IE840126L

IE840126L - Complex salt

Info

Publication number: IE840126L
Application number: IE840126A
Authority: IE
Original assignee: Schering Ag
Priority date: 1983-01-21
Filing date: 1984-01-20
Publication date: 1984-07-21
Also published as: GB8529903D0; ATA19184A; IT1213128B; LU85177A1; IL70711A; CH660183A5; DK25484D0; FR2590484A1; JP2556627B2; AU1018488A; FR2590484B1; IE56855B1; JPH04217927A; SE8400254L; DE3401052A1; IE890169L; AU574658B2; ES8504668A1; FI79026B; SE8400254D0

Abstract

A diagnostic preparation useful in a method of diagnosis using NMR, X-ray and ultra-sound, comprises (i) a physiologically tolerable complex salt which contains (a) a central element selected from elements having atomic numbers of from 21 to 29, 42, 44 and from 57 to 83, and (b) a radical of a physiologically-tolerable complex-forming acid and, if desired, (c) a radial selected from radicals of inorganic and organic bases and amino acids, and (ii) a physiologically tolerable carrier.The salts are claimed perse and may contain e.g. methylenephosphonic acid or aminoacetic acid type complexing acids. Metal complexes of monoclonal antibodies coupled with DTPA and CDTA are also prepared (Example 55). [GB2137612A]

Description

8 8 5 5 - 1 - THE INVENTION relates to a method of producing a union for the flow and return pipes of panel radiators, the union comprising a substantially spherical hollow body having a pipe connection sleeve which merges into the * 5 interior of the hollow body, the same being formed perpendicularly to such sleeve with a connection aperture for the radiator.

A wide variety of angle unions for this purpose are 10 known. Since in practice they are required in very large numbers, thsy are definitely mass-produced articles. The basic trend with mass-produced articles is to keep the cost per unit very low by using as little material as possible and by making the production method as simple as 15 possible.

Because of the consistent operation of such unions, there are relatively narrow limits to their construction.

The main consideration is therefore less their external 20 appearance than the method of their production.

A known production method comprises the following steps: 25 (a) Upsetting a tubular member in a mould to form a hollow-body part merging into a neck part centred on a longitudinal axis of the tubular member, the » hollow-body part having an aperture, centred on said longitudinal axis, at the end of the upset -2- tubular member remote from the neck part; (b) Welding on a sheet-metal round to close said aperture in the hoilow-body part which is remote 5 from the neck part, and (c) Forming the pipe connection sleeve and contriving a bore in the hollow-body part. 10 Such a method is herein referred to as being "of the kind specified".

In a known method of the kind specified, after the round has been welded on to close one opening of the 15 hollow-body part, a prefabricated pipe-connection sleeve Is ueldsd onto the hollow-body part so that said sleeve extends perpendicular to the longitudinal axis of the upset tubular member. That part of the hollow-body part which Is encircled by the end of said sleeve which is 20 welded to the hollow body part is then drilled through so that the bore thus formed in the wall of the hollow body member forms a continuation of the interior surface of said sleeve. Said bore and the interior of the sleeve are then formed with an internal screwthread. The neck 25 part of this union is relatively short and forms the opening for the connection of the radiator. The welded-on round, which enables the overall height of the union to be relatively reduced, is operative in the subsequent fitting of the union to the radiator as an abutment 30 surface for a press-welding electrode.

This known method of producing angle unions of the kind specified is elaborate because the pipe connection sleeve must be prefabricated in a separate operation, 35 then welded to the hollow body part. Separate pre-fabrication and more particularly the welding of the sleeve are relatively costly. In the known method the -2a- 10 wall of the hollow body must then be drilled through in the zone surrounded by the welded-on sleeve, which causes additional difficulty.

It is an object of the invention so to develop a method of the kind specified that not only are at least some of the steps of the method simplified but also fewer steps are necessary overall while consumption of material is much reduced.

According to the invention, there is provided a method of producing a union for the flow and return pipes of panel radiators, the union comprising a substantially spherical hollow body having a pipe connection sleeve 15 which merges into the interior of the hollow body, the same being formed perpendicularly to such sleeve with a connection aperture for the radiator, the method comprising the steps of: 20 (a; upsetting a tubular member in a mould to form a hollow-body part merging Into a neck part; (b) uelding on a sheet-metal round to close that aperture in the hollow-body part which is remote from the neck part, and 25 (c) forming the pipe connection sleeve and contriving a bore in the hollow-body part, u I -3- ond wherein the neck part is the pipe connection sleeve and the bore in the hollow-body port is the opening for connection of the radiator.

