FILTER INCLUDING RFID LABEL

专利摘要:
a filter assembly including an rfid tag for use in monitoring fluid processing, as well as a system and method for monitoring fluid processing, and a filter for use in the filter assembly are disclosed.
公开号:BR102017023078A2
申请号:R102017023078-3
申请日:2017-10-26
公开日:2018-05-15
发明作者:Paluszewski Paul；Vanzandt Brent；Warmuth Eric
申请人:Pall Corporation；
IPC主号:

专利说明:

"FILTER INCLUDING RFID LABEL" BACKGROUND OF THE INVENTION
[001] RFID tags are used in a variety of industries for a variety of applications. However, there is a need for improved systems and applications including RFID tags.
The present invention provides to alleviate at least some of the disadvantages of the prior art. These and other advantages of the present invention will become apparent from the description as set forth below.
BRIEF SUMMARY OF THE INVENTION
One embodiment of the invention features a fluid assembly comprising (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a generally cylindrical filter comprising a porous filter element. wherein at least the first end of the housing comprises a removable cover and a housing of the first end of the housing, wherein the housing is arranged to produce a fluid flow path through the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna disposed within or on the removable cover wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. - enabling a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the second cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
A method for monitoring fluid processing in a fluid assembly including an RFID tag and an RFID signal generator / controller according to one embodiment comprises: (A) receiving fluid related information passing through a first assembly comprising (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first housing end comprises a removable cover and a housing first end body, wherein the housing is arranged to produce a fluid flow path through the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
In some embodiments of the method, the information comprises any one or more of: filter differential pressure, flow rate and part number of the filter element and a preferred embodiment of the method comprises accessing the Internet using a cloud or enabled device. on the network and receive the information.
In another embodiment, a system for monitoring fluid processing comprises a filter assembly embodiment, a router gateway providing access to the Internet, the router gateway communicating with the generator / controller. RFID signal and at least one cloud or network-enabled device capable of accessing the Internet and receiving information related to the filter set.
In yet another embodiment, a filter for use in a monitoring system comprises a first end cap; a second end cap; a hollow cylindrical porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second filter end and a fastened RFID tag over or near the first end cap or second end cap. BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF DRAWING (S) Figure 1A is an external perspective view of a filter assembly according to one embodiment of the present invention showing a housing having a first end of the housing comprising a removable cover, a housing body and a second housing end, an RFID signal generator / controller, a sensor and a signal device.
Fig. 1B is a cross-sectional view of the filter assembly shown in Fig. 1A, also showing a first end housing body, first, second and third antennas, a third antenna clip, a RFID and a filter.
Figure 1C is an exploded view of the first end of the housing comprising the removable cover including the second antenna (as well as a cable for connection to the third antenna), and a body of the first end of the housing and Figure 1D is a view. lower body of the first end of the housing, also showing the third antenna, and the third antenna clip, prior to the installation of the third antenna, and the third antenna clip on the first end of the housing.
Figure 1E is an exploded view showing the third antenna 903, a third antenna holder, a bushing, and a first cable communicating with the second and third antennas, and Figure 1F is a partial cross-sectional view showing the first antenna, the second antenna, the third antenna, a third antenna clip, a bushing, and a first cable communicating with the second and third antennas in the filter assembly.
Figure 1G is a perspective view of the housing having the first end of the housing, the housing body and the second end of the housing shown in Figure 1A.
Figure 2 is a diagrammatic cross-sectional view showing an arrangement of the first, second and third antennas, the RFID tag and the RFID signal generator / controller in accordance with an embodiment of the present invention.
Figures 3a and 3B are perspective views of illustrative filters including first and second end caps for use in accordance with embodiments of the invention, wherein one of the end caps (showing the first end cap as an end cap closed) is partially trimmed to show the inside of the filter. The filter in figure 3A has a core and the filter shown in figure 3B is without a core.
[3] Figures 3C and 3D diagrammatically show bottom perspective and sectional views where RFID tags are attached to the first (closed) end cap, Figure 3C showing the RFID trapped in a "cavity" in the cap Figure 3 showing the RFID tag fixed in place on the end cap. Figure 3E shows a filter having first and second end caps, including the RFID tag attached to the end cap as shown in figure 3D.
Figures 4A to 4F show bracket mounted RFID tags for use in accordance with embodiments of the invention.
Figure 4A shows a perspective view and Figure 4B shows a top view of a support for use in accordance with an embodiment of the invention. Figure 4C shows a perspective view in which an RFID tag is mounted on the bracket shown in Figure 4A.
Figure 4D shows a perspective view and Figure 4E shows a top view of another support for use in accordance with an embodiment of the invention. Figure 4F shows a perspective view in which an RFID tag is mounted on the bracket shown in Figure 4D.
Figure 5A is a diagrammatic cross-sectional view showing the bracket mounted RFID tag shown in Figure 4C mounted in a filter housing, wherein the RFID tag is facing and is close to the closed end cap. .
[020] Figure 5B is a diagrammatic cross-sectional view showing the bracket mounted RFID tag shown in Figure 4F mounted in a filter housing, where the RFID tag faces and is close to the closed end cap .
Figures 6A and 6B are diagrammatic views showing the transmission of signals through fluid processing systems in accordance with illustrative embodiments of the invention, including the transmission of an RFID signal generator / controller signal (with respect to each of a first filter assembly (lower pressure filter assembly / return line) and a second filter assembly (high pressure filter assembly) through a local router connection port provided with access to the Internet, such that the signal is broadcast to a cloud application or a network application programming interface (API) where an end user can configure access through a secure system to authorized site personnel via any network enabled device The illustrated systems also show sensor nodes comprising miscellaneous assemblies (within the low pressure portion of the hydraulic circuits) with sensor s external to filter sets, where sensors also provide information to the cloud or network application. In the embodiment illustrated in Figure 6A, the sensor node is disposed between a fluid reservoir and the inlet of a feed pump, and in the embodiment illustrated in Figure 6B, the sensor node is disposed between the outlet of the pressure filter assembly. and the fluid reservoir. The embodiments of the systems illustrated in Figures 6A and 6B may be operated in a similar manner with the same components.
