EP3048065A1 - Method for evacuating a vacuum cavity body - Google Patents

Abstract

A method for evacuating a Vakuumdämmkörpers, wherein the vacuum insulation body to be evacuated contains a sorptive material, and the method comprises the steps in which the vacuum insulation is evacuated via an evacuation device to a first pressure level, which is vacuum-tight sealed to the first pressure level Vakuumdämmkörper, so to the gas material molecules present in the sorbent material diffuse, and the vacuum insulation body evacuated to the first pressure level is evacuated again to a second pressure level.

Description

The present invention relates to a method for evacuating a Vakuumdämmkörpers.

Vakuumdämmkörper come for example in the thermal insulation in cooling or. Freezers for use. Here, a vacuum insulation body is arranged in the region between the outer jacket of the device and the inner container to be cooled in order to achieve a sufficiently high thermal insulation by means of the principle of vacuum thermal insulation between the outside and inside of the device to be insulated.

In order to produce such a vacuum insulation body, a diffusion-tight envelope is provided, which usually surrounds a core material, which gives the vacuum insulation body after an evacuation process the corresponding dimensional stability and at the same time prevents the inner walls of the vacuum insulation body lie directly against each other.

A diffusion-tight envelope is preferably understood to be an envelope by means of which the gas entry into the vacuum insulation body is so greatly reduced that the increase in the thermal conductivity of the vacuum insulation body due to the introduction of gas is sufficiently low over its service life. The life span is, for example, a period of 15 years, preferably 20 years and more preferably 30 years. Preferably, the increase in the thermal conductivity of the vacuum insulation body due to the introduction of gas is <100% and particularly preferably <50% over its service life.

Preferably, the area-specific gas passage rate of the shell is less than 10 ^-5 mbar * l / s * m ^2, and more preferably less than 10 ^-6 mbar * l / s * m ² (measured according to ASTM D-3985). This gas passage rate applies to nitrogen and oxygen. For other types of gas (in particular water vapor), likewise low gas throughput rates are preferably in the range of less than 10 ^-2 mbar * l / s * m ² and particularly preferably in the range of less than 10 ^-3 mbar * l / s * m ² (measured according to ASTM F -1249-90). Preferably, the above-mentioned small increases in the thermal conductivity are achieved by these low gas passage rates.

The above values are exemplary, preferred indications that should not be construed to limit the invention.

In order to produce a vacuum in a vacuum insulation body is conventionally withdrawn via an attached to the vacuum insulation evacuation nozzle by means of a negative pressure gas from the area to be vacuumed, so that a vacuum is formed. Here is the time that the vacuum insulation body must be connected to an evacuation a decisive factor for the efficiency of the evacuation process and the associated costs.

These considerations are not limited to refrigerators and / or freezers but apply to thermally insulated containers in general.

The present invention is therefore based on the object to provide a method in which the time that a vacuum insulation body must be connected to an evacuation device can be reduced. This brings both the advantages of a reduced cost burden in the production of the vacuum insulation body as well as an overall more efficient manufacturing process of the vacuum insulation body or a refrigeration device containing the vacuum insulation body with it.

This object is achieved by the method for evacuating a vacuum insulation body with the features of claim 1. Accordingly, it is provided that the vacuum insulation body to be evacuated contains a sorptive material and the vacuum insulation body is evacuated to a first pressure level via an evacuation device, which is vacuum-tightly sealed to the first pressure level evacuated vacuum insulation body, so that gas molecules diffuse to the sorptive material present in the vacuum body, and the evacuated to the first pressure level Vakuumdämmkörper is evacuated to a second pressure level.

It is described here that the vacuum insulation body to be evacuated contains a sorptive material. The vacuum insulation body thus encloses a sorptive material with its internal dimensions. A sorptive material describes a material that is capable of absorbing foreign molecules from its environment. This process is commonly referred to as sorption. According to the invention, the vacuum insulation body is evacuated during a first evacuation process only for a comparatively short time, so that the vacuum insulation body or the interior of the vacuum insulation body is at a first specific pressure level. Thereafter, the Vakuumdämmkörper which has been evacuated to the first pressure level, sealed vacuum-tight, so that the existing in the vacuum insulation body sorptive material from the sealed environment of Vakuumdämmkörperinneren foreign molecules can accommodate. This behavior of the sorptive material is also commonly referred to as a sorption pump, since the sorptive material causes a certain transport effect on those same molecules by the uptake of foreign molecules present in its environment. In a further subsequent step, the vacuum insulation body is then evacuated again and thereby brought to a second pressure level.

