KR20010079614A - Method and device for storing articles under controlled atmosphere - Google Patents

Abstract

The present invention relates to a storage atmosphere forming means (5, 5, 6) capable of forming a storage atmosphere inside of one or more storage modules (X, Y, Z, 7), said storage module comprising two substantially parallelepiped, substantially perpendicular and opposing walls (P _X1 , P _X2 ), each of said walls The storage atmosphere forming means may cause gas from one of the two walls to flow in a substantially laminar flow direction toward the other wall.

Description

[0001] METHOD AND DEVICE FOR STORING ARTICLES UNDER CONTROLLED ATMOSPHERE [0002]

In particular, there is a need to temporarily store articles in a controlled atmosphere while waiting for the articles to be used in many industries (such as the electronics industry, the food industry, or even the pharmaceutical industry), or during manufacturing.

The storage atmosphere is typically composed of dry air or may be a nitrogen atmosphere containing residual oxygen or water vapor within a limited range.

Thus, for example, in the electronics industry, it is common to provide means for storing electronic components in the manufacturing process under an atmosphere of nitrogen or dry air.

- When storing the printed circuit before mounting

- When storing a bare chip before mounting it on electronic board

- When storing a new generation of electronic components such as QFPs and BGAs, these electronic components are sensitive to moisture as well as their metal terminals as well as plastic casings.

The electronics industry also has the option of storing the user for a long period of time under dry air or nitrogen (if it takes years) if the supply is uncertain for the time being, in the case of electronic components, which can be aging or strategic products. There is work.

Thus, in industry, storage forms vary greatly depending on the application, and may occur several times per day during storage, even several times per hour, when the storage device is open, once a month, or even less .

Such a storage process is necessary in order to prevent the interaction between the electronic component and the ambient air, and the main danger is related to the absorption of moisture from the ambient air by the electronic component, for example, There are cases where the tracks of the printed circuit are oxidized or the casing encapsulated with plastic absorbs moisture ("popcorn" effect), eg reaction with some contaminating particles in ambient air such as sulfur oxides or halogenated compounds I have to understand.

Thus, the problem of moisture absorption in the casing encapsulated with several plastics makes it possible for the user to bake the electronic component at a certain temperature, for example 24 to 48 hours, and the negative aspect of such baking treatment is economical and productive It is significant in both viewpoints.

As described above, when a storage device is used for a short period of time, the article is introduced into or taken out of the storage member as required by the user, so that the storage module is repeated very frequently, Is opened and closed.

Of course, the problem of moisture absorption also exists in the case of long-term storage.

The capacity of the storage module or reservoir varies and is typically in the range of approximately 100 to 200 liters and the continuous injected flow rate is generally very low, approximately 50 to 150 liters / hour.

One of the easiest ways to visualize the operational problems of such storage is to calculate the time it takes to re-adjust the atmosphere after the door is opened.

To do this, we use the traditional so-called "dilution purge" mathematical model described below.

V _P = V _O x log (X _O / X _F )

Here, V _P is the volume of the injected gas, V _O is the capacity of the chamber, X _O is the initial content of the corresponding component in the chamber (oxygen is 21% when the door is opened and air is introduced) _F represents the desired final content of the component, respectively.

To help you understand the problems that may arise, consider the following example of two industrial warehouses:

a) The first example of a reservoir is to store electronic components under a nitrogen working atmosphere (and therefore in the required atmosphere) with a capacity V _o = 0.22 m ³ and a residual oxygen content not exceeding 100 ppm (X _F = 100 ppm) .

Therefore, X _F corresponds to the air after the door is opened (residual oxygen is 21%).

The flow rate of nitrogen injected in this first example is permanently 0.25 m ³ / h.

From this, it can be seen that the required volume of nitrogen is 1.683 m ³ , and the time required for reconditioning the atmosphere after opening the reservoir is 1.683 / 0.25 = 6.73 hours, that is, 6 hours and 43 minutes.

b) If the Now size considerations a second example of a larger storage, the capacity of the reservoir (V _O) is 1.4 m ^3, and residual oxygen content should not exceed 100 ppm (X _F = 100ppm same manner as in Example 1) It is used to store electronic components under a nitrogen working atmosphere.

The flow rate of constantly injected nitrogen is the same as in Example 1 (25 m ³ / h).

From this, it can be seen that the required nitrogen volume is 10.7 m ^3, and the atmosphere regulating time after the reservoir is opened is 10.7 / 0.25 = 42.8 hours, that is, 42 hours and 48 minutes.

Thus, in these examples where the atmosphere conditioning time is not suitable for temporary storage and the storage is opened 4 to 5 times per hour on average, in these examples the storage is inefficient so that the residual oxygen content, That is, an atmosphere of 100 ppm or less can not be maintained. For this reason any attempt to control and adjust the atmosphere is meaningless.

