ITMI950445A1 - CLAMP FOR FREEZER FOR PIPES - Google Patents

Abstract

The invention relates to a clamp for a tube freezer apparatus which can be used to repair non-emptied pipes of their liquid content. The clamps intended for this purpose are applied around the tube to be repaired and connected to a liquid carbon dioxide cylinder. Carbon dioxide, introduced into the space between the clamp and the tube, lowers the temperature of the liquid existing in the tube, which liquid freezes to form a plug. This allows you to repair or replace the tube without having to drain the liquid. The essential peculiarity of the inventive band consists in the fact that the band is made of elastomeric material, rather than thermoplastic material, in order to avoid that it becomes fragile at low temperatures caused by carbon dioxide and that, due to the high delivery pressure of this fluid shatters, projecting dangerous splinters for the repairer. (Figure 1).

Description

DESCRIPTION

The invention relates to a clamp conforming to the preamble of claim 1 for a tube freezer.

The clamps of this type are used to be able to carry out repairs on pipes that are not emptied. The clamp is applied around the pipe to be repaired and connected to a carbon dioxide cylinder. Through the arrival duct, the liquid carbon dioxide is introduced into the space between the clamp and the tube, so that the liquid contained in the tube freezes forming a plug. The tube can then be repaired or replaced without having to be emptied. It always happens that liquid carbon dioxide is introduced at too high a pressure in the space between the clamp and the pipe, so the clamp, which is made of thermoplastic material, breaks and falls apart. This poses a great danger of injury to the person carrying out the repair.

The invention aims to produce clamps of the type indicated in such a way that, even with the supply of the refrigerant fluid at rather high pressures, the clamp is safely prevented from falling apart.

According to the invention, in the inventive band said object is achieved with the qualifying characteristics of claim 1.

Since in the inventive clamp the lower part and the upper part are made at least partially of elastomeric material, it is very simply prevented that the clamp from breaking and falling apart due to too high pressure when the coolant fluid is added. The elastomeric material can absorb the high pressure of the refrigerant fluid by means of adequate deformation thus preventing the upper and lower parts, subjected to high pressure and low temperatures, from shattering into many pieces. In this way, the person carrying out the repair is reliably protected against injury.

Further features of the invention can be seen from the further claims, the description and the drawings.

The invention is illustrated in detail on the basis of an example of realization represented in the drawings, in which:

fig. 1 is a bottom view of the lower part of a clamp according to the invention, fig 2 is a section taken along the line I-I of fig. 1,

fig. 3 is a section taken along the line II-II of fig. 2,

fig. 4 is a side view of the lower part of fig. 1,

fig. 5 is a top view of a top part of the inventive band,

fig. 6 is a section taken along the line VI-VI of fig. 5,

la, fig. 7 is a section taken along the line VI-VI of fig. 6,

fig. 8 is a side view of the upper part of FIG. 5,

fig. 9 coaming, in longitudinal section and in the assembled state, the lower part and the upper part of the inventive band.

In the field of heating systems, it is known the practice of locally freezing the water found in the heating pipes in case of repair work. For this purpose, the clamp is applied around the given heating pipe and the gap between the clamp and the heating pipe is cooled with liquid carbon dioxide. Then, the water found in this section of the heating pipe freezes and forms a plug. In this way, it is possible to detach the heating pipe located in this area to insert e.g. a new section of pipe and weld it on site. Then the clamp is removed from the tube so that the water cap can thaw.

The clamp is made up of two parts to be connected to each other in a removable way, namely a lower part 1 (figures 1 to 4) and an upper part 2 (figures 5 to 8). The lower part has a base body 3, which body has an approximately semicircular section and an edge 4 located above the other edge 5 (fig. 2). The two edges 4, 5 have a straight course along their entire length. The base body 3, partially cylindrical and preferably semi-cylindrical, is provided at both ends with an edge 6, 7 perpendicular to it and advantageously has a constant height along its entire length. With these edges 6, 7 facing in the direction of the curvature axis of the base body 3, in the working position the lower part 1 rests on the tube. In this way, the bottom 8 of the base body 3 which faces the tube is spaced from the tube.

The base body 3 has a slat 9 provided on the edge 5, which slat extends outwards and has a width smaller than the width of the base body 3 (fig. 1) and in which slat there is an introduction opening 10 for a threaded pin (not shown) or for a screw which, in cooperation with a nut screwed on it, joins the lower part 1 to the upper part 2. On its side away from the edge 5, the introduction opening 10 is provided of an enlargement 11 in which the head of the screw or of the threaded pin is blinded.

