Connection system

Abstract

A connection system (1) for detachably connecting a component element to a coated component part (3), includes a coupling element (2) that has a head (6) with a non-round outer cross-section and has a shank (5). The head (6) can be received by a frictional connection in a rotationally fixed manner in a head region (11) of a connection opening (4) of the component part (3). The shank (5) can be received in a friction-locked and/or firmly-bonded manner in a sealing region (12) of the connection opening (4). The head (6) has an internal geometry for connecting the component element.

Claims

1. A connection system (1) for detachably connecting a component element to a coated component part (3), comprising a coupling element (2) that has a head (6) with a non-round outer cross-section and has a shank (5), wherein the head (6) is received by means of an interlock in rotationally fixed manner in a head region (11) of a connection opening (4) of the component part (3), and the shank (5) is secured stationarily in a frictionally held manner or firmly bonded manner in a sealing region (12) of the connection opening (4), and the head (6) has an internal geometry for connecting the component element, wherein the coupling element has an axial passage opening, inside walls of the shank (5) that receive a component element and that extend along a longitudinal axis of the shank are smooth, and the coupling element comprises a corrosion-resistant material, wherein the connection system (1) further comprises the component part (3), wherein the component part (3) has a coating (15) which extends over an interface between the coupling element (2) and the component part (3), the coating (15) reliably preventing corrosive media to flow the between the shank and sealing region of the component part (3).

2. The connection system according to claim 1, characterized in that the internal geometry is formed as an internal thread (10).

3. The connection system according to claim 1, characterized in that the head (6) has a greater outer diameter than the shank (5), wherein the head (6) and the shank (5) are in particular designed as one piece.

4. The connection system according to claim 1, characterized in that the shank (5) has a round cross-section.

5. The connection system according to claim 1, wherein the coupling element (2) has a greater axial length than the connection opening (4), wherein the connection opening (4) ends in a flow channel (14) of the component part.

6. The connection system according to claim 5, characterized in that the shank (5) has a greater axial extent than the sealing region (12).

7. The connection system according to claim 1, wherein the coating (15) extends up to a front side of the shank (5), which front side faces away from the head (6), and extends in particular up into the passage opening (7).

8. The connection system of claim 1, wherein the coating is applied after insertion of the coupling element into the connection opening.

9. The connection system of claim 1, wherein the component part c is a pump housing.

10. The connection system of claim 9, wherein the pump housing is made from gray iron.

11. The connection system of claim 1, wherein the corrosion-resistant material comprises a bronze material.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features, details and advantages of the invention arise from the following description of exemplary embodiments based on the drawings. In the figures:

(2) FIG. 1 shows a spatial illustration of a coupling element prior to the insertion into a component part, and

(3) FIG. 2 shows the component part with inserted coupling element in cross-section.

DETAILED DESCRIPTION OF THE INVENTION

(4) FIG. 1 shows a connection system 1 that comprises a coupling element 2 and a coated component part 3 with a connection opening 4 for receiving the coupling element 2. The coupling element 2 has a shank 5 and a head 6, wherein the shank 5 has a round outer cross-section and the head 6 has a polygonal outer cross-section. The coupling element 2 is provided with an axial passage opening 7 that extends axially through the entire coupling element thus from a front side 8 facing away from the head up to a front side 9 arranged on the head 6. Thus, the shank 5 has a quasi-tubular shape. In this exemplary embodiment, the coupling element 2 is made from bronze, thus from a corrosion-resistant material that has sufficient stiffness and strength.

(5) In the head 5 of the coupling element 2 there is an internal thread 10 that serves as internal geometry for connecting a component element. In this exemplary embodiment, the shank 5 is formed with smooth walls on the inside and on the outside.

(6) The connection opening 4 in the component part 3 has a head region 11, the shape of which is adapted to the shape of the head 6 of the coupling element 2. In this exemplary embodiment, the head region 11 is also formed with a hexagonal inner cross-section. In the inserted state of the coupling element 2 in the connection opening 4, flat surfaces of the head 6 then rest against flat surfaces of the head region 11 so that relatively high torques can be transmitted from the coupling element 2 to the component part 3.

(7) FIG. 2 shows the connection system 1 in the assembled state. The coupling element 2 has been inserted completely into the connect ion opening 4. Here, the shank 5 of the coupling element 2 is held in a friction-locked manner in a sealing region 12 of the connection opening 4 and secures the coupling element 2 with respect to the component part 3 substantially in the axial direction. For this purpose, the shaft 5 can be oversized with respect to the connection opening 4 so that an interference fit is obtained.