Field of the Invention [0002] The present invention relates to a field related to an apparatus for storing articles under a controlled atmosphere.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic view of an article storage apparatus according to the present invention using an arrangement in which storage modules, in which gases are individually fed, are stacked.

Fig. 2 is another schematic view of an article storage apparatus according to the present invention, in which an arrangement in which storage modules are stacked is used and the gas is introduced into the apparatus at a single point.

Figures 3 and 4 are schematic views of an article storage apparatus according to the invention using an arrangement of storage modules arranged in parallel.

FIG. 5 is a schematic view of an article storage apparatus according to the present invention using an arrangement in which two parallel rows of storage modules arranged in parallel and communicating with each other are stacked in two rows. In consideration of a direction in which a gas flows, The gas is supplied to the article storage device through a single gas transfer device that supplies the gas to the article storage device.

Fig. 6 is a schematic view of an article storage apparatus according to the present invention in which a parallel array of storage modules arranged in parallel and communicating with each other is arranged in parallel (stacked) in four rows, wherein only the first storage module of each parallel array And this gas transfer device is included.

Figure 7 is a schematic diagram of an entire installation including an article storage device according to the present invention, wherein the operation of the article storage device is controlled and adjusted.

From the above, it is possible to provide a necessary storage atmosphere (for example, a nitrogen atmosphere having a low residual content of oxygen or water vapor), to quickly regulate the atmosphere after opening, and when the storage member is opened several times at one time It can be seen that a method of storing articles under an improved control atmosphere, which can also be used in the field of the present invention, is desperately required in the industry.

Accordingly, an apparatus for storing an article under a constant atmosphere according to the present invention comprises:

i) one or more storage modules capable of receiving an article to be stored;

j) a storage atmosphere forming means capable of forming a storage atmosphere inside the one or more storage modules

/ RTI >

Wherein at least one of the storage modules comprises a substantially parallelepiped and substantially perpendicular and opposing first and second walls, the storage atmosphere forming means comprising a first gas transfer device And the first gas transfer device is characterized in that the gas can flow in a substantially laminar state in the lateral direction toward the second wall opposed to the first gas transfer device.

Also, an article storage device under a constant atmosphere according to the present invention may include one or more of the following features.

At least one of the storage modules includes gas exhaust means for exhausting gas from the interior of the storage module to the outside, the gas exhaust means being capable of venting gas through the top of the article storage device.

At least one of said storage modules comprising a second gas diffusion device adjacent to said second wall and forming a second chamber with said second wall, wherein said first gas transfer device and said second A space for storing an article is formed between the gas diffusion devices.

The second wall included in one or more storage modules of the storage modules is formed by a second gas diffusion device which is adapted to receive gas from the one or more storage modules and to another storage Module.

The first gas transfer device forms a first chamber with the first wall, and the article storage device further comprises a gas injection means for injecting gas into the first chamber.

A plurality of storage modules which can be stacked to obtain the total storage capacity necessary for storage of the goods, each storage module having a gas discharge means for discharging the gas from the inside of the storage module to the outside, The discharge means has one or more duct / stack devices, one or more of which are located between the two second chambers of the two stacked storage modules and are located above the second chamber of the storage module located below The gas can be discharged into the second chamber of the storage module.

Each storage module includes a first gas transfer device capable of supplying gas to the storage module separately from the other storage modules.

A plurality of storage modules, each of which can be arranged in parallel to obtain the total storage capacity required for storage of the articles, said storage modules being capable of supplying a first gas delivery And a second chamber, and the article storage device further comprises a gas discharge means for discharging the gas from the interior of each storage module to the outside, each gas discharge means being connected to a second chamber of each storage module do.

- further comprising a number of storage modules in communication with one another and arranged in parallel in order to obtain the total storage capacity required for storage of the article, and thus for the parallel storage of these storage modules arranged in parallel, Wherein only the first storage module has a first substantially vertical first wall defining an outer wall of the parallel body and a first gas delivery device adjacent a first one of the second walls, Gas may flow toward the second wall opposite thereto to move to the next storage module in the parallel body.

The last storage module of the parallel body comprises a second gas diffusion device which is adjacent to a first one of the substantially perpendicular first wall and the second wall forming the outer wall of the parallel body And a second chamber together with the first wall having a gas discharging means for discharging the gas flowing into the last storage module from the storage module preceding the last storage module to the outside .

A substantially vertical second wall forming the outer wall of the parallel body comprises a second gas diffusion device which is connected to the last storage module preceding the last storage module of the parallel body And discharges the introduced gas to the outside.

- two or more parallel rows of parallel columns of storage modules in communication with each other are arranged in parallel, only the first storage module of each parallel column has a first gas transfer device, the last storage module of each parallel column Has a second gas transfer device adjacent to and substantially perpendicular to the second wall forming the outer wall of each parallel body and forming a second chamber with the second wall, And a gas discharging means for discharging the gas flowing into the last storage module from the storage module preceding the last storage module to the outside.