On its external face, the base body 3 has, on the opposite side, a further batten 12 located at the height of the batten 9 and spaced from the edge 4. It is also narrower than the base body 3 (fig. 1) and has an opening of introduction 13 with a cavity 14.

The two slats 9, 12 are connected to each other by two reinforcing ribs 15 and 16, which run outside the base body 3 and are parallel to each other (fig. 1). The two reinforcing ribs 15, 16 are perpendicular to the base body 3, so that they provide a high moment of resistance against bending. The reinforcing ribs 15, 16 are located, as illustrated in fig. 1, at the height of the lateral edges 17,18 and 19,20 of the ribs 9 and 12. The reinforcing ribs 15, 16 have their maximum height (fig. 2) approximately at the height of the transition from the ribs 9, 12 to the base body 3, whereby in this critical area the slats are stiffened in an optimal manner. Therefore there is no danger that the slats may slightly bend relative to the base body 3.

Approximately at the height of the lower face of the slat 9 presenting the cavity 11, the inner face Θ of the base body 3 is provided with a step 22 which extends between the two edges 6 and 7 of the base body 3. It serves, in such a way that will be explained later, from the support surface for the upper part 2.

The upper part 2 also has a partially cylindrical base body 23 extending, like the base body 3, over about 180 °. The one edge 24 of the base body 23 is surmounted by the opposite edge 25. The two edges 24, 25 have, like the edges 4, 5. flat configuration. The base body 23 is limited axially by edges 26 and 27, which advantageously have the same height along their length and extend to the edges 24, 25 (Figures 6 and 7). The edges 26, 27 are perpendicular to the internal side 28 of the base body 23. With the clamp mounted, the upper part 2 rests on the tube with the edges 26, 27. In this way, between the internal face 28 of the base body 23 and the tube of heating, a cylindrical interspace is formed into which carbon dioxide can be introduced. Moreover, with said edges 26, 27 and also with the edges 6, 7 of the lower part, it is possible to obtain an axial limitation of the space existing between the base body 3, 23 and the heating tube.

On the external face of the base body 23, at the height of the edge 24, a stick 29 is provided which has an introduction opening 30 with an enlarged cavity 31 in the lower part.

Spaced from the opposite edge 25 of the base body, a further stick 32 protrudes on the external face of the same, which is at the height of the stick 29 and which in turn has an introduction opening 33 with an enlarged cavity on the lower face. 34. The ribs 29, 32 of the upper face 2 are formed in the same way as the ribs 9, 12 of the lower face 1. Since all the ribs have the cavities 11, 14, 31, 34, the heads of the threaded pins or screws as the nuts can also be blindly arranged in these cavities. Advantageously, the cavities 11, 14, 31, 34 are polygonal openings (Figures 1 and 5), whereby e.g. the head of the threaded pin or screw or the nut can have a corresponding polygonal profile. In this way, a simple anti-torsion security is obtained on the tube when the clamp is locked.

The two slats 29, 32 are connected to each other by two reinforcing ribs 35, 36 extending perpendicularly to the external face of the base body 3 and parallel to each other (fig. 5). The two reinforcing ribs 35, 36 are located at the height of the lateral edges 37, 38 and 39, 40 of the two ribs 29, 32. As can be seen from figure 6, the reinforcing ribs 35, 36 have their maximum height at approximately at the height of the transition from the slats 29, 32 to the base body 23. In this way, the slats 29, 32 are supported in such a way that there is no danger of them bending inadmissibly towards the base body 23. The body base 23 has, half of its width and half of its length, a cylindrical attachment piece 41, which protrudes outwards and on which a conduit (not shown) can be applied by means of which the clamp can be connected to a CO2 cylinder ■ Through this duct and through the connecting piece 41, the liquid carbon dioxide is introduced into the intermediate space between the clamp and the pipe. The attachment piece 41 is located in the area between the two stiffening ribs 35, 36 and protrudes from these towards the outside.

At the height of the lower side 42 of the slat 29 which is provided with the cavity 31, the internal wall 28 of the base body 23 has a step 43 (Figures 6 and 7) extending between the two edges 26 and 27 of the base body, with the band mounted , the step 43 constitutes a flat support surface for the lower part 2.

