法国专利FR3046941A1 AIR FILTRATION SYSTEM FOR ELECTRIC CABINET

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专利摘要:
The invention relates to an air filtration system (2) for electric casing (1), comprising at least one filtration element (Fi) arranged to filter a stream of air injected into said envelope (1) by means of a ventilation device (3), said system (2) also comprising: - a plurality of independent filtering cells Ci, with i ranging from 1 to n and n greater than or equal to 3, each filtering cell Ci having a variable filtration capacity over time, and in that - each filter cell Ci, with i greater than or equal to 2, is made active to filter a portion of the air flow when the sum of the filtration capacities of the cells ranging from C1 to Ci -1 becomes lower than a determined threshold.
公开号:FR3046941A1
申请号:FR1650521
申请日:2016-01-22
公开日:2017-07-28
发明作者:Josep Lopez；Alain Perrin
申请人:Schneider Electric Industries SAS；
IPC主号:

专利说明:

Technical field of the invention
The present invention relates to an air filtration system for an electric envelope.
State of the art
For reasons of energy efficiency, it is now necessary to take into account the electrical energy consumed for the heat dissipation of electrical appliances housed in an electrical enclosure, such as for example an electrical cabinet. For this heat dissipation, the electrical envelope generally comprises an air inlet on which is positioned a ventilation device intended to promote the injection of air into the envelope to cool the electrical appliances and an air outlet. to vent hot air outside the envelope. To avoid bringing dust or other polluting particles inside the envelope, a filter is positioned at the air inlet of the envelope. This filter is for example composed of a cellular material responsible for collecting the particles coming from the outside during the injection of air into the envelope and thus to allow the injection of a "clean" air into the electric envelope. To ensure efficient cooling of electrical appliances, the air flow injected into the enclosure must always be sufficient.
In recent installations, to improve the cooling capacity of the devices, it is proposed to increase the number of fans and to extend the active filtration area. The air flow injected into the cabinet is therefore more important. In this type of installation, several ventilation cells, each provided with a fan and a filter, are for example arranged adjacently.
With such a ventilation architecture, all filters are used at the same time. They can therefore wear out at the same rate or with disparities, making the maintenance of the architecture more complicated. For such an architecture, different maintenance scenarios of the filtration system can be implemented, but these are never completely satisfactory. These different scenarios are as follows: - An operator can wait until all the filters are sufficiently worn to replace them all at the same time. However, this can lead to a significant decrease in the cooling capacity of the architecture if the filters show excessive wear. - An operator can replace each filter independently depending on its level of fouling, but this requires a regular check of the level of clogging filters.
An operator can replace all the filters at the same time before they are too worn out. This generates a higher cost and still requires regular check-ups.
It should be noted that in the event of a significant decrease in the cooling capacity due to too much clogging of the filters, two distinct situations may occur:
In a first situation, the flow of injected air becomes insufficient and the electrical devices will then tend to heat up, which can cause malfunctions, their shutdown or breakage in case of overheating.
In a second situation, the airflow required to properly cool the electrical devices housed in the envelope is maintained but increases the demand on the ventilation device, which in the long term may affect its service life.
It is therefore necessary to take into account the level of fouling of the air intake filters to clean or replace them at the appropriate time, before one of the two situations described above occurs.
The object of the invention is to propose an air filtration system for electric casing which makes it possible to overcome the disadvantages of the state of the art listed above.
Presentation of the invention
This object is achieved by an air filtration system for electric casing, comprising at least one filter element arranged to filter a stream of air injected into said casing by means of a ventilation device, said system comprising: independent filtration cells Ci, with i ranging from 1 to n and n greater than or equal to 3, each filter cell Ci having a variable filtration capacity over time, each filtering cell Ci, with i greater than or equal to 2, is made active to filter a portion of the air flow when the sum of the filtration capacity of the cells from C1 to C1-1 becomes less than a determined threshold.
According to a feature, each filter cell Ci is arranged to be activated by mechanical effect when the inlet air flow has a pressure which becomes greater than a determined value, said determined value being dependent on said filtration capacity threshold of the cells C1 at Ci-1.
According to another feature, each filter cell Ci comprises a valve movable between an open position and a closed position, said valve being calibrated to move towards its open position when the pressure of the inlet air flow becomes greater than said determined value. .
According to another feature, the valve is mounted to pivot about an axis.
According to another feature, each cell comprises a latch arranged to lock the valve in the closed position.
According to a first variant embodiment, in each cell, the filter element is housed in the cell, upstream of the valve.
According to a second variant embodiment, in each cell, the filter element is positioned downstream of the valve.
Advantageously, each filtering cell may for example comprise a sensor arranged to take a first state corresponding to the deactivated state of the filtration cell or a second state corresponding to the activated state of the cell. The system then comprises, for example, a processing unit connected to each sensor and arranged to recover the state of each sensor.
Advantageously, the processing unit comprises a calculation module arranged to calculate a duration flowing between two successive activations of two filtration cells.
Advantageously, the processing unit comprises a module for predicting the moment of replacement of the filter element from the duration calculated by the calculation module. The invention also relates to an electrical envelope intended to house electrical appliances and comprising an air inlet, an air outlet, a ventilation device arranged to promote the injection of air through the air inlet of the room. envelope and a filtration system according to that defined above and positioned at the air inlet, upstream of the ventilation device relative to the direction of injection of air into the envelope.
BRIEF DESCRIPTION OF THE DRAWINGS Other characteristics and advantages will appear in the following detailed description with reference to the accompanying drawings in which: FIG. 1 is a diagrammatic and side view of an electrical envelope on which the control system is positioned. 2A and 2B show diagrammatically the air filtration system of the invention, shown according to two distinct embodiments, FIGS. 3A to 3E illustrate the operating principle of the filtration system of the invention. In the air of the invention, FIG. 4 represents an advantageous variant embodiment of the air filtration system of the invention.