(8) The head 6 is received in the head region 11 in a form-locking manner. The sealing region 12 has a lesser axial extent than the shank 5, and the head region 11 has a greater axial extent than the head 6. Thereby, an air gap is created between a step that is formed by the transition from the head region 11 to the sealing region 12, and a step between the shank and the head 6. Thus, there is no form-locking connection in the axial direction so that relatively wide tolerances can be compensated, in particular with regard to the material thickness of the component part 3, which influences the length of the connection opening 4.

(9) The front side 8, in which the passage opening 7 ends, protrudes slightly beyond an inner surface 12 of the component part 3, which inner surface bounds a flow channel 14. Here, flow channel designates generally a chamber that is suitable for receiving a fluid, in particular a liquid.

(10) The inner surface 13 of the component part 3 is provided with a corrosion-resistant coating 15 so that the component part 3, for example, can be made as a gray iron casting and is still sufficiently protected against corrosion. The coating 15 extends also to the front side 8 of the coupling element 2 and can reach up into the passage opening 7. A transition between the coupling element 2 and the component part 3 is therefore covered by the coating and is reliably sealed. In the coupling element 2, no coating is required since the coupling element 2 is made completely from a corrosion-resistant material.

(11) The connection system according to the invention provides a coupling element 2 that is stationarily received in a connection opening 4 of a component part 3, wherein, the coupling element 2 consists of a corrosion-resistant material, and the component part 3 is provided with a corrosion-resistant coating that also extends over a transition between the coupling element 2 and the component part 3. The coupling element 2 is received with its relatively slim shank 5 in a friction-locked manner and/or firmly bonded manner in the sealing region 12 of the connection opening 4 so that a medium from the flow channel through the passage opening 7 and cannot penetrate between the component part 3 and the coupling element 2. Thus, the coupling element 2 protects the component part 3 against corrosion. Thus, the invention is particularly advantageously suitable for use with pumps or pump housings, which form the component part 3.

(12) Component elements, such as, for example, a drain cock or a bleed screw, are connected to the head 6 of the coupling element 2, for example, are screwed into the head 6. The occurring torques are transmitted to the component part 3 through the form-locking connection between the head 6 and the head region 11 of the connection opening 4, wherein no inadmissibly high stresses are introduced into the coating 15. Damage to a surface of the coupling element 2 in the region of the internal geometry does not result in the occurrence of rusty spots since the coupling element 2 is made from a corrosion-resistant material. Rather, slight damage to the surface has no consequences. Detaching the component element is therefore possible without any problems even after a long period of time, and there is no concern for rust-induced seizing up.

(13) Apart from the component part, the component elements can, of course, also comprise a coating.

(14) The connection system according to the invention provides a secure solution for establishing a detachable connection of a component element with a coated component part, wherein in particular a screw connection is also possible with higher torques and without damaging a coating. For this purpose, a coupling element is stationarily received and held in a connection opening of the component part by means of a combination of frictional and form-locking connections and a firmly-bonded connection. The shank of the coupling element provides here for securing the axial position by means of a frictional connection or a firmly-bonded connection and assumes the task of sealing, while transmitting torques takes place through the form-locking connection between the head and the head region.

(15) A polygonal geometry on the head prevents the head from rotating even in the case of high torques wherein, at the same time, screwing into a stable non-rusting metallic thread in the head of the coupling element is possible. Thus, screw connections on coated component parts such as, for example, pump housings can be reliably implemented, wherein torques no to a maximum of 120 Nm can also be introduced without any risk. There is no concern for a malfunction of the coating caused by an excessively high.

(16) Since the coupling element is made from a rustproof material, there is no concern for rusting, not even over a period of several years.

(17) The invention is not limited to any one of the above-described embodiments, but can be modified in many different ways.

(18) All features and advantages, including constructional details, spatial arrangements and method steps, arising from the description, in themselves and also in many different combinations, can be essential for the invention.

REFERENCE LIST

(19) 1 Connection system

(20) 2 Coupling element

(21) 3 Component part

(22) 4 Connection opening

(23) 5 Shank

(24) 6 Head

(25) 7 Passage opening

(26) 8 Front side

(27) 9 Front side

(28) 10 Internal thread

(29) 11 Head region

(30) 12 Sealing region

(31) 13 inner surface

(32) 14 Flow channel

(33) 15 Coating