Whereas in the known method the relatively short neck part will 5 subsequently be the opening for the connection of the radiator, in the method according to the invention the neck part is used to form the pipe connection sleeve. The advantage is that not only is prefabrication of a separate sleeve for each union eliminated but also the very time-consuming and expensive step of welding the sleeve to the hollow-body part is 10 eliminated. Whereas in the known method the hollow-body part must be drilled in the zone of the welded-on sleeve, in the method according to the invention the hollow-body part can be drilled at an exposed place relatively cheaply. 15 The method is greatly simplified because only a single part in addition to the metal round is processed throughout the complete procedure.

In a further development of the invention, to form the electrode engagement surface known in connection with such unions the hollow-body 20 part is faceted by a stamping step on the side opposite the place intended for the radiator connection aperture. Whereas in the union produced by the known method the metal round forms the engagement surface for the welding electrode, in the angle union produced by the preferred method embodying the invention such surface is embodied by the faceted or 25 flattened (lateral) part of the hollos-body part. Preferably, the faceting step is performed after the aperture in the upset tubular member has been closed by welding.

An embodiment of the invention is described below by way of 30 example with reference to the accompanying drawings wherein; FIGURE I is a sectioned view through part of a panel radiator with an angle union secured to if; 35 FIGURE 2 is a diagrammatic plan view corresponding to Figure I, and FIGURES 3 to 8 are sectioned views of partly machined articles, the end product being the angle union shown in Figure 8. -k- Figure I shows a part of a panel radiator P which is formed with a flow openinq ?.. Oiposed between the two poroltel panels of the radiator P neor tlw; openinq Z is f\ bearmq pnrt S which is of no further interest ;n the present connection and which is operative to prevent the two panels of the 5 radiator P being squeezed together.

An angle union 100 is press welded to opening Z, a centering collar of the port S extending through the opening Z into the union 100. 10 The union 100 has a pipe connection sleeve 2 formed with an internal screwthread 6. Opposite the sleeve 2, interior 4 of the hollow body is closed at the bottom by a base 3. On that side of the interior 4 which is opposite the opening Z the union 100 has a facet 5 whose exterior is engaged by an electrode for press welding. The other electrode is applied to the outside of 15 the radiator P opposite the face? 5.

On the side opposite the facet 5 the interior 4 is formed with a radiator connection opening 7 into which The centering collar of the part S extends. 20 Figure 2 is a plan view corresponding to Figure I. The sleeve 2 can, of course, extend downwardly or in some other direction from that shown.

A description will now be given with reference to Figures 3 to 8 of 25 the method of producing the union 100. First, a tubular member 10 of the required length is parted off from a tube. The member 10 is formed with a left opening 10a and a right opening 10b (Figure 3).

The elongated tubular member 10 is then upset in known manner by 30 means of a special mould so that it acquires the shape shown in Figure 4. The upset tubular member 20 which is shown in Figure k and in which there is a left opening 20a and a right opening 20b has a neck part 21, which widens near the left opening 20o, and a spherical hollow-body part 22. The upsetting step bevels the right opening 20b of the upset member 20 so that a 35 sheet metal round 3 shown in Figure 5 con readily be welded subsequently into the opening 20b, prefereobly by resistance welding, to close the opening.

The round 3 is virtually the only separate required for the production of the union in addition to the tubular member.

After the round 3 has been welded in, dished member 30 as shown in Figure 6 exists. On one side of the hollow-body part 22 a facet S is formed. The facet is contrived by stamping. The facet S is operative to receive a welding electrode in the subsequent step of welding the union to a radiator, for example, by resistance welding.

The inferior of the sleeve 2 is in known manner formed with an internal screwthread 6 (Figure 8). Also, that side of the hollow-body part 22 which is opposite the facet S is drilled and provided with bevelling to leave the radiator connection opening 7. The union 100 is than complete. - 6 -

Claims

CLAIMS:

1. A method of producing a union for the flow and return pipes of pane] radiators, the union comprising a substantially spherical hollow-body having a pipe 5 connection sleeve which merges into the interior of the hollow-body, the same being formed perpendicularly to such sleeve with a connection aperture for the radiator, the method comprising the steps of: (a) upsetting a tubular member in a mould to form a 1 q hollow-body part merging into a neck part; (b) welding on a sheet-metal round to close that aperture in the hollow-body part which is remote from the neck part, and (c) forming the pipe connection sleeve and contriving a 15 bore in the hollow-body part, and wherein the neck part is the pipe connection sleeve and the bore in the hollow-body part is the opening for connection of the radiator.

2. A method according to claim 1 wherein the neck part 20 is formed with an internal screw thread.

3. A method according to claim 1 in which the hollow-body part is faceted by a stamping step on the side opposite the place intended for the radiator connection aperture.

4. A method according to claim 2 in which the stamping step precedes the steps of forming the pipe connection sleeve and contriving said bore in the hollow~body part.

5. A method of producing a union, substantially as hereinbefore described with reference to the accompanying drawings.

6. A union produced by the method of any of claims 1 to 5. MACLACHLAN & DONALDSON, Applicants' Agents, 47 Merrion Square, DUBLIN 2.