DETAILED DESCRIPTION OF AT LEAST ONE EMBODIMENT The invention relates to a filtration system 2 used to filter the air injected inside an electrical envelope to cool the electrical devices installed in the envelope.
Referring to Figure 1, we take as an example an electrical casing 1 which has a parallelepiped shape comprising an upper wall 10, a bottom wall 11 and four side walls 12 opposite two by two. Of course, the filtration system of the invention will be able to adapt to all types, all shapes and sizes of electric envelopes. The electrical enclosure 1 is intended to house electrical appliances 6, for example fixed on rails, and comprises an air inlet 4 through which air is injected into the interior of the electrical enclosure 1 and an outlet air 5 to discharge hot air to the outside of the electrical enclosure 1.
A ventilation device 3 is positioned on the air inlet 4 of the envelope. When activated, it generates a flow of air that is injected inside the envelope 1.
The filtration system 2 of the invention is positioned on the air inlet 4, upstream of the ventilation device 3, with respect to the direction of injection of air into the envelope. The filtration system is intended to filter the flow of air injected via the air inlet into the envelope through the ventilation device 3. The output of the filtration system is connected to the air intake of the envelope 1.
In the remainder of the description and in the appended figures, it will be considered that the air is injected into the envelope, thus at the outlet of the filtration system 2, according to a constant flow rate Q (indicated "Q is" in the figures ) and at a constant pressure P (indicated "P este" in the figures).
In FIG. 1, the electrical envelope provided with the filtration system of the invention is shown in side view and has, without limitation, the following arrangement: The air inlet and the air outlet are shown on two opposite side walls 12 perpendicular to the plane of the drawing.
The filtration system 2 is fixed on a side wall 12 of the casing, outside the casing 1.
The ventilation device is positioned downstream of the filtration system 2 with respect to the direction of injection of air into the envelope.
Of course, this arrangement is given by way of example and any other arrangement could be provided, in particular with the air inlet and the air outlet on the two other opposite side walls or by using the wall upper for the air inlet or outlet.
According to the invention, with reference to FIGS. 2A and 2B, the filtration system 2 comprises several independent and separate filtering cells Ci (with i ranging from 1 to n and n preferably greater than or equal to 3 ). Depending on the size of the envelope, the number n of cells Ci will for example be adapted to adjust the cooling capacity. By independent cell is meant that each cell is partitioned with respect to the others and is capable of being traversed by a flow of air distinct from that which passes through each other cell. Each cell will include an air inlet opening to the outside and an air outlet opening to the air inlet of the electrical envelope. A chamber may be arranged between the air inlet of the envelope and the air outlets of the cells. As described below, the input and / or the output of each cell may initially be closed by a valve.
Each filtration cell Ci comprises a filtration element Fi designed to filter the flow of air passing through the cell. Each filter element may be independent and removable or be an area of a single larger filter element shared between several filtration cells. As shown in the accompanying figures, a single filter element may for example be used for all the filtration cells, this filter element being shared in as many filtration zones as filtration cells present in the system. For the sake of simplification, we will discuss in the following description of several independent filtration elements Fi, each associated with a separate filter cell Ci.
The filtration system more specifically comprises: a main filtration cell C1 which is initially active and which is traversed by all the airflow Q created by the ventilation device when all the other filtration cells are still inactive. Incrementally activated filtration cells, designated C2 to Cn, which are incrementally activated as the degree of fouling of the filtration elements F 1 of the already activated filtration cells changes.
In the accompanying figures, by way of example and without limitation, the filtration system 2 of the invention is shown with five filtration cells.
The incrementally activated C2-Cn filtration cells are activated as follows. For an inactive Ci cell, it becomes active when the filtration capacity of the C1 to C1 cells becomes insufficient, that is to say when all the F1-F1-1 filtration elements associated with these C1 cells to Ci-1 present an overall level of fouling which exceeds a determined threshold. When this global fouling level threshold is exceeded, at least one new filtration cell is activated in order to divide all the airflow generated by the ventilation device on a larger number of cells, thus increasing the filtration area. of the system and to maintain the filtration capacity at a sufficient level. As long as the system has sufficient filtration capacity by the incremental activation of filter cells, it will not necessarily be necessary to replace the filter elements. In addition, if the ventilation device 3 is controlled to generate a larger airflow Q, the filtration capacity of the system can be increased by activating several filtration cells simultaneously or at shorter time intervals.
With reference to FIGS. 2A and 2B, an incrementally activated C2-Cn filter cell is composed of, for example, a cavity 20 and is separated from an adjacent filter cell by walls 200. Each incrementally activated filtration cell comprises a valve 201 which is able to move between a closed position and an open position. When the filtration cell is inactive, the valve 201 is in the closed position and no part of the air flow passes through it. The filtration element associated with the cell can be positioned in two possible variants: upstream of the valve with respect to the direction of injection of the air flow (FIG. 2A), or downstream of the valve with respect to the direction of flow. injection of the air flow (Figure 2B).
The mounting of the filter element upstream of the valve allows in particular to protect the latter from pollution of the external environment.
The mounting of the filter element downstream of the valve makes it possible in particular to limit the jolts of air flow that occur during the start of the ventilation device or during changes in speed control of the ventilation device.
The operation and the features of the invention will be valid regardless of the arrangement of the filter elements with respect to the valves.
The valve 201 may be made in one piece or in several parts. It can move from one position to another, by employing various mechanisms: a pivoting mechanism used to rotate it about an axis 202 if it is in one part or around two parallel axes it is made in two parts, - thanks to a sliding mechanism, slides being provided to allow the sliding of the valve.
In FIGS. 2A and 2B and in a nonlimiting manner, each valve 201 is mounted to pivot about an axis. In these figures, the valve of the cell C2 is shown, in solid lines, in its closed position and, in dotted lines, in its open position. The activation of a cell, by opening the valve, may be implemented according to several distinct variants described below.
