FILTER BODY, FILTER ELEMENT, AND FILTER ASSEMBLY

Abstract

A filter body is provided with a filter medium that has filter layers arranged one over the other, wherein each filter layer is provided with at least one active material. The at least one active material may be the same in each of the filter layers. The filter layers are flowed through serially one after another in a through-flow direction of the filter body. The filter body is provided with sensor devices arranged one after another in the through-flow direction of the filter body, wherein each sensor device is arranged between neighboring filter layers so that the sensor devices in the through-flow direction of the filter body determine a sorption capacity of the at least one active material of each filter layer over a service life of the filter body.

Description

BACKGROUND

The present invention concerns a filter body for a filter element, a filter element with such a filter body, and a filter assembly with such a filter element.

Fuel cell filters or pesticide filters often require a precise prediction of their service life. However, this can be indicated only with too high a safety margin for most applications because of the ambient conditions that differ greatly from user to user. However, since such fuel cell filters or pesticide filters are often expensive, it is desirable to realize a service interval that is a long as possible.

KR 2012 0016525 A concerns a filter configuration for an air purifier. The latter comprises various filter stages that are to be flowed through serially, namely an active carbon filter stage, an odor filter stage, a particle filter stage, an antibacterial filter stage, and a HEPA stage. Sensors that are intended to signal an exchange of the respective filter layer are associated with the odor filter and the antibacterial filter, respectively.

The sensors that are associated with the filter layers are thus arranged in through-flow direction one after another but, since the respective filter stages differ in type, no gradual “consumption” of a sorption capacity can be determined; instead, only a binary value for a breakthrough of the respective filter stage is determined thereat.

SUMMARY

Based on this background, it is the object of the present invention to provide an improved filter body for a filter element.

Accordingly, a filter body for a filter element is proposed. The filter body comprises a filter medium that comprises a plurality of filter layers arranged one above the other and a plurality of sensor devices, wherein between two neighboring filter layers a sensor device is arranged, respectively, so that the sensor devices in a through-flow direction of the filter body are arranged one after another in order to determine a sorption or an adsorption capacity of the active material of the individual filter layers over a service life of the filter body. The filter layers comprise each at least one active material, wherein the at least one active material is the same in all filter layers. The filter layers in which the sensor devices are provided can be flowed through serially. The active material may comprise at least one sorbent or adsorption material that is the same in all filter layers.

In the meaning of the invention, “neighboring” not only designates filter layers that immediately adjoin each other but also filter layers that indirectly adjoin each other, i.e., such filter layers between which one or a plurality of additional, in particular sensor-free, filter layers are located. The gist of the invention resides in being able to determine the consumption of the sorption or adsorption capacity of the filter layers not only “binary” for the entire filter body but with a predetermined number of intermediate values which is enabled by arrangement of sensor devices in a plurality of the filter layers.

In order to obtain a measuring precision as good as possible, a sensor device may be provided between each of the neighboring filter layers.

The filter element is, for example an air filter element. For example, the filter element is a fuel cell filter or a pesticide filter. The filter element may be used in motor vehicles, trucks, construction vehicles, watercraft, rail vehicles, agricultural machines or vehicles, or aircraft. The filter element may also be used in immobile applications, for example, in building technology.

The filter medium is, for example a filter paper, a filter fabric, a laid filter material or a filter nonwoven. The filter medium may be produced by a spunbonding or meltblowing method or may comprise such a fiber layer applied onto a nonwoven or cellulose support. Moreover, the filter medium may be felted or needled. The filter medium may comprise natural fibers, such as cellulose or cotton, or synthetic fibers, for example, of polyester, polyvinyl sulfide or polytetrafluoroethylene. The filter medium is for example not folded but flat.

The filter medium or the individual filter layers comprise a sorption agent or a plurality of different sorption agents. Herein, “sorption” is to be understood as processes that lead to accumulation of a substance within a phase or at a boundary surface between two phases. The accumulation within a phase is more precisely referred to as absorption, the accumulation at the boundary surface is more precisely referred to as adsorption. The sorption agent may also be referred to as sorbent or adsorbent. A system of an adsorbed or absorbed, i.e., sorbed, material with the sorption agent may be referred to as sorbate.