- two or more parallel rows of parallel columns of storage modules in communication with each other are arranged in parallel, only the first storage module of each parallel column has a first gas transfer device, the last storage module of each parallel column Is formed by a second gas diffusion device which is capable of discharging the gas entering the last storage module from the storage module preceding the last storage module of each parallel body to the outside.

- a laminate in which two or more rows of parallel bodies of the storage modules arranged in parallel and arranged in parallel are arranged, from the last one of the rows of one parallel body in the stack, The gas can flow to the storage module located above and the gas can also flow to the last module of the row of the top parallel elements of the stack, And the stacking body includes a single gas transfer device for supplying gas to the first storage module in consideration of the flow direction of the gas.

The communication between the two storage modules arranged in parallel is effected by a gas diffusion device forming a common wall between these two storage modules arranged in parallel.

The first gas transfer device of the first storage module of the laminate comprises a first gas diffusion device forming a first chamber with a substantially perpendicular first wall defining an outer wall of the parallel body, And gas injecting means for injecting gas into the first chamber.

The first gas transfer device comprises one or more porous tubes which are open inside the storage module and extend along the first wall.

At least one of the gas diffusion devices is composed of a panel made of a porous material.

At least one of said gas diffusion devices comprises a panel of ceramic, sintered metal, polymer or fabric.

At least one of the gas diffusion devices is constructed of a metal mesh.

The two gas diffusion devices of the at least one of the storage modules are composed of a panel made of a porous material and the thickness of the second gas diffusion device is greater than the thickness of the first gas diffusion device.

The two gas diffusion devices of the at least one of the storage modules are comprised of a panel made of a porous material and the porosity of the second gas diffusion device is lower than the porosity of the first gas diffusion device.

The gas injecting means for injecting the gas into the first chamber comprises an orifice formed in a wall of the storage module.

The gas injection means for injecting gas into the first chamber comprises at least one tube which is open inside the first chamber and has a gas injection orifice, the orifice being connected to the first, substantially vertical, The first wall and the second wall.

The gas injecting means for injecting gas into the first chamber comprises at least one porous tube which is opened into the first chamber.

The present invention also relates to a method of manufacturing an article comprising: one or more storage modules capable of receiving an article to be stored, the substantially vertically parallel and substantially parallelepiped body comprising a first wall and a second wall opposite to each other; And a storage atmosphere forming means capable of forming a storage atmosphere, wherein the storage atmosphere forming means comprises means for storing gas from the first wall, To flow in a substantially laminar flow direction toward the second wall.

As can be understood from the above, it can be understood that according to the method of storing articles under a certain atmosphere according to the present invention, they can be stacked or arranged in parallel to obtain the total storage capacity necessary for storing articles, You can use an array of several storage modules that do not exist.

In the case of using an article storage device including a plurality of storage modules, it is preferable to arrange the article storage devices in parallel, that is, to provide each of the storage modules with a gas inlet, (Such as speed, efficiency, preventing contamination of unrelated storage modules, etc.).

However, in some special cases, particularly considering the number of storage modules used, it is within the scope of the invention to arrange the article storage devices in series and allow the gas to flow only at one point, To flow to another storage module.

According to one embodiment of the present invention, the storage atmosphere forming means comprises a first gas transfer device adjacent to a first one of a first wall and a second wall which are substantially vertical and opposed to each other, A second gas diffusion device forming a second chamber with a second wall, wherein the gas is discharged upward from the arrangement of the storage modules with the aid of one or more duct / chimney devices, and one or more of the duct / chimney devices Is positioned between the second chambers of the two stacked storage modules so that gas is discharged from the second chamber of the lower storage module to the second chamber of the upper module among the two stacked storage modules.

Advantageously, the gas is supplied in one of two flow rates to form a storage atmosphere inside the array of storage modules or storage modules used,

Wherein the open, with a storage module, or the door of a storage module of the arrangement of the storage module use the door is in the use as the atmosphere after the atmosphere control time (t _c) an atmosphere regulating the flow rate (Q _c) for until it is closed the storage module Or a storage module;

- after the atmosphere adjustment time (t _c ) has passed, returning to the maintenance step for supplying the gas to the arrangement of the used storage modules or storage modules with the maintenance flow rate (Q _m ) smaller than the atmosphere control flow rate (Q _c ) The process,

- continuously supplying the gas to the holding flow rate (Q _m ) as long as the door of one of the storage modules or storage modules in the used storage module is not opened

Lt; / RTI >

According to an advantageous embodiment of the invention, the switching to the atmosphere regulating flow rate is triggered as the open door is closed (for example by triggering a time delay relay driving an electrically actuated valve in the gas circuit) .

Other features and advantages of the present invention will become apparent from the following detailed description of several embodiments, which are given by way of non-limitative example, with reference to the accompanying drawings.

In the embodiment shown in FIG. 1, several storage modules (X, Y, Z,...) Are stacked, of which only the storage module X is shown in detail.