In a first variant, the valve 201 of a filtration cell Ci moves from its closed position to its open position by simple mechanical effect. When the filtration capacity of the cells C1 to C1 becomes lower than said determined threshold, the pressure of the air to be injected into the envelope increases, generating a mechanical force sufficient to open the valve 201 of the cell Ci. incremental cells will then be implemented by calibrating the opening of their valves 201 relative to the pressure of the air to be injected into the envelope through the ventilation device. The level of pressure required for the opening of a valve 201 can be adjusted in different ways. It may be for example to ballast the valve appropriately, to adjust the surface of the valve or to adjust the size of the cavity and / or the air inlet duct of the cell. The chosen solution may in particular depend on the type of ventilation device used, it can generate a constant air flow or, using a control electronics, a variable air flow.
In a second variant embodiment, the activation of a filtration cell Ci is controlled by a computer processing unit. When the filtration capacity of the cells C1 to C1 becomes lower than said determined threshold and stored in the processing unit, the processing unit controls the activation of an additional filtration cell Ci. This command will be for example the emission of an electrical signal: - to an electromechanical lock which, when activated, unlocks the valve 201, the opening of the valve being then made by simple gravity or at the using a mechanical member of the spring or actuator type, and / or - to an actuator arranged to actuate the valve 201 from its closed position to its open position.
The determination of the filtration capacity of a cell can be carried out in different ways: - By measuring the level of fouling of the filter element, by any measurement system already known. The processing unit compares the measured level of fouling with a stored fouling threshold. - By measuring the flow rate of the air flow at the outlet of the cell. If the flow rate of the air flow leaving a cell becomes lower than a determined threshold stored in the processing unit, this means that the filter element no longer has sufficient filtration capacity. - By measuring the time of use of the filter element and comparison with an effective normal operating time obtained by manufacturer data or by implementing a learning period. - By any other measurement and / or calculation solution.
Furthermore, whatever the embodiment variant used for the activation of the cell, the valve 201 may be initially locked in its closed position in order to prevent any inadvertent opening. Unlocking the valve 201 may be controlled for example by said processing unit which sends an unlocking electrical signal to an electromechanical lock when the corresponding filter cell is to be activated.
Referring to Figures 3A-3E, a filtration system according to the invention and comprising for example a main filtration cell and four incrementally activated filtration cells, operates as described below. In these figures, the operation is illustrated from the embodiment of Figure 2B but it should be understood that the principle is the same for the embodiment of Figure 2A.
Figure 3A:
Only the main C1 filtration cell is active. All the air flow Q to be injected into the envelope by means of the ventilation device is filtered by the filtration element of the main filtration cell C1.
Figure 3B:
The filtration capacity of the main filtration cell C1 has become less than a determined threshold value, causing an increase in the pressure of the air through the filtration system 2. When the pressure becomes greater than that of the opening threshold of the valve of the cell C2, the valve of this cell C2 opens. The activation threshold of the cell is for example fixed for an air flow rate equal to Q / 2 through the main filtration cell C1. Once the cell C2 activates, a flow of air equal to Q / 2 flows through the main filtration cell C1 and a flow of air equal to Q / 2 passes through the filtration cell C2.
Figure 3C:
The filtration capacity of the main filtration cell and the previously activated filtration cell C2 becomes insufficient and less than the determined threshold value, again causing an increase in the pressure of the air through the filtration system 2. the pressure of the air becomes greater than that of the opening threshold of the valve of the cell C3, the valve of this cell C3 opens. As before, the activation threshold of the cell is for example fixed for an air flow rate equal to Q / 2 for the assembly formed of the main filtration cell C1 and the filtration cell C2. Once the C3 cell activates, a flow of air equal to Q / 4 passes through the main filtration cell C1, a flow of air equal to Q / 4 through the filter cell C2, a flow of Flow air equal to Q / 2 passes through the C3 filtration cell.
Figure 3D:
The filtration capacity of the main filtration cell, the previously activated filtration cell C2 and the C3 filtration cell becomes insufficient and less than the determined threshold value, again causing an increase in the pressure of the air through the filtration system 2. When the air pressure becomes greater than that of the opening threshold of the valve of the cell C4, the valve of this cell C4 opens. As previously, the activation threshold of the cell C4 is for example fixed for a flow of air of flow equal to Q / 2 for the assembly formed of the main filtration cell, the filtration cell C2 and the C3 filtration cell. Once the C4 cell activates, a flow of air equal to Q / 6 through the main filtration cell C1, a flow of air equal to Q / 6 through the filter cell C2, a flow of Flow air equal to Q / 6 passes through the C3 filtration cell and a flow rate of air equal to Q / 2 passes through the C4 filtration cell.
Figure 3E:
The filtration capacity of the main filtration cell, the filtration cell C2, the filtration cell C3 and the previously activated filtration cell C4 becomes insufficient and less than the determined threshold value, again causing an increase in the air pressure upstream of the filtration system. When the pressure of the air becomes greater than that of the opening threshold of the valve of the cell C5, the valve of this cell C5 opens. As previously, the activation threshold of the cell C5 is, for example, set for a flow of air equal to Q / 2 for the assembly formed of the main filtration cell, the filtration cell C2, the C3 filtration cell and C4 filtration cell. Once the C5 cell activates, an airflow flow equal to Q / 8 passes through the main filtration cell, a flow of air equal to Q / 8 passes through the filtration cell C2, an air flow flow rate equal to Q / 8 passes through the filtration cell C3, a flow rate air flow equal to Q / 8 passes through the filtration cell C4 and a flow rate air flow equal to Q / 2 passes through the filtration cell C5.
When the assembly formed by all the cells of the system has a filtration capacity lower than a determined threshold, for example corresponding to a flow of air with a flow rate lower than Q / 2, it will be necessary to replace the filtration elements.
According to an alternative embodiment of the invention shown in FIG. 4, the filtration system 2 comprises a sensor 203 associated with each incrementally activated C2-Cn filtration cell, for detecting the instant of activation of the cell. The system 2 further comprises a CPU processing unit comprising a plurality of inputs, each associated with a separate sensor 203 for taking the state of each sensor. The processing unit comprises a calculation module arranged to determine the replacement moment T_Fi of each filter element Fi from the time elapsing between two successive cell activations.