The number of filter layers and the number of sensor devices is arbitrary, respectively. For example, a first filter layer, a second filter layer, a third filter layer, a fourth filter layer, and a fifth filter layer are provided. In this context, a sensor device is positioned between the first filter layer and the second filter layer, a sensor device between the second filter layer and the third filter layer, a sensor device between the third filter layer and the fourth filter layer, a sensor device between the fourth filter layer and the fifth filter layer, respectively. The “through-flow direction” is defined as a flow direction of a fluid, in particular air, flowing through the filter body. The through-flow direction is oriented from the raw side of the filter body to the clean side thereof.

The fluid to be filtered or purified is for example air. The fluid to be filtered comprises substances to be removed from the fluid. These substances may be, for example, gas and/or odor substances. For example, the substances can be n-butane, volatile organic compounds (VOC), nitrogen oxides (NOx), sulfur dioxide (SO2), hydrogen sulfide (H2S), ammonia (NH3) and/or formaldehyde (CH2O). The sorption agent or the sorption agents in the different filter layers are suitable to remove these substances that are to be removed from the fluid to be filtered.

Viewed in the through-flow direction, the filter layers are arranged one over the other. The sensor devices, viewed in the through-flow direction, are arranged for example in series or in a row. The sensor devices may also be arranged, respectively, immediately in the filter layer associated therewith. Herein, “sorption capacity” of the respective filter layer is to be understood as the suitability of the respective filter layer to remove the substances, that are contained in the fluid and to be removed therefrom, by sorption from the fluid. By means of the sensor devices, it is detected whether the respective filter layer is still capable of removing the substances to be removed from the fluid or whether the substances to be removed break through the respective filter layer. By means of the sensor devices, it may thus be determined for each filter layer whether the latter still removes the substances to be removed from the fluid or not. In particular, the filter layers comprise a sorption capacity of 100% prior to operation of the filter body. As soon as the substances to be removed break through the respective filter layer, the latter has a sorption capacity of 0%.

Since a plurality of sensor devices are provided and since they are positioned between the filter layers, it is possible to indicate a residual service life of the filter body with a high precision. An exchange of the filter body is required only at the time when a sensor device that is located closest to the clean side of the filter body emits a signal that the filter layer associated with it no longer absorbs or sorbs the substances to be removed from the fluid.

In embodiments, the filter medium is divided into a plurality of individual filter layers that are stacked on top of each other or the filter medium is coiled. In the first mentioned case, the filter body is a stacked body. In the second mentioned case, the filter body is a coil body. In the case the filter medium is divided into a plurality of individual filter layers, the filter medium is of a multi-part configuration. The individual filter layers are stacked on top of each other. In the case the filter medium is coiled, the filter medium may be coiled, for example, onto a support tube or a central tube of the filter medium in a spiral shape.

In embodiments, the active material of the filter layers comprises active carbon, for example untreated active carbon, catalytic active carbon or impregnated active carbon, an ion exchanger, adsorbents, for example potassium permanganate, chemical sorbents, a drying agent and/or an oxidation agent. The individual filter layers in this context are all identically provided with at least one of the aforementioned substances or individual filter layers are provided with different substances. The substances may be glued to the filter medium, for example.

In embodiments, the sensor devices comprise optoelectronic sensors, electrochemical sensors and/or gas sensors. By means of an optoelectronic sensor, for example, by means of a photodiode or photocell, color changes of the filter layers may be detected. A color change may happen when the substances to be removed break through the respective filter layer. For producing a color change, a coloring agent may be provided. By means of an electrochemical sensor or a gas sensor, the substances to be removed from the fluid may be directly detected upon breakthrough through the respective filter layer. The sensor devices form together a sensor unit of the filter body.

In embodiments, each sensor device is designed to provide a binary information whether the filter layer associated with the respective sensor device removes the substances to be removed from the fluid to be purified or whether these substances break through the filter layer. The binary information lies in providing evidence whether the respective filter layer still removes the substances to be removed from the fluid or does so no longer.