As will be described below, the embodiment of FIG. 1 has one gas inlet for each storage module, with the discharge of gas through a second chamber of the stacked storage module (duct / chimney device).

The storage module X (similar to other storage modules stacked thereon) is approximately parallelepiped and thus forms a first wall P _X1 and a second wall P _X2 which are approximately perpendicular.

The storage module X also includes a first gas diffusion device 5 and a second gas diffusion device 6. A space 1 for storing articles is formed between these gas diffusion devices, A shelf 2 is provided.

The first gas diffusion device 5 and the second gas diffusion device 6 are made of a sintered polymer material, in this embodiment, sintered polyethylene. The thickness of the first gas diffusion device 5 is about 2 mm, 2 gas diffusion device 6 has a thickness of approximately 4 mm.

The gas diffusion device may also be fabricated from other materials such as porous ceramics, sintered metal, fabrics (woven fabric, felt, non-woven fabric, etc.), or even metal mesh.

The first gas diffusion device 5 forms a first chamber 3 together with the first wall P _X1 and the second gas diffusion device 6 is connected to the second wall P _X2 Thereby forming the second chamber 4.

The gas is transferred from the external gas supply source (not shown) into the first chamber 3 through the pipe 7 having the gas injection orifice and opening into the interior of the first chamber 3.

It will be appreciated that the gas source can be significantly different depending on the specification of the atmosphere formed in the storage module. For example, in the case of a user who needs to store an article under a nitrogen atmosphere having a certain restriction on the content of residual oxygen in the storage, it is possible to use nitrogen originally in a low temperature state, or nitrogen obtained by separating and absorbing air, This nitrogen has an oxygen content that meets the above limitations.

In this case, the gas injection orifice of the pipe 7 is directed to the first wall P _X1 of the storage module, so that the gas injected as outlined in the figure in the figure 8 flows outwardly and the first gas diffusion And moves back toward the device 5 and moves.

Therefore, the gas injected by the pipe 7 moves along the storage space 1 through the first gas diffusion device 5, passes through the second gas diffusion device 6 and flows into the second chamber 4 do.

The gas is then discharged from the second chamber of the storage module X and discharged through the duct / stack device 10 (which is stacked on top of the storage module X), as shown schematically by arrow 9 in the figure The storage module Z is connected to the second chamber 12 of the module Y through the duct / chimney device 11 connecting the second chamber of the storage module Y and the second chamber of the storage module Z, To the second chamber of the chamber.

It will be appreciated that the duct / stack device that discharges gas from one chamber to another is preferably hermetically sealed to each storage module associated therewith.

Accordingly, the advantageous embodiments of the present invention illustrated in connection with FIG. 1 have the following features and advantages.

Gas flows from the bottom to the top of the article storage device having the arrangement of the storage modules shown and is discharged from the apparatus at the top.

On the other hand, it is possible to isolate the discharge passage 4 from the storage space 1 by means of the second gas diffusion device 6, and in particular to prevent the gas from returning so that air returns from the discharge passage to the storage chamber (A return preventing device).

However, it is also possible to maintain a slight excess pressure in the storage space 1 due to the presence of the second gas diffusion device 6.

Due to the group of " pipe 7 / first gas diffusion device 5 ", the gas leaving the first gas diffusion device can be diffused at a low velocity (preferably a few centimeters per second) have.

The assembly of the "pipe (7) / first gas diffusion device (5) / second gas diffusion device (6)" prevents the injected gas from mixing with the atmosphere of the chamber, , That is, the " piston " effect can be achieved.

It is possible to obtain a nitrogen buffer material in a sufficiently laminar state leaving the gas diffusion device 5 at a low speed toward the second gas diffusion device 6 in the lateral direction without being limited to the following description, 6) acts as an obstacle to stop the movement of the gas through the pressure drop it produces and because the door is opened and there is a zone having an intermediate composition between the air and the nitrogen buffer material, To the second gas diffusion device 6 is released.

Therefore, the air moves toward the second chamber 4 with minimized turbulence generation, thus minimizing the mixing phenomenon, and is directed from the second chamber to the outlet of the article storage device.

If, for example, the gas is injected upwardly from the bottom of the storage module or is sprayed downwardly from the top, the choice of spraying the gas from the side wall of the storage module in accordance with the invention, Can be mounted in the storage module without causing a large change in the flow of the gas.

In one embodiment of the present invention shown in Figure 1, the device for injecting gas into the first chamber 3 is composed of a simple pipe 7 having a jet orifice formed therein. However, other advantageous devices for injecting gas into the first chamber 3 can be devised, without departing from the scope of the present invention, as described in European Patent Application No. 659,515 and European Patent Application No. 686,844, Such devices are described, and the devices disclosed therein are suitable for embodiments of the present invention as gas injection assemblies that can achieve a good level of uniformity across the entire area of the chamber.

