DE1477238C - Thinning tool for T-shaped connection parts on pipelines - Google Patents

Description

The invention relates to a penetration tool, preferably for T-shaped connection parts Pipelines, consisting of a hollow body that can be connected to the pipeline to be tapped, the has a threaded hole directed towards the pipeline and at its upper end a base for the Has approach of a socket wrench with which a means of an external thread in the threaded hole of the hollow body screwed penetration body can be set in rotation, the one carries tubular end portion, on the end face in a plane perpendicular to the tool axis Cutting edges are arranged, in his of his from the plane of the cutting edges cavity running inside the cut-out obtained when penetrating through the pipe wall Pipe wall piece can be received.

In a known penetration tool of this type (US Pat. No. 2,990,731) is the tubular end portion is cylindrical and consists of hardened material. Once in the wall of the pipe to be bored a hole is drilled by means of the tubular end portion, the falls cut pipe section into the tapped pipeline and cannot use the penetration tool pulled out of the pipeline.

Furthermore, a penetration tool has become known (US Pat. No. 2,950,637), at which the penetration body provided there is cylindrical in its front end section and is made of solid material. The cutting action is with this penetrating tool achieved by the beveled end face of the penetrating body. Because the penetrating body but is not hollow, the section cut out of the pipeline to be tapped from Penetration tool are not included.

Another known penetration tool (German Patent 293 770) which is intended to do so is to cut a section out of the wall of a pipe that is not under pressure, the section cut out of the pipeline to be tapped becomes by spring force held in the penetration tool. However, this tool is not a penetration tool, which is only intended for single use, which is the T-shaped one The connector remains after the wall section has been cut out of the pipeline to be tapped Rather, it is usually one for drilling into pipelines used special drill, in which the cut out wall section in the tool is held so that it cannot fall into the pipeline.

Furthermore, it has already been proposed (German Auslegeschrift 1 087 850) for. Holding on to the cut out Section "in the end section of the penetration body is designed as a head cutter End portion to be provided with an internal thread, the pitch of which with that of the thread on Penetration body: corresponds. This will keep the cut out Wall section ensured, but this device has the disadvantage that a high torque is required and that a relatively large amount of chips are generated which fall into the pipe interior be able.

About the falling of what has been cut out

To prevent wall section in the pipeline to be tapped, has also been proposed (German Patent 887 594), the one used to cut out the wall section To provide hole milling cutter with a magnetic holding device for the cut-out wall section. Equipping the penetration tool in this way is, however, complicated and expensive the tool.

Furthermore, a drilling tool has become known (US Pat. No. 2 606 615), which is used to produce of holes in lightweight panels, especially in panels that are used as wall or ceiling covering to create good acoustics. This tool has a tubular penetration body, the outer part of which is conical in this way, that it tapers downwards, the axis of the cone at an angle to the axis of the tubular Penetration body lies. The end of the penetration body is with respect to his Axis bevelled so that the cutting edge has an oval shape. ■

The invention is based on the object of a penetrating tool intended for single use of the type mentioned at the outset, in which only for cutting out a wall section from the pipeline to be tapped a small torque is required and which has a better cutting efficiency than the known ones Penetration tools. The wall section cut out of the pipeline to be tapped should be done by the penetration tool, which is used to connect side lines used on pipelines under pressure.

According to the invention, this object is achieved in the case of a penetration tool as mentioned at the beginning This type is solved in that the tubular end section is 4P as in the case of penetration tools can be tapered on the outside in the axial direction towards the plane in which the cutting edges are located, that the end portion perpendicular to the tool axis has a non-circular cross-section, and that it is made of a material that is pushed forward on its tubular wall by the exerted lateral pressure is plastically deformed.