In embodiments, the filter body comprises moreover a contact element attached to the filter body which is in operative connection with the sensor devices. The contact element may be, for example, a plug or a bushing. The contact element may be in operative connection with the sensor devices, for example, by means of electrical conduits. However, the operative connection may also be a wireless connection between the sensor devices and the contact element. The contact element is for example configured to engage a corresponding interface of a filter receptacle of the filter element. The interface may be, for example, also a plug or a bushing.

Moreover, a filter element, for example a fuel cell filter or a pesticide filter, with such a filter body is proposed. In addition to the filter body, the filter element may comprise, for example, two end disks between which the filter body is arranged. Moreover, the filter element may comprise a central tube or support tube onto which the filter medium is coiled for forming the filter body. In the case that the filter element is a stacked filter, the filter element may comprise, in addition to the plate-shaped filter body, head bands or lateral bands that surround the filter body like a frame.

Moreover, a filter assembly with a filter receptacle and with such a filter element received in the filter receptacle is proposed. The filter receptacle is for example of a multi-part configuration and comprises at least a cover that may be removed in order to exchange the filter element. The filter receptacle may also be referred to, for example, as a housing or a filter housing.

In embodiments, the filter receptacle comprises an interface by means of which sensor signals of the sensor device are read out. The interface, as mentioned before, may be a plug or a bushing into which the contact element of the filter body is inserted. The interface may however also be directly in operative connection with the sensor devices. For example, the interface is connected by cables to the sensor devices. Alternatively, a wireless connection between the interface and the sensor devices for reading out the sensor signals may be provided.

In embodiments, the sensor devices are attached to the filter receptacle so that the sensor devices upon introduction of the filter element into the filter receptacle penetrate into the filter body and upon removal of the filter element from the filter receptacle are pulled out of the filter body. In this case, the sensor devices are not correlated with the filter body, but with the filter receptacle. The sensor devices may be attached to rod-shaped or lance-shaped elements that upon insertion of the filter element into the filter receptacle penetrate into the filter body. Alternatively, the sensor devices, as mentioned before, may also be associated with the filter body and, for example, can be glued thereto. In this case, the sensor devices are not connected fixedly to the filter receptacle.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a schematic section view of an embodiment of a filter assembly.

FIG. 2 shows a further schematic section view of the filter assembly according to section line II-II of FIG. 1.

FIG. 3 shows a schematic perspective partial section view of an embodiment of a filter element for the filter assembly according to FIG. 1.

FIG. 4 shows a further schematic perspective partial section view of the filter element according to FIG. 3.

FIG. 5 shows a schematic section view of a further embodiment of a filter assembly.

FIG. 6 a further schematic section view of the filter assembly according to the section line VI-VI of FIG. 5.

In the Figures, same or functionally the same elements are provided with the same reference characters, provided that nothing to the contrary is indicated.

DETAILED DESCRIPTION

FIG. 1 shows a schematic section view of an embodiment of a filter assembly 1. FIG. 2 shows a further section view of the filter assembly 1 according to the section line II-II of FIG. 1. FIG. 3 shows a schematic perspective partial section view of an embodiment of a filter element 2 for the filter assembly 1 according to FIG. 1. FIG. 4 shows a further schematic perspective partial section view of the filter element 2. In the following, reference is being had simultaneously to FIGS. 1-4.

The filter assembly 1 may also be referred to as a filter system. The filter assembly 1 comprises a filter receptacle 3 and the filter element 2 that is arranged in the filter receptacle 3. The filter receptacle 3 may also be referred to as a housing or a filter housing. The filter receptacle 3 is for example of a multi-part configuration and comprises at least one removable cover so that the filter element 2 may be exchanged.

The filter assembly 1 for example may be used as a fuel cell filter assembly or as a pesticide filter assembly. For example, the filter assembly 1 may be used in motor vehicles, trucks, construction vehicles, watercraft, rail vehicles, agricultural machines or vehicles, or aircraft. The filter assembly 1 may also be used in immobile applications, for example, in building technology. The filter element 2 is for example suitable to filter air. The filter element 2 for example may be a fuel cell filter or a pesticide filter.

Inside the filter receptacle 3, i.e., in an interior 4 of the filter receptacle 3, the filter element 2 is arranged. In the interior 4, there is also an interface 5 provided whose function will be explained hereafter. The filter element 2 comprises a filter body 6. The filter body 6 is cylinder-shaped, for example circular cylinder-shaped, and may be constructed with rotational symmetry in relation to a central or symmetry axis 7.

