DE102010003663A1 - Thermal storage composite material containing expanded graphite and PCM and process for its preparation - Google Patents

Abstract

A method for producing a composite material with expanded graphite and phase change material (PCM), characterized in that the composite material is produced by infiltrating a graphite body made of at least partially compressed expanded graphite with PCM in the liquid state and comminuting the infiltrated graphite body into particles, the PCM being produced during the Comminution is in the solid and / or liquid state.

Description

The invention relates to a PCM-EG composite material, a process for its preparation, a PCM-EG molding, a process for its preparation and a use of the PCM-EG molding.

Phase change materials (PCM of "phase change material") for the storage of latent heat are known. However, because of their low thermal conductivity, heat or cold to be stored or dispensed can be absorbed or released by PCM too slowly.

For this purpose, it is known to combine graphite with its high thermal conductivity together with PCM to form a highly effective composite material which has both high heat storage capacities and high absorption and release rates. Under the terms heat storage and heat conduction, cold storage and cooling line, etc. are always included below.

In order to store large amounts of heat or cold, correspondingly large-volume heat storage are needed. These are conventionally made by blending graphite into PCM. However, there is the problem that when melted PCM graphite and PCM tend to segregate, which can deteriorate the heat storage properties of the memory. In general, there is the problem that graphite flakes float on liquid PCM due to their low density and are difficult to stir into the PCM.

Another conventional method of making a PCM graphite heat store is to infiltrate a porous graphite block with liquid PCM. This has the disadvantage that an infiltration takes place only in a near-surface area and also a complex post-processing is necessary.

Furthermore, it is known to encapsulate PCM encapsulated in a graphite matrix, for example. The encapsulation prevents the PCM and graphite from segregating when the PCM melts. The disadvantage here is that the encapsulation obstructs heat conduction between graphite and PCM.

The object of the invention is to provide a PCM graphite heat storage material which does not have the above-mentioned disadvantages of the prior art, in particular PCM and graphite do not separate, which is easy to manufacture and the geometry of a heat storage, which consists of a Heat storage material is produced, has a high flexibility. Another object is to provide such a heat accumulator and a method for its production.

The first object is achieved with a method according to claim 1 and a heat storage composite material according to claim 4. Preferred embodiments are specified in the dependent subclaims.

According to a method of the present invention, an expanded graphite and PCM composite material is prepared by infiltrating a graphite body of at least partially compressed expanded graphite with PCM in the liquid state and comminuting the infiltrated graphite body into particles, wherein the PCM is in the solid and / or liquid state during comminution ,

In particular, the composite material may contain expanded graphite and PCM as the predominant main constituent, which in total constitutes at least 50% by weight, in particular at least 80% by weight, in particular at least 90% by weight. For example, PCM and expanded graphite are the only two constituents of the composite. However, it is also possible to use additives, such as nucleating agents or stabilizers.

The process according to the invention has the surprising effect that no separation of PCM and graphite occurs in the composite material obtained by the process according to the invention in contrast to conventional composite material. However, since the composite is in the form of particles, it can be mixed by itself. Fixation of PCM is provided locally in particles.

Advantageously, the crushing comprises at least one of the steps of milling, chopping, shredding and milling or other machining operations, such as rubbing or rasping. With these steps, a molded body infiltrated with PCM can be cut particularly well, so that particles are obtained which advantageously have a particularly uniform shape.

Preferably, the crushing is carried out with a crusher comprising shredders, shredders, graters, rippers, milling and the like. In particular, it is advantageous if the heat storage composite material is not strongly compressed, which is possible for example by machining.

Preferably, the PCM contains paraffin, sugar alcohol, gas hydrate, water, an aqueous solution of a salt, salt hydrate, a mixture of salt hydrates, a salt, a eutectic mixture salts, an alkali metal hydroxide, or mixtures containing at least one of the aforementioned PCMs. It may be advantageous for the PCM to contain sodium acetate trihydrate and / or calcium hydroxide hexahydrate.

The object is further achieved with a heat storage composite material according to claim 4. According to the invention, the heat storage composite material containing expanded graphite and PCM is present in comminuted particles of a graphite body infiltrated with PCM. This results in the advantages mentioned above for the method according to the invention.

The heat storage composite material preferably has a proportion of PCM of more than 60% by weight, in particular more than 70% by weight, in particular more than 80% by weight. Such high PCM levels are possible in contrast to the prior art, without causing segregation of PCM and graphite.

It may be advantageous for the particles to have an average particle size d50 between 5 μm and 5 mm, in particular between 30 μm and 1.5 mm, in particular between 200 μm and 0.5 mm.