Similarly, the case of a gas diffusion device consisting of a combination of a pipe 7 and a gas diffusion device 5 along a first wall of the storage module is illustrated, but it is also possible that the first wall of the storage module (as described hereinabove) _Lt ; / RTI &_gt; such as in the case of a porous tube extending along all or part of the size of the gas stream P &_lt; RTI ID = _0.0 &_gt; _X1 ). ≪ / RTI >

FIGS. 2, 3 and 4 show an article storage apparatus according to another embodiment of the present invention, in which storage modules are stacked or arranged in parallel to form an arrangement. Hereinafter, these embodiments will be briefly described.

As can be understood from reading the description of the embodiment of FIG. 2, the stack of storage modules (X, Y, Z) through a single pipe 7 which opens into the storage module X in the case of the embodiment of FIG. And the gas flows from the laminar flow state substantially in the lateral direction through the storage module X to the second chamber of the storage module X to be supplied to the storage module Y via the duct / And then flows to the storage module Z through the duct / chimney device 11 after passing through the storage module Y in the lateral direction.

Further, in the case of the present embodiment, the gas flows upward from the bottom of the article storage device through the arrangement of the storage module shown and is discharged.

In the case of the present embodiment, it is appropriate to consider the function of each part not to give too strict importance to the terms " first chamber " and " second chamber ". Thus, it can be said that the gas is introduced into the second chamber of the storage module Y from the duct / stack device 10, but also considering that this second chamber is the point at which the gas enters the storage module Y May be thought of as the first chamber of the storage module (Y).

In the case of the embodiment shown in Figure 3, the storage modules X, Y and Z are arranged in parallel and each storage module is provided with a separate gas inlet [pipe 7 open to the first chamber of each storage module , And the gas is discharged from each storage module through the duct / stack device 10, 11, ... connected to the second chamber of the storage module, respectively.

This embodiment is also one of the cases where it is preferable that the gas is discharged from the top of the article storage device.

4, gas is supplied through a single pipe 7 located in the first chamber of the storage module X, so that the storage modules X, Y, Z arranged in parallel communicate with each other . Therefore, the gas flows in the laminar flow state substantially in the lateral direction through the storage module X to the storage module Y, and then through the storage module Y to the storage module Z. [ At this time, the communication between the two storage modules arranged in parallel takes place through a gas diffusion device (13 and 14 in Fig. 4) forming a common wall between these storage modules.

Next, the gas is discharged to the outside of the article storage device through the second chamber of the storage module (Z) and the duct / stack device (10).

However, as described above, it is preferred in accordance with the present invention to supply gas individually to each storage module, and thus the embodiment of Figures 1 and 3 is preferred.

Figures 5 and 6 show two arrangements of a storage module according to the present invention.

The article storage apparatus shown in Fig. 5 comprises a laminate in which two columns of parallel bodies of a storage module arranged in parallel communicate with each other and are arranged in a stacked structure. When considering the direction in which the gas flows, The gas is supplied through a single gas transfer device 50 (not shown in detail in the drawings) that supplies gas to the module.

The gas flows from one storage module of the sub-parallel body to an adjacent storage module to reach the last storage module 50F of this sub-parallel body, and from this last storage module 50F to the last storage module 50F To the storage module 50G in the upper parallel body located immediately above and flows to the last storage module 50L of the upper parallel body. The last storage module 50L is provided with a gas discharging means 51 for discharging the gas flowing into the last storage module 50L from the preceding module of the last storage module 50L to the outside.

This gas discharging means 51 is advantageously provided with a valve.

- The article storage device shown in Fig. 6 is arranged in parallel with four rows (60A to 60F, 70A to 70F, 80A to 80F, 90A to 90F) of a parallel body of storage modules arranged in parallel and communicating with each other, Only the first storage module of each parallel body has a first gas transfer device (corresponding to 60, 70, 80, and 90, respectively, although not shown in detail in the drawings) The vertical wall of the last storage module of the sieve is formed by a second gas diffusion device which distributes the gas flowing from the preceding module of the last module of the parallel body to the last module through the duct / Can be discharged.

It is advantageous to have a valve in each duct / chimney unit.

Fig. 7 schematically shows an entire facility including an article storage apparatus according to the present invention, in which the article storage apparatus is controlled and adjusted.

Fig. 7 shows two article storage apparatuses 20A and 20B according to the present invention, in which each article storage apparatus is supplied with gas by supply lines 21A and 21B, respectively, and these supply lines are electrically operated And is connected to a gas source 23 through a line 22 comprising a valve 24.

Thus, each article storage device 20A and 20B includes an arrangement of one or more storage modules that can be stacked or arranged in parallel.

The facility also includes a storage room or plant-located oxygen probe 25 in which the article storage devices 20A and 20B are located, a data input and processing device 26 (e.g., a programmable controller) And a display device 27.

For better understanding, the following description will be given in more detail.

Dotted lines show the flow of information to the controller 26 (e.g., the residual oxygen content 30A and 30B delivered from the article storage device or the content of residual oxygen in the plant delivered from the oxygen probe 25 30C).