In addition to the filter body 6, the filter element 2 may comprise two end disks arranged at end faces at the filter body 6, which are not illustrated in FIGS. 1-4. The end disks may be manufactured of a plastic material. For example, the end disks may be embodied as inexpensive injection molded plastic components. The end disks may also be manufactured of a polyurethane material which is in particular cast in casting molds, for example foamed. The end disks may be connected by casting to the filter body 6. The filter body 6 is arranged between the end disks and may be fused, glued or welded thereto. A support tube or central tube may be received inside the filter body 6. The filter body 6 may be coiled onto this support tube or central tube.

The filter body 6 comprises a filter medium 8. The filter medium 8 is coiled as a coil onto the aforementioned central tube and forms thus a plurality of filter layers 9 to 13 one over the other. The filter medium 8 is, for example, a filter paper, a filter fabric, a laid filter material or a filter nonwoven. For example, the filter medium 8 may be produced by a spunbonding or meltblowing method or may comprise such a fiber layer applied onto a nonwoven or cellulose support. Moreover, the filter medium 8 may be felted or needled. The filter medium 8 may comprise natural fibers, such as cellulose or cotton, or synthetic fibers, for example, of polyester, polyvinyl sulfide or polytetrafluoroethylene. Fibers of the filter medium 8 may be oriented during processing in, at a slant to, and/or transversely to, or randomly in relation to a machine direction.

The respective filter layers 9 to 13 comprise an active material, in particular sorption material. Herein, “sorption” is to be understood as a collective term for processes that lead to an accumulation of a substance within a phase or at a boundary surface between two phases. The accumulation within a phase is referred to more precisely as absorption, and the accumulation at the boundary surface more precisely as adsorption. In particular, the filter layers 9 to 13 each comprise active carbon, for example untreated active carbon, catalytic active carbon or impregnated active carbon, an ion exchanger, drying agent, adsorbents, for example potassium permanganate, chemical sorbents and/or oxidation agents.

In particular, the filter layers 9 to 13 each may also comprise a coloring agent that is operable to generate a color change when the sorption capacity of the respective filter layer 9 to 13 is depleted. Herein, “sorption capacity” is to be understood as the property of the respective filter layer 9 to 13 to filter substances to be removed, for example, gas and/or odor substances, for example n-butane, volatile organic compounds (VOC), nitrogen oxides (NOx), sulfur dioxide (SO2), hydrogen sulfide (H2S), ammonia (NH3) or formaldehyde (CH2O), from a fluid L to be purified, for example air. The respective filter layer 9 to 13 comprises a sorption capacity of 100% prior to use. As soon as the substances to be removed from the fluid L break through the respective filter layer 9 to 13, the latter comprises a sorption capacity of 0%.

In operation of the filter assembly 1, the fluid L to be purified passes from a raw side RO of the filter element 2 through the coiled filter medium 8 to a clean side RL of the filter element 2. The filter body 6 comprises in this context a through-flow direction DR oriented from the raw side RO to the clean side RL. In the through-flow direction DR, the filter layers 9 to 13 are positioned on top of each other.

The filter body 6 comprises moreover a sensor unit 14 that is operable to determine the sorption capacity of the filter layers 9 to 13. The sensor unit 14 comprises a plurality of sensor devices 15 to 18 that are arranged between two neighboring filter layers 9 to 13, respectively. A first sensor device 15 is arranged between the filter layers 9, 10, a second sensor device 16 between the filter layers 10, 11, a third sensor device 17 between the filter layers 11, 12, and a fourth sensor device 18 between the filter layers 12, 13. The sensor devices 15 to 18 may be connected fixedly to the filter body 6. For example, the sensor devices 15 to 18 are glued to the filter body 6. For example, the sensor devices 15 to 18 may be introduced between the filter layers 9 to 13 upon coiling the filter medium 8.