权利要求:
Claims (12)
[1" id="c-fr-0001]
An air filtration system (2) for an electric envelope (1), comprising at least one filtration element (Fi) arranged to filter a stream of air injected into said envelope (1) by means of a filtering device. ventilation (3), said system (2) being characterized in that it comprises: - a plurality of independent filtering cells Ci, with i ranging from 1 to n and n greater than or equal to 3, each filtering cell Ci having a capacity variable filtration over time, and in that - each filter cell Ci, with i greater than or equal to 2, is made active to filter a portion of the air flow when the sum of the filtration capacity of cells ranging from C1 to Ci-1 becomes lower than a determined threshold.
[2" id="c-fr-0002]
2. Filtration system according to claim 1, characterized in that each filtering cell Ci is arranged to be activated by mechanical effect when the inlet air flow has a pressure which becomes greater than a determined value, said determined value being dependent on said filtration capacity threshold of C1 to C1 cells.
[3" id="c-fr-0003]
3. Filtration system according to claim 1 or 2, characterized in that each filtering cell Ci comprises a valve (201) movable between an open position and a closed position, said valve being calibrated to move to its open position when the inlet air flow pressure becomes greater than said determined value.
[4" id="c-fr-0004]
4. Filtration system according to claim 3, characterized in that the valve (201) is pivotally mounted about an axis (202).
[5" id="c-fr-0005]
5. Filtration system according to claim 3 or 4, characterized in that each cell comprises a latch arranged to lock the valve (201) in the closed position.
[6" id="c-fr-0006]
6. Filtration system according to one of claims 3 to 5, characterized in that, in each cell, the filter element (Fi) is housed in the cell, upstream of the valve.
[7" id="c-fr-0007]
7. Filtration system according to one of claims 3 to 5, characterized in that, in each cell, the filter element (Fi) is positioned downstream of the valve.
[8" id="c-fr-0008]
8. Filtration system according to one of claims 1 to 7, characterized in that each filter cell comprises a sensor (203) arranged to take a first state corresponding to the deactivated state of the filtration cell or a second state corresponding to the activated state of the cell.
[9" id="c-fr-0009]
9. Filtration system according to claim 8, characterized in that it comprises a processing unit (UC) connected to each sensor (203) and arranged to recover the state of each sensor.
[10" id="c-fr-0010]
10. Filtration system according to claim 9, characterized in that the processing unit (UC) comprises a calculation module arranged to calculate a time flowing between two successive activations of two filter cells.
[11" id="c-fr-0011]
11. Filtration system according to claim 10, characterized in that the processing unit (UC) comprises a module for predicting the moment of replacement of the filter element from the duration calculated by the calculation module.
[12" id="c-fr-0012]
Electrical enclosure (1) for housing electrical appliances and having an air inlet (4), an air outlet (5) and a ventilation device (3) arranged to promote the injection of air by the air intake of the envelope, characterized in that it comprises a filtration system (2) according to that defined in one of claims 1 to 11 and positioned at the air inlet, upstream of the ventilation device (3) with respect to the direction of injection of air into the envelope.