- A dashed line with an arrow at one end or both ends indicates the feedback action of the controller 26 with respect to the components of the plant or a hybrid scenario in which the controller 26 receives information from the component and performs a feedback operation based on this information (hybrid scenario).

As an example, you can see the action (40B) that the controller (26) does against the valve (24) so that the gas is supplied or stopped as needed. Information flows between the controller 26 and the gas supply source 23 in two directions. In this case, the controller 26 not only receives information about the gas supply source (pressure, flow rate, residual oxygen content, etc.) , And also controls the residual oxygen content of nitrogen obtained by separating the air, for example, by permeating or absorbing air, to the gas supply source as necessary. Likewise, the two-way information flow can be seen between the controller 26 and the PC 27, so that the selected data is constantly transmitted to the PC so that the user can constantly monitor (nitrogen consumption, A change in the residual oxygen content with the passage of time in the atmosphere, a time for adjusting the atmosphere, etc.), and when a drift is observed in the opposite direction, a warning signal is transmitted to the controller so that appropriate action can be performed.

Therefore, it is possible to control (supervise) the storage and safety conditions of the entire article storage device assembly through the facility including the article storage device due to the excellent operation of the article storage device according to the present invention It is understood that it is also possible to provide a remote monitoring function (to transmit data periodically, or in some cases, to an access unit somewhat remote from the user's location) have.

The application of the present invention is illustrated by the following operating conditions, taking the equipment shown in FIG. 1 including two stacked storage modules as an example.

- The internal volume of each storage module is 27 liters, each equipped with a dedicated nitrogen (originally low temperature nitrogen) inlet, and the flow rate is approximately 2 Nm ³ / h.

Each storage module has two porous gas diffusion apparatuses (5 and 6 in Fig. 1) made of polyethylene having a porosity of 40 microns, the thickness of the gas diffusion apparatus 5 is 2 mm, while the gas diffusion apparatus (6) is 4 mm.

The second chamber of the storage module at the bottom and the second chamber of the storage module thereon are connected by the duct / chimney device.

The results obtained under these operating conditions are summarized as follows.

- After the door (eg the door of the bottom storage module) was opened, the oxygen content of the atmosphere in the storage module changed from 21% to less than 100 ppm per liter in 4 minutes.

After the same door was opened, the dew point of the atmosphere in the storage module (representing the water vapor content) changed from + 12 ° C to -27 ° C in about 5 minutes.

Thus, the performance obtainable with the present invention is not only fully compatible with short-term storage conditions, that is, when doors are opened frequently, but also with medium to long-term storage, It can be seen that the moisture is not absorbed. Also, in the case of applications where the specification of the atmosphere is less stringent (for example, when the limit of residual oxygen content is not 100 ppm but 1000 or 2000 ppm), the atmosphere re-adjustment time is very fast so as to be only 3 minutes, Has been found to be perfectly suited to the operation of the case of a plurality of openings.

Also, according to the present invention, by contacting electronic components or electronic circuits at ambient temperature with the neutral gas for different times (typically several hours to 48 hours) depending on the characteristics of each electronic component or electronic circuit, a "popcorn" phenomenon The inventors have discovered another advantage of the present invention from the fact that the electronic components are dried as evidenced by the reduction in the number of the electronic components.

Although the present invention has been described in connection with several embodiments, the present invention is not so limited and may make modifications and variations in a manner that is obvious to those skilled in the art. Accordingly, the present invention is specifically illustrated with respect to the performance and advantage of the inert gas spraying. However, considering all the various results described above, the present invention can be applied to, for example, the field of using N ₂ / CO ₂ And the like.

Claims (42)