Alternatively, the sensor unit 14 may also be correlated with the filter receptacle 3 so that the sensor devices 15 to 18 are mounted at the filter receptacle 3. In this case, the sensor devices 15 to 18 penetrate into the filter body 6 when introducing the filter element 2 into the filter receptacle 3. Accordingly, the sensor devices 15 to 18 are again pulled from the filter body 6 upon removal of the filter element 2 from the receptacle 3. In this way, the sensor unit 14 upon exchange of the filter element 2 may be reused any number of times. The sensor devices 15 to 18 comprise, for example, optoelectronic sensors, electrochemical sensors, and/or gas sensors. For example, an optoelectronic sensor in the form of a photocell can detect a color change of the respective filter layer 9 to 13.

The sensor devices 15 to 18, viewed in the through-flow direction DR, are arranged one after another or in series. Thus, the sorption capacity of the filter layers 9 to 13 may be determined over a service life of the filter body 6 in a stepped manner. In operation of the filter assembly 1, the fluid L to be purified flows through the filter body 6 in the through-flow direction DR. Accordingly, first the outermost filter layer 13 will lose its sorption capacity. Accordingly, as soon as the substances to be removed from the fluid L break through the filter layer 13, the sensor device 18 emits a corresponding signal. The filter element 2 may however still be used until the sensor device 15 which is closest to the clean side RL emits a corresponding signal. As soon as the sensor device 15 emits the signal that the filter layer 10 no longer comprises sufficient sorption capacity, the filter element 2 should be exchanged. For example, each sensor device 15 to 18 is operable to provide a binary information whether the filter layer 9 to 13 associated with the respective sensor device 15 to 18 removes the substances to be removed from the fluid L to be filtered or whether these substances break through the respective filter layer 9 to 13.

The sensor devices 15 to 18 may be arranged so as to be displaced relative to each other viewed along the symmetry axis 7, as illustrated in FIG. 1. Alternatively, the sensor devices 15 to 18, viewed in the through-flow direction DR, may also be arranged immediately one after another.

As shown in FIG. 4, the filter body 6 moreover may comprise a contact element 19 that is in operative connection with the sensor devices 15 to 18. The contact element 19 may be connected, for example, by means of cables or conductive paths arranged between the filter layers 9 to 13 to the sensor devices 15 to 18. Alternatively, the signal transmission from the sensor devices 15 to 18 to the contact element 19 may also be realized wireless. The contact element 19 is configured to interact with the interface 5 of the filter receptacle 3. For example, the contact element 19 may be a plug that is configured to engage the interface 5 embodied as counter plug or bushing.

FIG. 5 shows a schematic section view of a further embodiment of a filter element 2. FIG. 6 shows a further schematic section of the filter element 2 according to the section line VI-VI according to FIG. 5. The filter element 2 according to FIGS. 5 and 6 differs from the filter element 2 according to FIGS. 1-4 substantially in that the filter medium 8 is not coiled but divided into a plurality of independent filter layers 9 to 13 that are separate from each other and are stacked on top of each other.

The function of the filter element 2 according to FIGS. 5 and 6 corresponds in this context to the function of the filter element 2 according to FIGS. 1-4. As shown in FIGS. 5 and 6, the filter element 2 comprises in addition to the filter body 6 lateral bands 20, 21 as well as head bands 22, 23 that surround the filter body 6 like a frame. A final layer 24, 25 may also be placed on the outwardly positioned filter layers 9, 13, respectively. The final layer 24, 25 may be, for example, a nonwoven filter layer.

In fuel cell filters or pesticides filters, a precise prognosis in regard to service life is required. However, due to the ambient conditions which differ greatly from user to user, this is done for most applications only with too high a safety margin. Since such fuel cell filters or pesticide filters are often expensive, it is desired to provide service intervals as long as possible. By means of the sensor devices 15 to 18 positioned in the filter body 6, a precise prediction of the service life of the filter element 2 is possible. An exchange of the filter element 2 is required only at the time when the sorption capacity of the filter body 6 is almost depleted.