Advantageously, the particles of the heat storage composite material have a flowability. This has the advantage that the heat storage composite material can be poured into a virtually arbitrarily shaped mold and can already be present in such a form by pouring in a high relative bulk density.

Preferably, the heat storage composite has a flowability, although the PCM is at least partially in liquid form. Presumably, a pore system in the expanded graphite is designed such that the PCM moves from a surface of the EG particles into an interior of the EC particle, so that the surface remains substantially dry and therefore the flowability is at least substantially maintained.

According to the invention, the heat storage composite material in the form of particles can be used directly as a thermal storage. For this purpose, the particulate heat storage composite material is advantageously given in designated cavities, containers or the like, where, for example, accumulates and / or dissipated heat or cold.

The second object is achieved by a method according to claim 9.

According to the inventive method, a heat storage molded body containing graphite and a PCM is prepared by particulate heat storage composite material containing graphite and a PCM, in particular heat storage composite material according to the invention, in particular produced by a method according to the invention, using heat and / or pressure to a Solidified body.

This has the advantage that a shaped body is obtained which, like the individual particles of heat storage composite material of which it consists, does not undergo segregation of the PCM and graphite. This is particularly the case both in the production of the molding and in its use, where the PCM can also at least partially melt.

Other particles containing PCM and graphite may also be used as the particles obtained by comminuting an infiltrated graphite body for the process of the invention. Such particles with graphite and PCM may, for example, also have lower PCM contents than 60% by weight. This can be particularly advantageous when PCM and graphite are not prone to segregation, as is the case at low PCM levels. Then conventionally produced particles of PCM and graphite can be used.

Advantageously, the heat storage composite material is given prior to the application of heat and pressure in a press or casting mold whose inner shape corresponds to the desired outer shape of the shaped body. As a result, a molded body having predetermined outer geometries is produced directly.

This also has the advantage that a post-processing of the molding is only necessary to a small extent or completely eliminated.

Preferably, the shaped body is at least partially formed around at least one partial body. As a result, it is possible to produce specifically complicated geometries of the shaped body.

It may be advantageous that by forming the partial body, a cavity is created, which is suitable for receiving an object to be tempered. As a result, objects to be tempered in the resulting molded body can be introduced directly into cavities of the shaped body, which are then exposed directly to cooling of the heating.

It may also be advantageous that the part body is left in the molding after the production of the molding.

Preferably, the part body has a cavity which is suitable for receiving an object to be tempered. This has the advantage that the part body does not have to be removed, so that a cavity is formed, but the part body itself can accommodate an object to be tempered. For receiving a battery to be cooled or a similar cylindrical body can be used about a hollow cylinder, which is left in the molding. The hollow cylinder acts initially shaping, but also fulfills the task of receiving the cylindrical body to be cooled.

According to an advantageous variant of the part body is left in the molding and is itself the object to be tempered dar. This has the advantage that not only no additional Entformungsschritt is necessary, but the tempering body must not be additionally introduced.

It may be advantageous for the object to be tempered to be a conduit through which a liquid or a gas can flow. This can be, for example, a pipe, a hose or the like. As a result, for example, a heat exchanger can be produced.

According to another advantageous embodiment, the object to be tempered may be a battery. In the context of the invention, the term "battery" is understood to mean any desired electrical energy store, such as a fuel cell, an accumulator, a capacitor, or the like.

The second object is further achieved with a heat storage molding according to claim 18. Advantageous embodiments are specified in the dependent subclaims. The invented graphite and PCM heat storage molded article, which is produced in particular by a method according to the invention, in particular with a particulate heat storage composite material according to the invention, has been solidified by applying heat and / or pressure to the shaped article.

Advantageously, the PCM and the graphite in the molding do not segregate during use.

In particular, even with a complete melting of the PCM, the PCM and the graphite in the molded article advantageously do not separate out.

According to an advantageous variant of the molding is provided with an outer shell. As a result, no PCM can escape even if the PCM completely melts. The heat storage molded body is also protected against external influences.

It may further be advantageous that the at least one part body is part of the outer shell. As a result, partial bodies can be used for shaping with the shaped body, which are left in the shaped body. Either a remaining outer shell is connected to the body part or the outer shell is already connected to the body during the forming of the molding around the body part.

It may also be advantageous that an inner surface of the cavity of the part body is part of an outer surface of the outer shell.