(X, Y, Z,...) Capable of receiving an article to be stored, storage atmosphere forming means (5, 7) capable of forming a storage atmosphere inside the one or more storage modules An apparatus for storing an article under a constant atmosphere, comprising: Wherein at least one of the storage modules is a substantially parallelepiped and comprises a first wall (P _X1 ) and a second wall (P _X2 ) that are substantially perpendicular and opposed to each other, (P _X1 ) adjacent to the first gas transfer device (5, 7), the first gas transfer device having a gas flow direction substantially in a lateral direction from the laminar flow state toward the second wall (P _X2 ) And the flow rate of the refrigerant can be made to flow. 2. The apparatus of claim 1, wherein at least one of the storage modules includes gas exhaust means (10) for exhausting gas from the interior of the storage module to the outside, Is discharged to the outside. 3. A device according to claim 1 or 2, wherein at least one of the storage modules comprises a second gas diffusion device (6) which forms a second chamber (4) with the second wall , And a space (1) for storing an article is formed between the first gas transfer device and the second gas diffusion device. 3. The apparatus of claim 1 or 2, wherein the second wall included in at least one of the storage modules is formed by a second gas diffusion device, And to pass from the module to another storage module disposed in parallel with the storage module. 3. The apparatus according to claim 1 or 2, wherein the first gas transfer device forms a first chamber (3) together with the first wall, and the article storage device comprises gas injection means (7). ≪ / RTI > 5. The apparatus according to claim 3 or 4, wherein the first gas transfer device forms a first chamber (3) together with the first wall, and the article storage device comprises gas injection means for injecting gas into the first chamber (7). ≪ / RTI > 7. The system of claim 3 or 6, further comprising a number of storage modules (X, Y, Z) that can be stacked to obtain the total storage capacity required to store the article, (10) for discharging the gas from the inside of the stacking apparatus to the outside, the gas discharging means having one or more duct / stack devices (10, 11) Characterized in that the gas can be discharged from the second chamber (4) of the storage module located at the bottom into the second chamber (12) of the storage module located at the upper part by being positioned between the two second chambers of the module Goods storage. 8. The article storage apparatus according to claim 7, wherein each storage module includes a first gas transfer device capable of supplying gas to the storage module separately from the other storage modules. 7. The system of claim 3 or 6, further comprising a number of storage modules (X, Y, Z) that can be arranged in parallel to obtain the total storage capacity required to store the goods, A first gas transfer device 7 and a second chamber which can supply gas to the storage module separately from the module, and the article storage device includes gas discharge means for discharging the gas from the inside of each storage module to the outside Wherein each gas discharging means is connected to a second chamber of each storage module. 4. The apparatus according to any one of claims 1 to 3, further comprising a number of storage modules (X, Y, Z) which can be arranged in parallel and in communication with one another to obtain the total storage capacity required for storage of the article, Accordingly, a first storage module and a last storage module are defined in a parallel body of the storage modules arranged in parallel, and only the first storage module forms a substantially vertical first wall and a second wall forming the outer wall of the parallel body (7) adjacent to the first wall, the first gas transfer device (7) being configured such that the gas flows towards the second wall (13) opposite to it, to the next storage module Wherein the storage device is capable of moving the storage device. 11. The apparatus of claim 10, wherein the last storage module (Z) of the parallel body includes a second gas diffusion device, the first gas diffusion device including a first wall substantially perpendicular to the outer wall of the parallel body, Adjacent to the first wall of the wall and forming a second chamber with the first wall from the storage module (Y) preceding the last storage module (Z) to the last storage module (Z And a gas discharging means (10) capable of discharging the gas introduced into the space (10) to the outside. 11. The apparatus of claim 10, wherein the substantially vertical second wall forming the outer wall of the parallel body comprises a second gas diffusion device, wherein the second gas diffusion device comprises a storage module preceding the last storage module of the parallel body And the gas flowing into the last storage module is discharged to the outside. 13. The method according to any one of claims 10 to 12, wherein the first gas transfer device of the first storage module of the parallel body forms a first chamber with a substantially perpendicular first wall forming the outer wall of the parallel body Wherein the article storage device further comprises gas injection means (7) for injecting gas into the first chamber. 4. The apparatus according to any one of claims 1 to 3, wherein two or more rows (60A to 60F, 70A to 70F, ...) of parallel bodies of the storage modules communicating with each other and arranged in parallel are arranged in parallel , Only the first storage modules 60A, 70A, ... of the respective parallel bodies are connected to the first gas transfer device (not shown) adjacent to the first one of the first and second walls, Characterized in that the first gas transfer device is capable of causing gas to flow toward the second wall (13) opposite thereto, to move to the next storage module in the parallel body The article storage device under a certain atmosphere. 15. The method of claim 14, wherein the last storage modules (60F, 70F, ...) of each parallel body are adjacent to and substantially perpendicular to the second wall forming the outer wall of each parallel body The second chamber includes a gas discharging means for discharging the gas flowing into the last storage module from the storage module preceding the last storage module of the parallel body to the outside And a storage unit for storing the product. 15. The method of claim 14, wherein a second wall of each of the last storage modules (60F, 70F, ...) of each parallel body is formed by a second gas diffusion device, And the gas flowing into the last storage module from the preceding storage module can be discharged to the outside. 