WO2012025157A1 - Watering device having an elastically compressible body and method for producing same - Google Patents

Abstract

For a watering device, which contains at least one compressible compensating body as a freezing-protection device, the compressibility of the compensating body is determined by micro-sized hollow bodies, which are embedded into a carrier material and which have a flexible closed shell.

Description

 Irrigation device with elastically compressible body and method for its production.

The invention relates to an irrigation device with an elastically compressible body as an antifreeze device and to a method for producing a compressible body for an irrigation device.

In the case of irrigation systems, the problem is known that frost effects on irrigation devices which are completely or partially filled with water can be destroyed by the strong volume expansion during the transition from the liquid state to the ice housing of the irrigation device. As a countermeasure is particularly known to integrate compressible compensation body in the housing of such irrigation facilities. Such compressible compensating bodies are typically made of closed-cell foam made of an elastic material, which is compressed in the volumetric expansion of the water and thereby prevents an excessive increase in the internal pressure in the irrigation device. Designs are z. In US 7,278,625 or US 2007/06531 6 A1.

Practice shows that these foams over time with water soak and thus the volume reduction of the body compensation in the case of freezing is given only to a small extent and can no longer limit a pressure increase sufficient.

The invention has for its object to provide an irrigation device with at least one compressible body as the antifreeze device and a method for producing such a compressible body. Solutions according to the invention are described in the independent claims. The dependent claims contain advantageous refinements and developments of the invention.

It turns out, surprisingly, that an elastically compressed body used as antifreeze, hereinafter also referred to as a compensating body, includes a gas filling through the use of closed flexible casings, a high reversible compressibility combined with high long-term stability against the ingress of water into the hollow bodies has. Gas-filled micro hollow bodies, which typically have a spherical shape and are known under their English name microspheres, are in particular common as fillers in different applications. Deformable micro hollow bodies have a thin shell of a flexible material, which is typically a thermoplastic material. Manufactured from smaller microparticles containing a blowing agent within a closed jacket of thermoplastic material by heating the microparticles to an elevated temperature at which the thermoplastic softens and the blowing agent forms a gas which inflates the particles into the hollow bodies. Upon cooling, their shape is retained.

In the compensation body, the hollow microbodies are advantageously connected to one another by means of a further flexible, in particular an elastically deformable carrier material. The hollow microbodies can in particular be embedded in the carrier material, which essentially fills the spaces between the hollow microbodies. The hollow microbodies advantageously have a size distribution of the diameters with a ratio of the largest diameter to the smallest diameter of at least 2.0, as a result of which a particularly high proportion of the volume of the compensation body is determined by the microbeam. Hollow body can be taken, resulting in a particularly high degree of compressibility of the compensation body is given. The volume of gas accumulated over all micro hollow bodies, which due to the small wall thickness of the flexible casing can be approximately equated to the volume of the micro hollow bodies, is advantageously more than 50% of the volume of the compensating body in its uncompressed state. The hollow body is advantageously at pressures which are maximally tolerated by the protected housing of the irrigation device without damage and z. B. at 20 bar, compressible by at least 40% of its uncompressed volume.

The production of a compressible body to be used as antifreeze in an irrigation device is advantageously carried out by applying an elevated process temperature to a starting material which is a mixture of a thermoplastic carrier material and expandable microparticles. The increased process temperature is to be chosen so that the microparticles are inflated in the manner already described and generally known to the micro hollow bodies. The carrier material, which is preferably different from the thermoplastic material of the shell of the microcavities, is also in a plastic state at this elevated process temperature, which is typically between 120 ° C and 220 ° C. Expandable microparticles are available from different suppliers in different materials and sizes. The production of the compensation body can advantageously take place in a shaping tool which determines the shape of the compensation body.

The gas filling of the hollow microbodies is typically under a pressure which is increased in relation to the ambient pressure and which can advantageously be set by process parameters of the production process. In particular, In particular, an internal pressure of the Mikrohohlkorper can be adjusted, which is slightly higher than the water pressure in the regular operation of the irrigation device, so that at frequently changing pressure, such. B. on the pressure side of a frequently switched on and off garden pump or between a shut-off valve and an outlet nozzle of a garden spray in regular operation no compression of the compensation body occurs and fatigue in the thermoplastic material of the shells of Mikrohohlkorper is further prevented. The internal pressure of the Mikrohohlkorper but is much lower to choose than the maximum for the housing of the irrigation pressure permissible. For example, if the latter is 20 bar, the internal pressure of the micro-hollow bodies could advantageously be in the range of 5 bar.

The features mentioned above and the claims which can be taken from the images are advantageously realizable both individually and in various combinations. The invention is not limited to the exemplary embodiments described, but can be modified in many ways within the scope of expert knowledge.

Claims

claims:

1 . Irrigation device comprising at least one chamber adapted to receive water and at least one elastically compressible body containing gas inclusions and communicating in a water-conducting manner with water in the chamber, characterized in that the compressible body contains gas-filled hollow micro-bodies with a flexible closed shell.

2. Irrigation device according to claim 1, characterized in that the diameter of the micro hollow body is less than 0.1 mm.

3. Irrigation device according to claim 2, characterized in that more than half of the micro-hollow bodies have diameters of less than 0.05 mm.

4. Irrigation device according to one of claims 1 to 3, characterized in that the hollow microbodies are embedded in a flexible carrier material.

5. Irrigation device according to one of claims 1 to 4, characterized in that the gas pressure within the hollow body at the operating temperature of the irrigation device is higher than the ambient air pressure.

6. Irrigation device according to one of claims 1 to 5, characterized in that the cumulative gas volume of the micro hollow body makes up at least 50% of the volume of the compressible body.

7. Irrigation device according to one of claims 1 to 6, characterized in that the compressible body is compressible by at least 40% of its uncompressed volume.

8. A method for producing an elastically compressible body for an irrigation device according to claim 1 by means of a molding process carried out at elevated process temperature, wherein from a thermoplastic starting material, a body is generated with gas-filled cavities, wherein

a material mixture of a thermoplastic elastomer and of expandable microparticles is selected as the starting material,

the expandable microparticles within a jacket of a thermoplastic material contain a propellant which forms a gas at the elevated process temperature,

at the elevated process temperature, the expandable microparticles are expanded, under the effect of the gas pressure of the propellant, into gas-filled hollow micro-bodies with envelopes of thermoplastic material which are surrounded by the thermoplastic elastomer,

- The composed of the thermoplastic elastomer and the micro hollow body body is cooled.

9. The method according to claim 8, characterized in that the weight fraction of the microparticles in the starting material between 1% and 20%, in particular between 2.5% and 10% is selected.