An advantage of this method is that according to the invention, the vacuum insulation body in a first evacuation must be connected to an evacuation device only for a relatively short time and the sorptive material can continue a "suction effect" during a sealed state. The air particles taken up by the sorptive material can then be removed more easily in a second evacuation process.

As a rule, after completion of the first evacuation process, the insulating body is decoupled from the vacuum pump, with any evacuation connection remaining on the vacuum body. Preferably, the Evakuierstutzen is designed to vacuum-tight seal the Vakuumdämmkörper using a check valve. If the vacuum insulation body located at a first pressure level is sealed in a vacuum-tight manner, it is now possible, for example, for another external production step on the vacuum body be performed so that the vacuum insulation body contributes in its final form for the insulation of a refrigeration device. This can be, for example, the completion of the outer shell and / or the refrigeration technology or the like. In this case, it is also possible that further production steps can be performed without an evacuation line attached to the vacuum insulation body, which considerably simplifies the execution of the production steps.

Since gas is bound in the interior of the vacuum insulation body by the sorptive material immediately following the vacuum-tight sealing of the vacuum insulation body evacuated to the first pressure level, the sorptive material acts as a sorption pump.

Subsequently, when the vacuum insulation body is again attached to a vacuuming apparatus such as a vacuum pump, it is easier in the second evacuation step to suck the gas diffused to the sorptive material out of the vacuum insulation body (to evacuate).

In a further embodiment of the method according to the invention, during the execution of the step A, namely during the evacuation of the vacuum insulation body via an evacuation device to a first pressure level, the sorptive material present in the vacuum body is heated so that it releases a part of the gas molecules accommodated in the sorptive material and evacuation feeds.

By heating the sorbtive material contained in the vacuum insulation body, it releases the bound foreign molecules, which are removed by means of the evacuation device attached to the vacuum insulation body.

Closing now the vacuum insulation body in a state in which the sorptive material can be described as degassed due to the effect of temperature, that is as in a state in which a large part of the bound by the sorptive material foreign molecules (in gaseous form) is discharged, this enhances the effect of the sorption pump of the sorptive material. Due to the onset of cooling of the sorptive material, the binding pressure of the sorptive material increases with the foreign molecules present in its environment. As a result, foreign molecules diffuse to the sorptive material at a greater rate and / or in a greater amount.

In a further embodiment of the present method, during execution of step C, namely, re-evacuating the vacuum insulation body evacuated to the first pressure level to a second pressure level, the sorptive material present in the vacuum body is heated to make part of the collected gas molecules similar to that above described procedure and the evacuation feeds.

The advantages associated with heating the sorptive material have also been described above and therefore will not be reiterated in any detail. Briefly, heating the sorptive material results in release of the foreign molecules bound in the sorptive material, which can be more easily withdrawn during a subsequent evacuation process.

Advantageously, in the process according to the invention, the between the steps B and C, namely between the vacuum-tight sealing evacuated to the first pressure level vacuum insulation body and the re-activation of the evacuated to the first pressure level Vakuumdämmkörpers to a second Pressure level, the sorptive material from an existing temperature level is cooled and / or cooled by itself, so that in the vacuum body existing gas molecules are absorbed by the sorptive material to these evacuation in step C, namely the evacuating again evacuated to the first pressure level Vacuum insulation body to a second pressure level, supply.

By cooling a sorptive material foreign molecules are increasingly taken up in the vicinity of the sorptive material. For the effect of an increasing absorption capacity of the sorptive material, it is of minor importance whether the sorptive material has been previously heated, or is cooled or cooled from an existing temperature level.

Combinations of heating and cooling or cooling of the sorptive material are also considered to be particularly advantageous, since in this case the described advantageous aspects occur particularly pronounced.

According to a further embodiment of the present method, a certain period of time is inserted between the steps B and C, namely between the vacuum-tight sealing of the vacuum insulation body evacuated to the first pressure level and the renewed evacuation of the vacuum insulation body evacuated to the first pressure level to a second pressure level Diffusion of the gas molecules can take place towards the sorptive material. This certain period of time is preferably more than three minutes, more preferably more than 15 minutes, most preferably more than 60 minutes and most preferably more than 240 minutes.