REFERENCE CHARACTERS

• • 1 filter assembly
  • 2 filter element
  • 3 filter receptacle
  • 4 interior
  • 5 interface
  • 6 filter body
  • 7 symmetry axis
  • 8 filter medium
  • 9 filter layer
  • 10 filter layer
  • 11 filter layer
  • 12 filter layer
  • 13 filter layer
  • 14 sensor unit
  • 15 sensor device
  • 16 sensor device
  • 17 sensor device
  • 18 sensor device
  • 19 contact element
  • 20 lateral band
  • 21 lateral band
  • 22 head band
  • 23 head band
  • 24 layer
  • 25 layer
  • DR through-flow direction
  • L fluid
  • RL clean side
  • RO raw side

Claims

1. A filter element comprising: a filter body comprising a filter medium having a plurality of filter layers arranged one over the other, wherein each filter layer comprises at least one active material, and wherein the filter layers are configured to be flowed through in series one after another in a through-flow direction of the filter body; anda plurality of sensor devices arranged in series one after another in the through-flow direction of the filter body, each sensor device positioned between neighboring filter layers and operable to determine a sorption capacity of the at least one active material of a corresponding one of the filter layers;wherein the sensor devices are configured to penetrate into the filter body and to pull out of the filter body.

2. The filter element according to claim 1, wherein the filter layers are individual filter layers of the filter medium that are stacked on top of each other.

3. The filter element according to claim 1, wherein the filter medium is coiled to form the filter layers.

4. The filter element according to claim 1, wherein the at least one active material is selected from the group consisting of active carbon, an ion exchanger, an adsorbent, a chemical sorbent, potassium permanganate, a drying agent, an oxidation agent, and combinations thereof.

5. The filter element according to claim 1, wherein the at least one active material comprises active carbon, untreated active carbon, catalytic active carbon or impregnated active carbon.

6. The filter element according to claim 1, wherein the sensor devices comprise optoelectronic sensors, electrochemical sensors, and/or gas sensors.

7. The filter element according to claim 1, wherein each sensor device is associated with the corresponding one of the filter layers and is operable to emit a binary information indicating whether or not the corresponding one of the filter layers removes a substance to be removed by the filter medium.

8. The filter element according to claim 1, wherein the filter body further comprises a contact element operatively connected to the sensor devices.

9. A filter element comprising: a filter body, wherein the filter body comprises: a filter medium having a plurality of filter layers arranged one over the other, wherein each of the filter layers comprises at least one active material, and wherein the filter layers are configured to be flowed through serially in a through-flow direction of the filter body;a plurality of sensor devices arranged one after another in the through-flow direction of the filter body, each sensor device positioned between two filter layers in the through-flow direction of the filter body to determine a sorption capacity of the at least one active material of a corresponding one of the filter layers over a service life of the filter body;wherein the sensor devices are configured to penetrate into the filter medium of the filter body with the filter element inserted into a filter receptacle and to pull out of the filter medium of the filter body with the filter element removed from the filter receptacle.

10. The filter element according to claim 9, further comprising a contact element operably connected to the sensor devices.

11. The filter element according to claim 10, wherein the contact element is in operative connection with the sensor devices by electrical conduits.

12. The filter element according to claim 10, wherein the contact element is in operative connection with the sensor devices by a wireless connection.

13. The filter element according to claim 10, wherein the contact element is configured to engage a corresponding interface of the filter receptacle.

14. The filter element according to claim 13, wherein the contact element and/or the interface is a plug or a bushing.

15. The filter element according to claim 13, wherein the interface is operable to read a sensor signal of each of the sensor devices.

16. The filter element according to claim 9, wherein the sensor devices are attached to the filter receptacle, wherein the sensor devices are configured to penetrate into the filter medium of the filter body between the two filter layers when the filter element is inserted into the filter receptacle, and wherein the sensor devices are configured to be pulled out of the filter medium of the filter body when the filter element is removed from the filter receptacle.

17. The filter element according to claim 16, wherein the sensor devices are operable to emit a binary information whether or not a corresponding one of the filter layers continues to remove a substance to be removed by the filter medium, and wherein the filter element is removed from the filter receptacle when all of the sensor devices emit the binary information.

18. The filter element according to claim 9, wherein the filter layers are individual filter layers of the filter medium that are stacked on top of each other.

19. The filter element according to claim 9, wherein the filter medium is coiled to form the filter layers.

20. The filter element according to claim 9, wherein the at least one active material comprises active carbon, untreated active carbon, catalytic active carbon or impregnated active carbon.