NL1031712C2 - Formation of object made from ice, e.g. ice sculpture, involves passing water around coolant pipe arrangement with same shape as object - Google Patents

Abstract

A pipe arrangement (3) is configured to define the shape of the object (1) and then coolant is transported through the pipes whilst passing water around the arrangement so that ice becomes deposited around the pipes, forming the desired object. An independent claim is also included for the heat exchanger used to form the object, including either one film (5) which forms an enclosed volume around the pipes for the water to be passed around in, or a combination of a first film and a second film which form an enclosed volume around the pipes, the latter being located in the space between the two films.

Description

Method for manufacturing an object from ice, objects manufactured in this way and heat exchanger

The invention relates to a method for manufacturing an object from ice. It is customary to manufacture objects from ice by starting from a sufficiently large block of ice, parts of which are then removed until the object remains. In the method according to the invention, the object is synthesized around a system of 10 cooling pipes. To this end, the inventive method has the feature that a form of pipes is used to realize a shape that approaches the object at least substantially, after which a cooling medium is passed through the system of pipes and water is supplied around the system of pipes, the object being supplied by ice deposit around the system of pipes. This may involve relatively complex shapes, such as domes, caves, bridges and the like, but also relatively simple shapes such as a bar or seating furniture.

20

A favorable realization of the inventive method is characterized in that the system of pipes is arranged on a closed surface, whereby an ice surface with a predetermined surface structure can be obtained. It is thereby possible to design the closed surface in such a way that it can be removed after the object is ready. For example, a smooth or precisely worked ceiling in an ice cave can be realized. Moreover, the closed surface can serve as a support until the object is self-supporting.

A further favorable realization of the inventive method in which the closed surface also forms a support in a simple manner has the feature that the closed surface forms part of an inflatable structure and that the inflatable structure is inflated before water is passed around the system of pipes. . Once the object is self-supporting, the inflatable structure can easily be deflated and then removed. Preferably, however, the closed surface remains part of the ice object.

A further favorable realization of the inventive method in which the closed surface also forms a support in a simple manner and in which, moreover, the closed surface is obtained without water being wasted in this regard, is characterized in that the system of pipes is arranged between two closed surfaces. The two closed surfaces are preferably part of an inflatable structure, wherein the inflatable structure is inflated before water is passed between the two closed surfaces around the system of pipes. Also when this method is applied, the two closed surfaces remain part of the ice object, so that they are in fact integral with the ice object.

A further favorable realization is characterized in that the system of pipes is made of a flexible material, so that the system of pipes, together with a support, can be folded before it is packaged and / or transported.

According to a further aspect of the invention, a favorable embodiment has the feature that when the cooling medium is supplied under pressure, the system of pipes realizes a shape that at least substantially approximates the object, so that the system of pipes actually also forms a support.

3

A further favorable realization is characterized in that a tubular film is arranged around almost every pipe of the system of pipes, whereafter the tubular film is filled with water. Once this water has been frozen, an object is obtained that closely follows the shape and structure of the system.

A further favorable realization is characterized in that a diameter of the tubular foil is chosen such that tubular foils filled with water form a substantially closed surface. In this way an object can be obtained which on the one hand substantially follows the shape and structure of the system of pipes, the object moreover forming a closed surface. Use is herein preferably made of a tubular foil which is manufactured from an at least substantially transparent material, as a result of which it is incorporated substantially invisibly in the object.

The invention also relates to objects, such as a sculpture, ice cave, bar or furniture, at least partially manufactured with the method as described in the previous paragraphs.

In a favorable embodiment, the objects are characterized in that they are provided with a system of conduits filled with a cooling liquid, connected to a cooling machine, so that they can also be maintained for a long time even at a relatively high ambient temperature.

In a favorable alternative embodiment, the objects are characterized in that they are provided with a system of pipes filled with a cooling liquid, connected to a heat exchanger arranged in the outside air. This 4 embodiment can only be used if the outside air has a temperature that is considerably lower than 273 K. It is then even possible to insert into an igloo or ice cave, for example, so that within a pleasant temperature 5 can be realized, while the object still remains can be maintained for a long time.

The invention also relates to a heat exchanger, comprising a system of pipes through which a cooling medium or a heating medium is passed and a volume placed around and / or within this system of pipes through which a second medium is passed. The inventive heat exchanger is characterized in that the volume comprises a surface made of at least substantially closed surface within which or why the system of pipes is placed or that the volume comprises a first and a second surface made of film made of substantially closed surface, the first surface the second surface comprises at least substantially and wherein the system of pipes is placed between the first and the second surface. The heat exchanger is preferably provided with means for inflating the volume and the system of pipes is made of a flexible material, so that the heat exchanger can be easily set up and broken down again.