This ensures that the gas molecules attracted by the sorption force of the sorptive material and located in the vacuum insulation body have sufficient time to be absorbed by the sorptive material.

In a further particularly advantageous embodiment of the present invention, the sorptive material which is present in the vacuum insulation body is arranged in a region near an evacuation nozzle. Preferably, the sorptive material is no further than 45 cm, more preferably no further than 30 cm, most preferably no further than 15 cm, and most preferably no further than 7 cm from a vacuum through the evacuation nozzle the opening formed in the vacuum body.

The Evakuierstutzen is a simple coupling device to which an evacuation device can be connected to the vacuum insulation body. Arranging the sorptive material near this evacuation nozzle has several advantages. Thus, when aspirating from the sorptive material, no additional path has to be covered by a core material usually present in the vacuum insulation body. In addition, after the sorption pumping effect, after evacuation of the vacuum insulation body via an evacuation device to a first pressure level and the vacuum-tight sealing of the evacuated vacuum insulation body comes into force, the gas molecules taken up by the sorptive material are already close to the evacuation nozzle, which facilitates evacuation of the vacuum insulation body.

Advantageously, in another embodiment, the first pressure level is above the second pressure level.

Preferably, the first pressure level is a pressure level at which diffusion processes through a core material located in the vacuum body limits the speed of the evacuation process.

This is a particularly effective process feature, since for the evacuation process those gas transport processes are limiting in which diffusion processes through the core material are the limiting factor for the speed of the evacuation process.

Accordingly, it is no longer necessary to aspirate the accelerated gas molecules by attaching an evacuating device, but to have it done by the attractive effect of the sorptive material, during which already a further production of the vacuum insulation body can be tackled.

When the vacuum insulation body is then re-attached to a vacuum device after a certain time, the gas which has in the meantime diffused to the sorptive material can preferably be expelled by heating the sorptive material. In this case, if the sorptive material is also arranged in the vicinity of the evacuation nozzle, migration of the gas diffused to the sorptive material into the core material is effectively prevented since favorable flow conditions to the pump are present and movement of the gas molecules from this is only possible with difficulty.

In a further embodiment, the combination of steps B and C, namely the vacuum-tight sealing of an evacuated vacuum insulation body and the renewed evacuation of the evacuated vacuum insulation body, can be repeated several times in succession.

This strengthens the above-described effect of vacuuming, while at the same time only a relatively short duration of a compound with an evacuation device is needed.

In one embodiment, the vacuum insulation body is a heat insulation body of a thermally insulated container, preferably a refrigerator and / or freezer. It can be provided that the container has a body with an inner container and an outer wall, wherein there is at least one intermediate space between the inner container and the outer wall, and wherein the method is carried out on a Vakuumdämmkörper, which is located within this space. Furthermore, it can be provided that the container has a closure element with an inner wall and an outer wall, wherein there is at least one intermediate space between the inner wall and the outer wall, and wherein the method is performed on a Vakuumdämmkörper which is located within this space.

At least one and preferably all evacuation steps of the method according to the invention are preferably carried out, while normal or ambient pressure prevails outside of the vacuum insulation body or outside of its envelope. The evacuation is then carried out by connecting a suitable incorporated in the envelope of the vacuum insulation body interface, such as an evacuation nozzle, which may have a valve, to a vacuum pump. Preferably, in this embodiment, it is preferably not necessary at any time to introduce the vacuum insulation body or its sheath into a vacuum chamber. In this respect, it is possible to dispense with a vacuum chamber in one embodiment of the method.

The invention further relates to a thermally insulated container, preferably a refrigerator and / or freezer, which comprises a Vakuumdämmkörper which has been evacuated according to one of the preceding embodiments. Here, the vacuum insulation body may be contained in a closure element, a door or a body of the container or refrigerator and / or freezer.

The temperature-controlled interior is either cooled or heated depending on the type of appliance (cooling unit, heating cabinet etc.). For the purposes of the present invention, heat-insulated containers have at least one temperature-controlled internal space, it being possible for it to be cooled or heated so that a temperature below or above the ambient temperature of e.g. 21 ° C results. The invention is therefore not limited to refrigerators and / or freezers but generally relates to appliances with a temperature-controlled interior, for example, heat cabinets or heat chutes.