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同族专利:

公开号 | 公开日

JP2017183702A|2017-10-05|

FR3046941B1|2018-01-05|

US20170209822A1|2017-07-27|

EP3195917A1|2017-07-26|

US10279296B2|2019-05-07|

引用文献:

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法律状态:
2017-01-13| PLFP| Fee payment|Year of fee payment: 2 |

2017-07-28| PLSC| Publication of the preliminary search report|Effective date: 20170728 |

2018-01-17| PLFP| Fee payment|Year of fee payment: 3 |

2019-12-17| PLFP| Fee payment|Year of fee payment: 5 |

2021-01-27| PLFP| Fee payment|Year of fee payment: 6 |

2022-01-26| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

申请号 | 申请日 | 专利标题

FR1650521|2016-01-22|

FR1650521A|FR3046941B1|2016-01-22|2016-01-22|AIR FILTRATION SYSTEM FOR ELECTRIC CABINET|FR1650521A| FR3046941B1|2016-01-22|2016-01-22|AIR FILTRATION SYSTEM FOR ELECTRIC CABINET|

EP16204275.8A| EP3195917A1|2016-01-22|2016-12-15|Air filtering system for an electrical enclosure|

US15/399,300| US10279296B2|2016-01-22|2017-01-05|Air filtering system for an electrical enclosure|

JP2017008663A| JP2017183702A|2016-01-22|2017-01-20|Air filtering system for electrical enclosure|

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