the art and. illustrates a cross sectional view of a housingless water pump 2,

(4) FIG. 2 shows a water pump according the disclosure,

(5) FIG. 3 shows a cross section of the water pump,

(6) FIG. 4 and FIG. 5 show an explosion view

(7) FIG. 6 shows a boot and a heat sink of the water pump, and

(8) FIGS. 7-9 show a method of assembling the water pump.

(9) Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.

DETAILED DESCRIPTION

(10) Example embodiments will now be described more fully with reference to the accompanying drawings.

(11) The water pump 2 includes a volute 10, a boot 20, and a band clamp 22 attaching the boot 20 and the volute 10. The volute 10 includes an inlet 12 and an outlet 14.

(12) The volute includes a power supply connection 16.

(13) The volute 10 is connected to a boot 20 via a band clamp 22 forming a cover 4, which encompasses the internal components and includes a power supply connection 16 for housing a supply line 46. The internal components of the housingless water pump 2 include a stator 24 press fit into the boot 20. The stator 24 surrounds a rotor 26. The rotor 26 is separated from the stator 24 by a wet sleeve 30. The rotor 26 and the stator 24 are separated by a magnetic air gap having a distance (A). The wet sleeve 30 prevents fluid from contacting the stator 24. The rotor 26 includes a shaft 38 and an impeller 28 for moving a fluid as the fluid enters the inlet 12. The impeller 28 moves the fluid through the outlet 14 for use. An electronic board 40 is located outside the wet sleeve 30 so that the electronic board 40 is separated from any fluids within the housingless pump 2.

(14) FIGS. 2 to 9 shows an embodiment of the water pump with reduced parts, especially without wet sleeve, according the disclosure.

(15) The pump 2 has a boot 20 that combines different functions: the boot defines the outer circumference of the pump, covers the stator 24 and a wet sleeve function and host a rotor 26. A heat sink 5 is mounted in the boot 20 wherein a rotor shaft 38 is seated. A sealing 6 in form of an O-ring seals the heat sink 5 versus the inner circumference of the boot 20 in an opening 50.

(16) The boot 20 has the form of a cylindrical ring with the cylindrical opening 50 inside. In the ring the devices of the stator are located in the opening the rotor 26 is mounted around the shaft 38.

(17) The pump boot is prepared by over molding the stator 24 that eliminates air gaps between the different components as stator stack 7, supply pins 9 and copper wires 8. The over molding increases the heat dissipation of the stator. The stator stack 7 is over molded during the process by a first material M1. The first material is for example a plastic material: PA66-GF30Glass. The material is fiber reinforced and has a good heat aging. The material M1 should have a high stiffness and dimensional stability and must be specified for producing electrically insulating parts.

(18) After this first step of over molding the stator stack 7 the supply pins 9 are inserted and connected to the wires and the winding of wires 8 is finalized. After contacting wires and pins and an electrical control the package is over molded with a second material M2. The material M2 is for example PPS-GF34 that has a good resistance against aging, chemicals and radiation and forms a boot that is strong and rigid.

(19) After the boot is completed as over molded single part a heat sink 5 bearing a shaft 38 is mounted along the inner circumference of the boot 20.

(20) The heat sink 5 is sealed in the opening 50 with an O-ring 6 against the boot.

(21) Alternative to the solution with the separate heat sink 5 the bottom of the boot can be closed by the molding process, including a seat for the shaft 38.

(22) This closed solution could be applied if temperatures are lower than about 90°, creating a part that reduces the need of sealing.

(23) An electronic board 40 is mounted on the surface of the boot 20 at the heat sink 5 apart from the impeller 28 portion.

(24) The volume of air trapped around the electronic board 40 is reduced. This results in a increasing of heat transfer rates and a reduction of the overall volume of the water pump. In cases where it is necessary to fill the volumes with plastic molded material to keep the components stable the electronic board can be mounted before the last over molding process with material M2 takes place.

(25) The electronic board and a first portion P1 of the length l of the boot is covered with part of a housing cap 41 a second portion P2 of the length l of the boot is covered by a part of a volute 10. The volute and the cap housing are sealed with Orings versus the boot outer circumference.

(26) In FIG. 6 the two central parts the boot 20 and the heat sink 6 are shown. FIG. 6a shows in an explosion view the boot made from plastic mold material having a cylindrical opening 50. The opening 50 better seen in FIG. 6c in a cross section along A-A of FIG. 6b is adapted to be closed on one side by the heat sink 5 as shown in FIG. 6d. FIG. 6e is the situation after the heat sink 5 with the sealing 6 is installed in the opening of the boot. FIG. 6f shows a view from the bottom of the boot after installation of the heat sink. In the embodiment of FIG. 6 a rim 43 is molded in the over mold process of stator 24.

(27) The rim 43 surrounds the complete circumference of the boot 20 and extend to a larger diameter in comparison to the diameter of the boot. The rim is part of the mounting and fixing devices that are discussed later. The rim 43 includes in this embodiment four lugs 42 that surrounds slots 44 in the rim. The slots are arranged along a radial length and follow the radii of the boot. The lugs 42 are formed as walls surrounding the slots 44 at the outside circumference of the rim and partly two end faces of the slot.

(28) In FIGS. 4 and 5 the parts of the whole water pump are shown in an explosion sketch. On the right side the volute 10 is shown as part of the final water pump. This volute 10 comprises axial hooks 11 which are arranged at the outer circumference of the device. The axial hooks 11 are defined by hook structures 52 formed like a L and wherein the hooks are extending along the diameter of the volute 10. The openings of the hook structures 52 are arranged around the diameter so that the hook openings, the direction of the smaller arm of the L of two adjacent axial hooks are all apart from each other looking in the same direction. The hooks 11 do not increase diameter of the volute but only extend along the axial direction.

(29) For assembling the water pump the boot 20 has the rim 43 with the slots 44. The cap housing 41 is designed with radial hooks 45 wherein the openings of the radial hooks are directed radial outside the diameter of the cap housing 41.

(30) The radial hooks are mounted by tongues 53 that are fixed at the outer side of the cap housing, providing a defined flexibility. Normally the radial hooks are mold with the cap housing in one step.

(31) In FIGS. 7, 8 and 9 the mounting process of the water pump is explained.

(32) In a first step the volute 10 with the axial hooks 11 is put on the boot 20 and the axial hooks 11 enter into the slots of the rim 43 of the boot. For an easy insertion the slots 44 have rims 42 to guide the axial hooks 11 better. The insertion of the hooks 11 is so deep that the smaller arms of the L-formed axial hooks are completely put through the slots. The slot are broad enough to catch the hooks easily.

(33) This insertion is also supported because the hooks are formed to follow the circumference contour of the volute, FIG. 8a, 8b.

(34) In a second step the both parts, boot 20 and volute 10, are twisted along their central axis in the direction of the hooks' openings so that smaller arm of the L-formed axial hooks is overlapping the rim of the boot, as visible in FIG. 8c.

(35) The volute is therefore fixed to the boot.

(36) The slot 44 in the rim 43 is remaining broad enough to be able to be snap fitted to the radial hooks 45 of the cap housing 41.

(37) The radial hooks 45 are flexible and it is possible to press them through the remaining space of the slot 44 to be fixed by the hooks' noses that extend outwardly.

(38) The mounting and fixing method works with the two types of hooks in the two covering parts having together a broadness b1 and b2 to fill the space in the slots in the rim.

(39) The hooks of the cap housing blocks a rotation of the volute back to the original mounting position and finalize the water pump assembly process.

(40) The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.