In one embodiment, it is provided that the container according to the invention or the container whose insulation comprises a vacuum insulation body evacuated in the context of a method according to the invention is a refrigerator and / or freezer, in particular a domestic appliance or a commercial refrigerator , For example, such devices are included, which are designed for a stationary arrangement in the home, in a hotel room, in a commercial kitchen or in a bar. For example, it may also be a wine refrigerator. Furthermore, refrigerated and / or freezers are also included in the invention. The devices according to the invention may have an interface for connection to a power supply, in particular to a household power grid (eg a plug) and / or a standing or installation aid such as feet or interface for fixing within a furniture niche. For example, the device may be a built-in device or a stand-alone device.

Preferably, the container or the device is designed such that it is connected to an AC voltage, such as a home voltage of e.g. 120 V and 60 Hz or 230 V and 50 Hz can be operated. In an alternative embodiment, it is conceivable that the container or the device is designed such that it can be operated with direct current of a voltage of, for example, 5 V, 12 V or 24 V. In this embodiment, it can be provided that a plug-in power supply is provided inside or outside the device, via which the device is operated. Operation with DC voltage can be used in particular when the container has a thermoelectric heat pump for controlling the temperature of the interior.

In particular, it can be provided that the refrigerator and / or freezer has a cabinet-like shape and has a usable space which is accessible to a user at its front side (in the case of a chest at the top). The working space can be subdivided into several compartments, which are all operated at the same or at different temperatures. Alternatively, only one compartment can be provided. Within the useful space or a compartment and storage aids such as storage compartments, drawers or bottle holders (in the case of a chest also room divider) may be provided to ensure optimum storage of refrigerated or frozen goods and optimum space utilization.

The useful space can be closed by at least one door pivotable about a vertical axis. In the case of a chest, a flap pivotable about a horizontal axis or a sliding lid is conceivable as a closure element. The door or other closure element can be in the closed state by means of a peripheral magnetic seal with the body substantially airtight in combination. Preferably, the door or another Heat-insulated closure element, wherein the heat insulation can be achieved by means of a foaming and optionally by means of vacuum insulation panels, or preferably by means of a vacuum system and particularly preferably by means of a full vacuum system. If necessary, door racks can be provided on the inside of the door in order to be able to store refrigerated goods there as well.

In one embodiment, it may be a small appliance. In such devices, the work space defined by the inner wall of the container has, for example, a volume of less than 0.5 m ³ , less than 0.4 m ³ or less than 0.3 m ³ . The outer dimensions of the container or device are preferably in the range up to 1 m in terms of height, width and depth.

With regard to such a container, it may be in the context of a method according to the invention evacuated vacuum insulation with respect to such a container to a full vacuum system. This is to be understood as a thermal insulation which consists exclusively or predominantly of an evacuated area which is filled with a core material. The limitation of this range can be formed for example by a vacuum-tight film and preferably by a high-barrier film. Thus, between the inner container and the outer wall as thermal insulation, only such a film body is present, which has a region surrounded by a vacuum-tight film in which vacuum prevails and in which a core material is arranged. A foaming and / or Vakuumisolationspaneele as thermal insulation or other thermal insulation except the full vacuum system between the inside and the outside of the container or device are preferably not provided.

This preferred type of thermal insulation in the form of a full vacuum system may be between the inner container and the outer wall of the body and / or extend between the inner wall and the outer wall of the closure element, such as a door, flap, lid or the like.

Further details and advantages of the present invention will become apparent from the following embodiment.

In the manufacture of a refrigerator and / or freezer with full vacuum insulation, an inner container is provided and connected along the leading edges to an incomplete stand of an outer container, with the rear wall of the outer container being missing.

Between the inner container and the outer container, a gap is formed, which is lined in the process in any way with a vacuum-tight film, the resulting film bag having an open back of the scaffold facing opening, which preferably substantially the entire rear surface of the intermediate product Device occupies.

On the basis of this opening a pearl slurry is now filled in the foil bag and compacted. Subsequently, the opening is welded circumferentially with a cover and evacuated the enclosed space of the film to form the vacuum insulation body.