If the penetration body in the penetration tool according to the invention in the direction of the If the wall of the pipeline to be tapped is screwed, those cutting edges begin first to penetrate "the pipe wall, which happens to be the first to hit the wall First, all cutting edges run in the track given to them by their spacing, whereby a relatively wide scraping zone is created, which is always penetrates further into the wall of the pipeline to be tapped. The ones that are further apart Cutting edges bend inwards in that the entire penetration section as a result of 6p the conical curvature of the outer wall of the tubular: end section when penetrating into the Wall of the pipeline is pressed inward. The outer cutting edges move inside the wide scraping zone, following the law of least resistance, inwards until it finally lie with the inner cutting edges essentially on a circle. In the proposed according to the invention So penetrating tool becomes less of a real cutting action than rather one Grinding or scraping effect achieved, with the material removal angularly between the large and the minor axis of the tubular end portion occurs.

With the new penetration tool, the cut-out part is held in place by that the penetration body is permanently and plastically deformed. Because of the non-circular shape of the tubular end section is required for cutting out the wall section Reduced torque, as a scraping effect due to this special shape of the end section is generated, which requires less torque than a pure cutting action.

The material from which the penetration tool is made is in spite of the invention intended plastic deformability is still much harder than the material to be tapped Pipeline, however, the penetration section and the cutting edges when penetrating of the tool in the wall of the pipeline permanently and plastically deform in such a way that it lie around the cut-out wall section of the pipeline to be tapped.

According to a preferred embodiment of the invention it is provided that the non-circular Cross-section is an oval.

Furthermore, it is recommended that the cutting edges, as is known with penetration tools, can be generated by notches and their number is more than two.

Another embodiment of the penetration tool according to the invention is characterized by this from that the cavity forming the recording is filled with lubricant and connected to the outer wall of the The end section is connected by a channel. In this penetration tool, the lubricant squeezed out at the beginning of the cutting process by the contactors existing between the cutting edges. At the same time, some of the lubricant can be pressed out through the channel,

A cutting edge is preferably located on both sides of a notch, all cutting edges having a bevel in the circumferential direction in the plane containing the cutting edges, through which the cutting edge sections lying on the tubular inner wall of the end section form the cutting edge sections lying furthest forward in the direction of rotation. It is recommended that the notches at the ends of the smaller and larger main axes; . the oval or lie ejelipsenförmigen _{cross-section;} ; ,.-._ ■■■

Is there the; The above-mentioned channel is arranged along the minor main axis, so in the course of ' of the cutting process, during which: the slots or notches close and the Lubricant only gets to the outside through the channel, on the outside there is always enough space available for receiving the pressed-out lubricant. The lubricant is pressed out in that the cutout from the pipeline assumes a piston-like function. If the channel were not provided, so the cut-out wall section could not get into the bore of the tool.

The penetration provided according to the invention

transmission tool can with extremely low torque be operated. The wall section cut out of the pipeline to be tapped has an edge approach which is not larger in diameter than the diameter of the bore of the to be connected pipe. Since the cutout is captured in the penetration tool, it can be pulled out of the opening made in the wall of the pipeline to be tapped. Due to the oval shape, the deformation properties of the end portion of the penetration tool forming material and due to the formation of the cutting edges takes place final Deformation of the tubular end portion approximated when the cutout is made and fixed is received in the hollow end of the penetration tool. This is due to the shape of the manufactured Cutout an inevitable mechanical interlock between the cutting edges and the Section ensured.

There is an essential advantage of the penetration tool proposed according to the invention in that when tapping the pipe on its outer wall a narrow degree in the form of a truncated cone is formed. This degree acts as a conical shoulder of the tool a kind of valve seat if the penetrating tool is left in place and the one in the pipeline should close the opening produced.

Further features and advantages of the invention emerge from the claims and from the following Description in which an exemplary embodiment is explained in detail with reference to the drawing. It shows

F i g. 1 shows a cross section through a T-shaped connection piece according to the invention,

F i g. 2 shows the partially cut tool in an enlarged view,

F i g. 3 is an end view of the upper part of the tool for receiving a socket wrench,

F i g. 4 is an end view of the penetration portion of the tool;

5 shows a section through the tool in the area of the lubrication channel along the section line 5-5 in Fig. 2,

6 is an enlarged longitudinal section through the penetration end portion, with one of the notches is shown, through which the cutting edges arise,

F i g. 7 is a side view of the penetration end; whereby one recognizes the emergence of the cutting edges ...: ■■

F g. Figure 8 is a section through the piercing end after the pipeline has been pierced and shows how the cutout is held in the tool,

9 is an enlarged, exposed, end view the tapering of the cutting edges,

Fig. 10 is a section to show the lower end of the tool shortly before engagement in the Pipeline,

11 shows a section similar to FIG. 10, the represents the position of the tool with respect to the pipeline after the penetration process is complete is and

F i g. 12 shows a section through the pipeline after the tool has been removed.