A favorable embodiment has the feature that the heat exchanger is adapted to recover water from the ambient air.

30

The invention will now be further elucidated with reference to the following figures, wherein:

FIG. 1 schematically represents a method for manufacturing an igloo in perspective; 5

FIG. 2 schematically represents a method for manufacturing an object from ice;

FIG. 3 schematically represents an alternative method for manufacturing an object from ice; FIG. 4 schematically represents an alternative method for manufacturing an object from ice; FIG. 5 schematically represents a method for manufacturing an ice bar in perspective;

FIG. 6 schematically represents a possible embodiment of a heat exchanger according to the invention.

FIG. 1 schematically shows a method for manufacturing an igloo 1 in perspective. The shape of igloo 1 is predetermined with the aid of a construction 2 of, for example, metal or metal mesh, which is easy to process and which supports the emerging igloo in an initial phase. A system of conduits 3 is attached to this construction 2 with binding wire, such that the entire outer surface of igloo 1 is covered, with the exception of a door opening not further shown. The system of pipes 3 is now connected to a cooling installation 4 known in the art, which pumps, for example, a cooled glycol mixture through the system of pipes 3. The system of pipes 3 can now be watered, or water sprayed, or water vapor present in the atmosphere allowed to grow, until igloo 1 is realized with such a thickness that the ice formed is self-supporting. Subsequently, structure 2 can be removed or made virtually invisible by also spraying water on the inside of igloo 1 until the formed ice layer conceals construction 2 from view. A plastic foil 5 can also be provided between structure 2 and the system of conduits 3, as a result of which structure 2 can be easily removed and subsequently, if desired, plastic foil 5 can be removed. Furthermore, plastic film 5 can be designed in such a way that an inflatable object is obtained which approximates the shape of igloo 1. The system of pipes can then be attached to this plastic foil 5, for example with self-adhesive tape, so that construction 2 is no longer needed.

The system of pipes 3 can now be watered or water sprayed until igloo 1 is realized with a thickness such that the ice formed is self-supporting. Once igloo 1 is standing and if the outside temperature is sufficiently low, if desired, cooling installation 4 can be replaced by a heat exchanger arranged in the outside air, which dissipates heat produced in the igloo. It is then even possible to burn in the igloo, such that a pleasant temperature can be achieved.

FIG. 2 schematically shows a method for manufacturing an object 6 from ice. The shape of object 6 is predetermined with the aid of an inflatable structure 7, for example manufactured from plastic, such as polyethylene foil or from rubber. A system of conduits 3 is arranged around inflatable structure 7, such that the entire outer surface of inflatable structure 7 is covered, possibly with the exception of openings not further shown. The system of pipes 3 is now connected to a cooling installation known in the art, which is not further shown, which pumps, for example, a cooled glycol mixture through the system of pipes 3. The system of pipes 3 can now be watered, or water sprayed, or water vapor present in the atmosphere allowed to grow, until object 6 is realized with a thickness such that the ice formed is self-supporting. Inflatable structure 7 can then be removed if desired or made virtually invisible by also spraying water on the inside of object 6 until the formed ice layer conceals inflatable structure 7 from view.

35 7

FIG. 3 schematically shows an alternative method for manufacturing an object 6 from ice. The shape of object 6 is predetermined with the aid of a structure consisting of two layers 7a, 7b, for example manufactured from plastic, such as polyethylene foil or from rubber. A system of flexible conduits 3 is provided between layers 7a, 7b. The space comprised by layer 7a is then inflated, while the space between layers 7a, 7b is filled with water. The system of flexible conduits 3 is now connected to a cooling installation known in the art, not further shown, which pumps, for example, a cooled glycol mixture through the system of conduits 3. Subsequently, the air from the space covered by layer 7a can be drained away. The shape of object 6 can also be realized by filling the system of flexible pipes 3 with a cooled glycol mixture with a sufficiently high pressure, as a result of which the system of flexible pipes 3 forms, as it were, a skeleton between layers 7a, 7b, whereafter fills the space between layers 7a, 7b with water. If one wants to dismantle object 6, for example because an event where object 6 played a role has ended, the ice is melted and any glycol mixture still present in the system of pipes 3 is removed, whereafter layers 7a, 7b together with the system of conduits 3 can be folded and discharged. If desired, to accelerate the melting of the ice, a heated medium can be passed through the system of pipes 3.