According to the invention, it can be advantageous to use a heat storage body according to the invention as a thermal storage, as Batteriethermierkörper, for air conditioning, especially of buildings or vehicles, as a heater storage in particular of buildings or vehicles, as in central heating storage, as a cold storage element, as a cooling wall element, as Heizwandelement, in particular of rooms, including vehicle interiors, cooling of electrical components, such as batteries or to use as a cooling element of food.

Further advantageous embodiments and developments are described below with reference to an embodiment with reference to FIG 1 and 2a to 2c explained in more detail.

Showing:

1 a perspective view of a heat storage body according to the invention, which is suitable as Batteriethermierkörper,

2a) to 2c) schematically steps of a method according to the invention for producing a heat storage molded body made of heat storage composite material.

An inventive heat storage composite material 1 in the form of particles 2 is present, is represented in the following steps: Natural graphite is expanded in a known manner and compressed so far that creates a partially compressed preform of expanded graphite. This preform is infiltrated with a phase change material (PCM for short) which is in liquid form at the infiltration conditions. This is molten paraffin in this example. Also suitable, however, are also sugar alcohols, gas hydrates, water, aqueous solutions of salts, salt hydrates, mixtures of salt hydrates, salts and eutectic mixtures of salts, alkali metal hydroxides, and mixtures which are at least contain one of the aforementioned PCMs. The infiltration can be carried out by dip impregnation, vacuum infiltration or other known methods. It will contain a PCM graphite composite material which has the outer shape of the preform, that is, for example, as a plate of a thickness of 1 cm is present. The dimensions of the preform can be varied as desired. By pressing pressure in compressing the expanded graphite, various densities are set, such as between 0.01 g / cm ³ and 0.4 g / cm ³ . Depending on the density, the open porosity of the preform is correspondingly variable and thus the possible percentage of PCM in the infiltrated heat storage composite material.

The resulting heat storage composite material is ground after hardening or solidifying the PCM by cooling with a Rapsel in particles having a particle size d50 between 30 microns and 1.5 mm. Depending on the machines used, which are used for crushing the heat storage composite material, targeted smaller or larger grain sizes can be achieved. Also, the PCM does not necessarily have to be cooled before the heat storage composite material is comminuted into particles.

The particles obtained have the property that they themselves have a stable graphite network of the former preform and therefore the PCM is stabilized. Because of the small pore size in the graphite, PCM, after reflow, is believed to be retained by capillary forces and surface forces in the particular particle without flowing out.

This causes the particles 2 pourable and can in a press or casting mold 3 be poured, as in the 2a) to 2c) shown. After that, they already have a high bulk density due to their very good flowability ( 2 B ). By applying pressure and temperature, the individual particles cake, sinter, or melt, resulting in a single overall body 4 solidified and compacted, as a heat storage molded body 4 referred to as. Pressure and temperature can be adjusted depending on the PCM used.

By applying a negative pressure during the compression, a porosity in the resulting heat storage molded body is minimized.

This method is suitable, even complicated shaped heat storage moldings 4 manufacture. For example, a heat storage molded body can be 4 as in 1 shown without mechanical reworking would be necessary. The heat storage molded body 4 to 1 is a battery tempering, in the recesses 5 Batteries (not shown) can be introduced. Heat generated by the batteries is stored as latent heat from the PCM, with the graphite of the heat storage molded body 4 accelerates the transport of heat from one surface of the battery to the PCM.

In the present embodiment, the heat storage molding has 4 an outer shell 6 made of sheet metal, which is the heat storage composite material 1 from external influences, such as mechanical damage or chemical influences, such as from leaking batteries. In the 2a) to 2c) becomes the outer shell 6 already as a press or casting mold 3 used, allowing a demolding and providing an additional outer shell 6 omitted. Instead, a form can also be used 3 be used, from the obtained heat storage moldings 4 is removed from the mold and then an outer shell 6 is provided (not shown).

In particular, hollow partial bodies remain 7 with a recess 5 , which are designed to receive a body to be tempered, such as a battery, in the molded body 4 , In the present example, the part bodies 7 Parts of the press or casting mold 3 , Alternatively, one could leave a remaining outer shell 6 which are the part bodies 7 not integral then contains then around the molding 4 Arrange.

In a variant of the exemplary embodiment (not shown), tubes of a heat exchanger are enveloped with the aid of particles according to the invention as described above for the partial bodies. The tubes remain in the obtained after application of pressure and / or temperature heat storage moldings. The resulting heat storage shaped body 4 would instead of in 1 have shown recesses continuous round holes.