In Fig. 1 shows a main gas line 10 with a bore 11 and with an outer surface 12. A T-shaped fitting T is attached to the outer surface 12 of the pipeline 10.

The connection T-piece consists of a main section 13, of which a lower extension 14 and an upper extension 15 go out. A lateral extension extends from the main section 13 to one side 16, which is usually referred to as the house connection.

The T-piece can be attached to the pipe 10 in any suitable manner. This is currently happening preferably by welding. For this purpose, the lower extension 14 is bevelled with a Edge 17 provided, which facilitates the production of the welded connection.

The lower extension 14 includes a threaded bore 18 which widens at 19 at the pipe-communicating end. The upper extension 15 also includes a threaded hole 20 which is aligned with the threaded hole 18 and is of the same diameter. A penetration tool A is shown in FIG. 1 screwed into the threaded hole 20. The external threads of the tool A can also come into engagement with the threaded bore 18 when the tool is moved downwards to pierce the pipeline.

The upper extension 15 is provided with an external thread at the point 21, onto which an end cap 22 is screwed after the pipeline has been tapped and the tool A is inserted into the position shown in FIG. 1 has been withdrawn.

The lateral extension 16 consists of a base 23 for receiving a house connection.

In Fig. 2 to 7, the tool A , which consists of a main body 24, is shown in detail. The main body 24 has an external thread 25 which cooperates with the threaded bores 18 and 20 of the T-shaped connector. The upper end of the main body 24 includes a hexagonal socket base 26 for receiving a socket wrench. With the cap 22 removed, a socket wrench can be inserted into the base 26 and the tool moved down the cooperating threads until it engages and penetrates the main gas line. *

An end section 27 is located at the end of the tool opposite the base 26 offset diameter, the transition between the main body 24 and the end section 27 is formed by a conical shoulder 28. the End section 27 contains a receptacle 29 which is tubular. However, the tube is not cylindrical, but has a non-circular, for example an oval cross-section through a smaller axis 30 and a larger axis 31 according to FIG. 5 is defined.

The tubular end portion 29 has a tapered outer wall 32, which at its free End merges into cutting edges 33. There are four such cutting edges 33 are provided by notches or depressions 34 arise, with a cutting edge on both sides of a notch 34 33 lies. From consideration of FIG. 9 it can be seen that each cutting edge 33 is beveled or inwardly running in, d. i.e. that the actual edge on the inside

side of the wall. The four notches 34 are preferably on the axes of the oval Cross-section defined ellipse. On the closed side of the receptacle 29 is a radially extending channel 36 is provided, the connection between the receptacle and the outer wall of the end portion 27 ensures. This channel 36 lies on the small semi-axis 30 of the ellipse.

The tool A is made of suitable tool steel with the required flexibility properties, the tubular end section at point 27 having such strength or flexibility that it deforms plastically during the cutting process and forms a frame around the cutout from the pipeline 10 according to FIG. 8 is cut out.

The receptacle 29 is filled with a lubricant whose viscosity is so great that it normally sticks in the recording. Although this lubricant is poured into the receptacle at any time this is preferably done from the outset during manufacture.

The application and mode of operation of the T-shaped connector with the cutting tool is shown in in the following way:

The T-piece is welded onto the pipe 10 at point 17 and the cap 22 is removed. A socket wrench is now inserted into the base 26 and the tool A rotated in such a way that it moves in the direction of the pipe 10. During the downward movement of the tool A , the thread 25 is screwed into the threaded hole 18. As the tool moves further, the cutting edges 33 engage the pipeline 10 and cut into it. In this process, the material flows and moves laterally outward as opposed to an inward radial deformation or displacement. As the cutting process continues, the tapered wall of the tubular end section 27 deforms and finally assumes an approximately circular cross section.