17. A method according to any one of claims 14 to 16, wherein the first gas transfer device of the first storage module of each parallel body forms a first chamber with a substantially vertical first wall defining an outer wall of the parallel body Wherein the article storage device further comprises gas injection means (7) for injecting gas into the first chamber. The laminate according to any one of claims 1 to 3, comprising a laminate in which two or more rows (50A to 50F, 50G to 50L) of parallel bodies of the storage modules communicating with each other and arranged in parallel are arranged and stacked , The gas may flow from the last storage module 50F among the rows of one parallel body in the stack to the storage module 50G located above the last storage module 50F, Gas can flow to the last module 50L of the sieve column and this last module 50L is provided with a gas discharging means 51 for discharging the gas flowing from its leading module to its last module 50L to the outside Wherein the stack includes a single gas transfer device (50) for supplying gas to a first storage module (50A) in consideration of the flow direction of the gas. 19. The apparatus of claim 18, wherein the first gas transfer device of the first storage module of the stack forms a first chamber with a substantially vertical first wall defining an outer wall of the parallel body, Further comprising a gas injection means (7) for injecting a gas into the first chamber. 20. A method according to any one of claims 10 to 19, characterized in that the communication between the two storage modules arranged in parallel is by means of a gas diffusion device forming a common wall between these two storage modules arranged in parallel Characterized in that the article storage device under a certain atmosphere. 18. The article storage apparatus according to any one of claims 10 to 17, wherein each last storage module of the parallel body of the storage module is associated with a gas discharge means with a valve. 22. The apparatus according to any one of claims 1 to 21, wherein the first gas transfer device comprises at least one porous tube which is open inside the storage module and extends to all or a part of the dimension of the first wall Characterized in that the article storage device under a certain atmosphere. 8. The article storage apparatus according to any one of claims 3 to 7, wherein at least one of the gas diffusion apparatuses comprises a panel made of a porous material or a metal mesh. 24. The article storage apparatus according to claim 23, wherein at least one of the gas diffusion apparatuses is constituted by a panel made of a ceramic, a sintered metal, a polymer or a fabric. 7. The apparatus of claim 6, wherein the two gas diffusion devices of at least one of the storage modules are comprised of a panel of porous material, the thickness of the second gas diffusion device is greater than the thickness of the first gas diffusion device Wherein the storage device is a storage device. 7. The apparatus of claim 6, wherein the two gas diffusion devices of the at least one of the storage modules are comprised of a panel of porous material, wherein the porosity of the second gas diffusion device is lower than the porosity of the first gas diffusion device Wherein the storage device is a storage device. The gas ejecting apparatus according to any one of claims 5, 6, 13, 17, and 19, wherein the gas ejecting means formed by the first gas delivering device for ejecting the gas into the first chamber comprises: And an orifice formed on one wall of the storage module. 20. The gas-discharging device according to any one of claims 5, 6, 13, 17, and 19, wherein the gas injecting means, which is formed by the first gas-moving device and injects gas into the first chamber, Characterized in that the orifice is oriented towards a first one of the first and second walls which are substantially perpendicular and opposed to one another of the storage module, the orifice being open in the first chamber and having a gas injection orifice And a storage device for storing the article. 20. The apparatus according to any one of claims 5, 6, 13, 17, and 19, wherein the gas injection means, which is formed by the first gas transfer device and injects gas into the first chamber, And at least one porous tube opened into the first chamber. (X, Y, Z, and Z) capable of accommodating an article to be stored, the substantially parallelepiped comprising a first wall (P _X1 ) and a second wall (P _X2 ) And storing atmosphere forming means (5, 7) capable of forming a storage atmosphere inside the one or more storage modules, the method comprising the steps of: Wherein the gas flows from the first wall to the second wall facing the first wall in a laminar flow state substantially in a lateral direction. 31. The method of claim 30, wherein several storage modules (X, Y, Z) are used that are stacked or arranged in parallel to obtain the total storage capacity required to store the article. 32. The method of claim 31, wherein gas is supplied to each module separately from other modules. 33. The method of claim 30 or 32, further comprising supplying a gas to form a storage atmosphere within the array of storage modules or storage modules used, Wherein the open, with a door of a storage module of the arrangement of the storage module or the storage module using the door is in the use of the atmosphere for adjusting the flow rate (Q _c) during the standby after the atmosphere control time (t _c) until it is closed the storage module or A step of injecting a gas into an arrangement body of the storage modules, A step of returning to a holding step of supplying gas to the used storage module or the array of storage modules with a holding flow rate Q _m smaller than the atmosphere controlling flow rate Q _c after the atmosphere adjusting time t _c is over and, A step of continuously supplying the gas to the holding flow rate Q _{m as} long as the door of one of the storage modules or the storage modules in the used storage module is not opened; And storing the article in a predetermined atmosphere. 34. The method of claim 33, wherein the switching to the atmospheric regulating flow rate is triggered automatically as the door is opened. 35. A method according to any one of claims 30 to 34, wherein the content of a given component is controlled (26, 27) in the atmosphere of the storage space of the at least one storage module. A method according to any one of claims 30 to 35, wherein the content of a given component in the atmosphere of the storage space of the at least one storage module is adjusted (26, 27). 37. The method of claim 35 or 36, wherein the at least one storage module is remotely monitored for changes in the content of a given component in the atmosphere of the storage space. 37. The method according to any one of claims 30 to 37, wherein the article is an electronic circuit or an electronic part. 39. The method of claim 38, wherein the storage atmosphere in contact with the article causes the article to dry at ambient temperature. 40. The method of claim 38 or 39, wherein the storage atmosphere is a neutral gas. 41. The method of claim 40, wherein the neutral gas used is essentially nitrogen at a low temperature. 41. The method according to claim 40, wherein the neutral gas used is nitrogen obtained by separating air by permeation or absorption.