In order to carry out the evacuation, an evacuation nozzle is incorporated in the covering film, which can be connected to a vacuum pump. Near this Evakuierstutzens a reservoir is arranged with a sorptiven material within the filled with the pearl slurry interior. For example, this reservoir comprises a gas-permeable bag, which is in communication with the cover and was incorporated in the cover before welding.

In the context of the method according to the invention, this evacuation nozzle is now connected to a vacuum pump and it is evacuated for a short time, for example less than 5 minutes. Then the vacuum pump is uncoupled and the evacuation nozzle sealed airtight. In a break of several hours, remaining gas molecules are adsorbed on the sorptive material near the evacuation nozzle. Now, in a further step, the evacuation nozzle is again connected to a vacuum pump and it is evacuated for a short time, for example, less than 5 minutes. The pressure levels in the first and second steps may be different or identical. Due to the proximity of the sorptive material to the evacuation nozzle, the paths for the gas are short and much of the gas adsorbed to the sorptive material can be withdrawn in this second evacuation step. Thus, a good vacuum can be achieved with a comparatively short evacuation time.

Claims (14)

Method for evacuating a vacuum insulation body, wherein the vacuum insulation body to be evacuated contains a sorptive material,
characterized,
that the method comprises the steps: (a) evacuating the vacuum insulation body via an evacuation device to a first pressure level, (b) vacuum-tight sealing of the vacuum insulation body evacuated to the first pressure level, so that gas molecules diffuse to the sorptive material present in the vacuum insulation body, and (c) re-evacuating the evacuated to the first pressure level Vakuumdämmkörpers to a second pressure level. The method of claim 1, wherein, while performing step (a), the sorptive material present in the vacuum insulation body is heated to release a portion of the collected gas molecules and to deliver the evacuation. A method according to any one of the preceding claims, wherein, during execution of step (c), the sorptive material present in the vacuum insulation body is heated so that it releases a part of the absorbed gas molecules and supplies it to the evacuation. Method according to one of the preceding claims, wherein between steps (b) and (c) the sorptive material is cooled or cooled from an existing temperature level, so that gas molecules present in the vacuum insulation body are absorbed by the sorptive material in order to prevent them from evacuating Feed step (c). Method according to one of the preceding claims, wherein between the steps (b) and (c) a certain period is inserted, in which a diffusion of the gas molecules can take place to the sorptive material, and the certain period of time preferably greater than 3 minutes, preferably greater than 15 Minutes, more preferably greater than 60 minutes, and most preferably greater than 240 minutes. Method according to one of the preceding claims, wherein the Vakuumdämmkörper contains a sorptives material, which is arranged in a region near an evacuation nozzle, preferably not more than 45cm, preferably not more than 30cm, in a particularly preferred not more than 15cm and in a whole most preferably not more than 7cm away from an opening formed by the evacuation nozzle in the vacuum insulation body. Method according to one of the preceding claims, wherein the first pressure level is above the second pressure level. Method according to one of the preceding claims, wherein the first pressure level is a pressure level at which diffusion processes by a core material located in the vacuum insulation body limit the speed of the evacuation process. Method according to one of the preceding claims, wherein the combination of steps (b) and (c) is repeated several times in succession. Method according to one of the preceding claims, wherein at least one and preferably all evacuation steps of the method are carried out while normal or ambient pressure prevails outside the vacuum insulation body or outside its envelope. Method according to one of the preceding claims, wherein the vacuum insulation body is a heat insulation body of a thermally insulated container, preferably a refrigerator and / or freezer. The method of claim 11, wherein the container has a body with an inner container and an outer wall, wherein between the inner container and the outer wall is at least one gap, and wherein the method is performed on a Vakuumdämmkörper which is located within this space. The method of claim 11, wherein the container comprises a closure member having an inner wall and an outer wall, wherein between the inner wall and the outer wall is at least one gap, and wherein the method is performed on a Vakuumdämmkörper which is located within this space. Heat-insulated container, preferably refrigerator and / or freezer with at least one body and at least one tempered and preferably cooled interior, which is surrounded by the body and with at least one closure element, by means of which the temperature-controlled and preferably cooled interior is closable, being between the tempered and preferably cooled interior and the outer wall of the container or device is at least one space,
characterized,
in that at least one vacuum insulation body which has been evacuated according to one of claims 1 to 13 is present in the intermediate space.