The inventive method can also be used for very complicated outer contours of the heat storage molding to be produced 4 can be applied, ie it can in complex shaped press / casting molds 3 be applied.

In principle, the method according to the invention can be used everywhere where heat and / or cold should be dissipated and / or stored. As the heat storage composite material according to the invention 1 can contain large amounts of PCM, particularly high amounts of heat and cold can be stored.

Forming a heat storage molded body 4 is generally compatible with all particles 2 from a PCM graphite composite 1 produce. This method according to the invention is not based on the use of the particles according to the invention 2 limited. In particular, all the features described in the claims, the figures and the description can be combined as desired, as long as they are technically meaningful and serve the solution according to the invention of the objects which the invention has set itself.

Claims (24)

A method of making an expanded graphite and phase change material (PCM) composite, characterized in that the composite material is made by infiltrating a graphite body of at least partially compressed expanded graphite with PCM in the liquid state and crushing the infiltrated graphite body into particles, the PCM being formed during the Crushing in the solid and / or liquid state is present. A method according to claim 1, characterized in that the crushing comprises at least one of the steps of milling, shredding, shredding, machining, such as milling, rubbing or rasping. A method according to claim 1 or 2, characterized in that the PCM is paraffin, sugar alcohol, gas hydrate, water, an aqueous solution of a salt, salt hydrate, a mixture of salt hydrates, a salt, a eutectic mixture of salts, an alkali metal hydroxide or mixtures with contains at least one of these PCMs. Heat storage composite material containing expanded graphite and PCM, characterized in that the heat storage composite material is present in comminuted particles of a PCM infiltrated graphite body, in particular produced by a method according to one or more of claims 1 to 3. Heat storage composite material according to claim 4, characterized in that the proportion of PCM is more than 60%, in particular more than 70%, in particular more than 80%. Heat storage composite material according to claim 4 or 5, characterized in that the particles have a mean particle size d50 between 5 microns and 5 mm, in particular between 30 microns and 1.5 mm, in particular between 200 microns and 0.5 mm. Heat storage composite material according to one or more of claims 4 to 6, characterized in that the heat storage composite material in the presence of the PCM in solid and / or liquid form is free-flowing. Use of the heat storage composite material according to one or more of claims 4 to 7 as a thermal storage. A process for the production of a heat storage shaped body containing graphite and a PCM, characterized in that a particulate heat storage composite material containing graphite and a PCM, in particular according to one or more of claims 4 to 8, in particular produced by a method according to one or more of the claims 1 to 3, is solidified using heat and / or pressure to form a shaped body. A method according to claim 9, characterized in that the heat storage composite material is placed before the application of heat and pressure in a mold or molding whose inner shape corresponds to the desired outer shape of the shaped body. A method according to claim 9 or 10, characterized in that the shaped body is at least partially formed around at least one partial body. A method according to claim 11, characterized in that by forming the partial body, a cavity is formed, which is suitable for receiving an object to be tempered. Method according to claim 11 and / or 12, characterized in that the partial body is left in the molded body after the production of the shaped body. Method according to one or more of claims 11 to 13, characterized in that the part body has a cavity which is suitable for receiving an object to be tempered. Method according to one or more of claims 11 to 14, characterized in that the part body is left in the molding and even represents the object to be tempered. Method according to one or more of claims 11 to 15, characterized in that the object to be tempered is a line through which a liquid or a gas can flow. Method according to one or more of claims 11 to 16, characterized in that the object to be tempered is a battery. Heat storage molded article, in particular produced by a process according to one or more of claims 9 to 17, containing graphite and a PCM, characterized in that the particulate heat storage composite material, in particular according to one or more of claims 4 to 8, in particular produced according to one or more of claims 1 to 3), which contain graphite and a PCM, has been solidified by applying heat and / or pressure to the shaped body. Shaped body according to claim 18, characterized in that the PCM and the graphite in the molding do not segregate during use. Shaped body according to claim 19, characterized in that the PCM and the graphite in the molding do not segregate in a complete melting of the PCM. Shaped body according to one or more of claims 18 to 20, characterized in that the shaped body is provided with an outer shell. Shaped body according to claim 21, characterized in that the part body is part of the outer shell. Shaped body according to claim 22, characterized in that an inner surface of the cavity of the partial body is part of an outer surface of the outer shell. Use of a shaped article according to one or more of claims 18 to 23, in particular produced by a method according to one or more of claims 9 to 17, as a thermal store, Batteriethermierkörper, for air conditioning, especially of buildings or vehicles, as a heater storage, especially in buildings or vehicles or for cooling electrical components or food.

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