FIG. 4 schematically shows an alternative method for manufacturing an object 8 from ice. The shape of object 8 is predetermined with the aid of a cantilevered system of conduits 3, optionally provided with some support 9 to which individual conduits of the system of conduits 3 can be tied to keep, for example, mutual distances between individual 8 conduits. A sleeve 10 is made around each pipe of the system of pipes 3, made of, for example, plastic foil, which is then filled with water. The system of pipes 3 is now connected to a cooling installation known in the art, not further shown, which pumps, for example, a cooled glycol mixture through the system of pipes 3. In this case, the water freezes in sleeves 10. Preferably, the distance between individual pipes of the system 10 of pipes 3 is chosen such that adjacent sleeves 10 touch each other, so that a substantially closed surface is obtained. Water can then be sprayed on the outer surface and on the inner surface of this closed surface to cover cuffs 10, whereafter object 8 is realized in ice.

FIG. 5 schematically represents a method for manufacturing an ice bar 11 in perspective. For example, an object is molded from wood and board that approximates the shape of the ice bar 11 to be produced. This mold is covered with plastic foil and on the front surface 12, the top surface 13 and the side surfaces 14a, 14b a system of pipes 3 is fixed through which a cooled glycol mixture is pumped. Water is then spread on front surface 12, top surface 13 and side surfaces 14a, 14b until ice bar 11 is realized. Even at relatively high temperatures, the ice bar can easily be preserved by pumping a cooled glycol mixture through the system of pipes 3.

30

FIG. 6 schematically shows a possible embodiment of a heat exchanger 15 according to the invention. Heat exchanger 15 consists of an inflatable volume 7, for example manufactured from plastic, such as polyethylene foil or from rubber. Within system 7, a system of flexible 9 pipes 3 is provided. Volume 7 is then inflated. The system of flexible conduits 3 is now connected to a cooling installation known in the art, which is not further shown, which pumps, for example, a cooled glycol mixture through the system of conduits 3. The result is that on the outside of volume 7, water from the ambient air condenses, which is collected in a bowl 16. This water can be used if there is a need for it or it can be discharged if the space in which heat exchanger 15 is situated has to be dried.

It goes without saying that heat exchanger 15 can also be used for releasing heat. In that case, a heated medium must be passed through the system of flexible conduits 3.

> "1031712 *

Claims (18)

Method for manufacturing an object from ice, characterized in that with a system of conduits 5 a shape is realized which at least substantially approximates the object, after which a cooling medium is passed through the system of conduits and around the system of pipes supply water, whereby the object is created by icing around the system of pipes. Method according to claim 1, characterized in that the system of pipes is arranged on a closed surface. 3. Method according to claim 2, characterized in that the closed surface forms part of an inflatable structure and the inflatable structure is inflated before water is passed around the system of pipes. Method according to claim 3, characterized in that the closed surface remains part of the ice object. 5. Method according to claim 1, characterized in that the system of pipes is arranged between two closed surfaces. 6. Method as claimed in claim 5, characterized in that the two closed surfaces form part of an inflatable structure and the inflatable structure is inflated before water is passed around the system of pipes. 1031712 Method according to claim 6, characterized in that the two closed surfaces remain part of the ice object. Method according to one of the preceding claims, characterized in that the system of pipes is made of a flexible material. 9. Method as claimed in claim 8, characterized in that the system of pipes realizes a form which at least substantially approaches the object when the cooling medium is supplied under pressure. 10. Method as claimed in claim 1, characterized in that a tubular foil is arranged around virtually every pipe of the system of pipes, whereafter the tubular film is filled with water. 11. Method as claimed in claim 10, characterized in that a diameter of the tubular film is chosen such that water-filled tubular films form a substantially closed surface. 12. Objects, such as a sculpture, ice cave, bar or piece of furniture, at least partly manufactured with the method according to one of claims 1 to 11. 13. Objects as claimed in claim 12, characterized in that the objects are provided with a system of pipes filled with a cooling liquid, connected to a cooling machine. Objects according to claim 12, characterized in that the objects are provided with a system of pipes filled with a cooling liquid, connected to a heat exchanger arranged in the outside air. A heat exchanger, comprising a system of conduits 5 through which a cooling medium or a heating medium is passed and a volume placed around and / or within this system of conduits through which a second medium is passed, characterized in that the volume is made of foil comprises at least substantially closed surface within or around which the system of pipes is placed or the volume comprises a first and a second substantially closed surface made of foil, wherein the first surface comprises the second surface at least substantially and wherein the system of pipes between the first and second surfaces are positioned. A heat exchanger according to claim 15, characterized in that the heat exchanger is provided with means for inflating the volume. 20 A heat exchanger according to claim 15 or 16, characterized in that the system of pipes is made of a flexible material. A heat exchanger according to any one of claims 15 to 17, characterized in that the heat exchanger is adapted to recover water from the ambient air. 1031712 "