Since the two parts 1, 2 can be completely detached from each other, they can be easily applied around the tube. The lower part 1, with its coupling piece 44 having the protruding edge 4, is engaged in the upper part 2 so that the edge 4 of the lower part 1 abuts against the step 43 of the upper part 2 (Figure 9 ). Similarly, the coupling piece 45 of the upper part 2 (Fig. 6), which is equipped with the edge 25, then projects towards the lower part 1 so that the edge 25 rests on the step 22 (figures 2 and 3) of the lower part. Then the two parts 1, 2 are locked against each other by means of threaded pins (or screws) and nuts, which are introduced through the corresponding ribs 9, 12, 29, 32. Since the ribs are supported by the reinforcement ribs 15, 16, 35, 36, the two parts 1, 2 are clamped against the tube at the respective peripheries with the edges 6, 7, 26, 27. The coupling pieces 44, 45 are formed so as to abut on the support surface 48, 49 and then on the step 22, 43, of the respective parts 1, 2. It is thus ensured that the liquid carbon dioxide flowing into the annular space between the base bodies 3, 23 and the heating tube can escape only to a modest extent towards the outside. In this way, the liquid in the tube can freeze safely and quickly, so that the repair can be carried out effortlessly on the un-emptied tube.

The lower part 1 and the upper part 2 are advantageously produced in one piece elastomeric material. The term elastomeric material refers to both plastic and rubber materials. As plastic materials, PA 12 copolymers, polyamides of block ether (PEBA) and the like and thermoplastic elastomers of poly (ether) -ester known for example are advantageously available. under the trade names Riteflex, Pipiflex and the like.

If liquid carbon dioxide is introduced with excessive pressure into the annular space between the clamp and the tube, the elastomeric material can yield due to elastic deformation, so there is no danger that the clamp will shatter.

To prevent the clamp from falling apart at low temperatures and at a high pressure of the carbon dioxide to be delivered, the clamp can also be made of elastic material only on the external side or it can be equipped with a coating of elastomeric material, while the the rest of the lower part 1 and the upper part 2 can be made of harder material, such as e.g. a thermoplastic resin or a duroplast. The elastomeric material surrounding this harder material prevents parts of the band made of harder material from falling apart.

However, it is also possible to insert as an elastomeric material, in the lower part 1 and in the upper part 2, at least one elastically yielding protective element such as e.g. a fabric, a net or the like. In this case, the lower part 1 and the upper part 2 are made of a rather hard material. If the pressure of the carbon dioxide to be introduced is too high, the clamp - thanks to the protective element - does not fall apart but the protective element expands appropriately. In particular, when the protection is made as a fabric or as a net, an intimate union can be obtained between said protective element and the remaining material, whereby a high degree of safety against shattering is ensured.

The fabric or mesh can be made of textile material, tear-resistant plastic material or even metal material embedded in the lower part 1 or in the upper part 2,

As an elastomeric material, it is also possible to use embedded threads made of tear-resistant plastic or metal and advantageously extending in the direction of the periphery of the base body 3, 23.

Finally, it is also possible to make the lower part and the upper part 2 in elastomer and rubber. With an appropriate mixture of these components it is possible to obtain an excellent adaptation to the case of use that arises from time to time.

Claims (12)

R IV EN D IC A T IO N I 1. Clamp for a freezer appliance for pipes having a lower part and an upper part connected together by means of at least one supporting element and of which at least one has an attachment for a duct which serves for the supply of a refrigerant fluid, preferably carbon dioxide liquid, characterized in that the lower part (1) and the upper part (2) are made, at least partially, of an elastomeric material. 2. Clamp according to claim 1, characterized in that the lower part (1) and the upper part (2) are made entirely of elastomeric material. Band according to claim 1 or 2, characterized in that the elastomeric material is an elastomer. Clamp according to one of claims 1 to 3, characterized in that the elastomeric material is a thermoplast-elastomeric polyamide. Clamp according to one of claims 1 to 3, characterized in that the elastomeric material is a poly (ether) ester thermoplastic elastomer. 6. Clamp according to claim 1 or 2. characterized in that the elastomeric material is rubber. Clamp according to one of claims 1 to 6, characterized in that the lower part (1) and the upper part (2) are made of elastomer and rubber. 8. Clamp according to claim 1, characterized in that the lower part (1) and the upper part (2) have a coating of elastomeric material. Strap according to claim 1, characterized in that in the lower part (1) and in the upper part (2) a fabric or a net or the like is embedded as an elastomeric material. 10. Band according to claim 9, characterized in that the fabric is made of textile material. Strap according to claim 9, characterized in that the fabric is made of an artificial tear-resistant material. 12. Band according to claim 9, characterized in that the fabric is made of metallic material.