During the initial cutting process, lubricant is squeezed out of the notches 34, which reduces the friction during the cutting process.

The further the tool works its way into the pipeline, the more the notches 34 are closed. After the cutout has been cut out of the pipeline and pressed into the receptacle 29, the lubricant is enclosed and generates a back pressure which resists the entry of the cutout, which exerts a piston-like effect. However, this back pressure is eliminated or reduced by the channel 36, through which the lubricant continues to be squeezed out.
Due to the outwardly tapering surface 32 and the resilient property of the tool material, the cutting edges 33 are compressed, especially in the area of the larger semiaxis, with the result that the cutting edges enclose the cutout or receive it in a locked manner during the final stage of the cutting process. Due to the fact that only a little metal of the pipeline has been pressed inwards, rather deformed outwards, the protruding lip, which inevitably arises at the cutout, can be kept at an absolute minimum and is no larger in diameter than the one in opening created in the pipeline. With the cutout held in the receptacle 29, the tool can be withdrawn by a rotary movement in the opposite direction, the cutout also being pulled out of the opening made in the pipeline.

The backward movement of the tool is continued until the position shown in FIG. 1 within the bore 20 is reached and the house connection is exposed. In this position, the tool A acts as a valve or closure for the bore 20. The cap 22 is then returned to the position shown in FIG. 1 position shown screwed on.

From Figs. 10, 11 and 12 it can be seen that on the outer wall of the pipeline 10 is a thin lip or a ridge 37 arises. This ridge 37 assumes the shape of a truncated cone. It is therefore special suitable opposite the conical shoulder 28 of the

Tool A to act as a 'kind of valve seat. The end section of the tool is often left in the opening produced for a certain period of protection, so that in this way a good seal is obtained against the escape of gas from the pipeline

is ensured. Once the ridge 37 has formed, a good seal needs to be achieved only a small torque to be applied to the tool.

1 sheet of drawings

209 528/81

Claims (7)

Patent claims: 1. Penetration tool, preferably for T-shaped connection parts on pipelines, consisting from a hollow body that can be connected to the pipeline to be tapped, the one for Pipeline has directed threaded hole and at its upper end a base for the Has approach of a socket wrench with which a means of an external thread in the threaded hole of the hollow body screwed penetration body can be set in rotation, which carries a tubular end portion, arranged on its end face in a plane perpendicular to the tool axis cutting edges in its cavity extending inward from the plane of the cutting edges the cut-out pipe wall piece obtained when penetrating through the pipe wall can be received is, characterized in that the tubular end portion (27) is known as in penetrating tools on the Outside in the axial direction towards the plane in which the cutting edges (33) are located, tapers that the end section (27) has a non-circular cross-section perpendicular to the tool axis, and that it is made of a material which, when pushed forward on its tubular wall exerted lateral pressure plastically deformed. 2. penetration tool according to claim 1, characterized in that the non-circular Cross-section is an oval. 3. Penetration tool according to claim 1 or 2, characterized in that the cutting edges (33), as in penetrating tools known, can be generated by notches (34) and their number is more than two. 4. penetration tool according to claim 1 to 3, characterized in that the recording forming cavity filled with lubricant and connected to the outer wall of the end section connected by a channel (36). 5. penetration tool according to claims 2 to 4, characterized in that to both Side of a notch (34) is a cutting edge (33), and that all cutting edges in the circumferential direction in the plane containing the cutting edges. one . Bevel, possess, through which the cutting, Edge sections form the cutting edge sections which are furthest forward in the direction of rotation. 6. penetration tool according to claim 3 to 4, characterized in that the notches (34) at the ends of the smaller and larger main axes (30, 31) of the oval or elliptical Cross-section lie. 7. penetration tool according to claim 4 to 6, characterized in that the channel (36) runs along the minor main axis (30).