Figure 6C is a diagrammatic view showing signal transmission through a fluid processing system according to another illustrative embodiment of the invention, wherein the system includes a single filter assembly (high pressure filter assembly). . Similar to the illustrative systems shown in Figures 6A and 6B, Figure 6C shows the transmission of a signal from the RFID signal generator / controller via a local router gateway provided with internet access such that the signal It is broadcast to a network application programming interface (API) or a cloud application where an end user can configure access through a secure system to authorized site personnel via any network or cloud enabled device. The illustrated system also shows a sensor node comprising a diverse array (within the low pressure portion of hydraulic circuits) with sensors external to the filter assembly, wherein the sensors also provide information for network or cloud application.
DETAILED DESCRIPTION OF THE INVENTION
According to one embodiment of the present invention, a fluid assembly is provided comprising (a) a housing having a first end of the housing, a housing body and a second end of the housing, the housing containing a generally cylindrical filter. comprising a porous filter element, wherein at least the first end of the housing comprises a removable cover and a first end body of the housing, wherein the housing is arranged to produce a fluid flow path through the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the second cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID tag for RFID signal generator / controller via third antenna, second antenna and first antenna.
[024] In one embodiment, the filter assembly further comprises (viii) a second cable having a first end of the second cable and a second end of the second cable, wherein the first end of the second cable is coupled to the generator / controller of the second cable. RFID signal, and the second end of the second cable is coupled to the first antenna.
In another embodiment, a system for monitoring fluid processing comprises a filter assembly embodiment, a router gateway providing internet access, the router gateway communicating with the signal generator / controller. RFID, and at least one network or cloud enabled device capable of accessing the internet and receiving information related to the filter set.
In another embodiment, the system for monitoring fluid processing comprises (A) a fluid assembly comprising (a) a housing having a first end of the housing, a housing body and a second end of the housing, the housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first end of the housing comprises a removable cover and a housing of the first end of the housing, wherein the housing is arranged to produce a fluid flow path through the housing. filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna; (B) a router gateway providing internet access, the router gateway communicating with the RFID signal generator / controller, and (C) at least one network or cloud enabled device capable of accessing the Internet and receive information related to the filter set.
In some embodiments, the system comprises first and second filter assemblies, each filter assembly comprising (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a filter generally cylindrical comprising a porous filter element, wherein at least the first end of the housing comprises a removable cover and a housing of the first end of the housing, wherein the housing is arranged to produce a fluid flow path through the filter. such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
If desired, system embodiments may further comprise one or more sensor nodes, which may be arranged external to the filter assembly or assemblies, wherein the sensor node comprises one or more sensors, such as, for example, a sensor. fluid condition sensor and / or a water sensor (eg to monitor dissolved water).
[029] A method for monitoring fluid processing in a fluid assembly including an RFID tag and an RFID signal generator / controller according to one embodiment comprises: (A) receiving fluid related information passing through a first assembly comprising (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first housing end comprises a removable cover and a housing first end body, wherein the housing is arranged to produce a fluid flow path through the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) the RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to, and wirelessly receive a signal from the RFID tag; (vi) the RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
[030] In some embodiments of the method, the information comprises any one or more of: filter differential pressure, flow rate and filter element part number, and a preferred embodiment of the method comprises accessing the Internet using a cloud or enabled device. on the network and receive the information.
[031] A method for monitoring fluid processing in a filter assembly including an RFID tag and an RFID signal generator / controller communicating with a router gateway providing internet access, the method comprising accessing the internet using a cloud or network enabled device and receiving fluid related information passing through a fluid assembly comprising (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first end of the housing comprises a removable cover and a housing of the first end of the housing, wherein the housing is arranged to produce a fluid flow path through such that fluid is filtered as it passes through the pore filter element only; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) the RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the second cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
In some embodiments of the method, the information comprises any one or more of the following: filter differential pressure, flow rate and part number of the filter element.
In yet another embodiment, a filter for use in a monitoring system comprises a first end cap, a second end cap, a hollow cylindrical porous filter element comprising a first filter end and a second filter end, the first end cap is sealed at the first end of the filter and the second end cap is sealed at the second end of the filter and an RFID tag is attached to or near the first end cap or the second end cap.
[034] Embodiments of the invention provide for wireless transmission of an RFID signal through an air gap between a fixed electronics enclosure and a removable component housing an RFID tag reader antenna in a fluid processing system. . Advantageously, the maintenance of a removable component (e.g. a filter housing cover and / or a filter element) of a filter assembly may be performed without disconnecting / reconnecting one or more cables and / or wires ( particularly external cables and / or wires) and / or without the need to “fit” or carefully align one or more connections between a fixed electronics module and the removable component. In view of the proximity of the first and second antennas, and the proximity of the third antenna and the RFID tag, there is no need to increase the signal. Signals can be passed (for example, the RFID tag can be read) without compromising a sealing surface of the closing gasket. Problems associated with attempting to read a signal "through" a metal filter housing can be avoided. There is no need to drain the filter container and open the housing to confirm the presence of the filter element, element part number, element quality and / or service hours. What's more, manufacturing is simplified by eliminating expensive, fault-prone housing cabling and penetrations, and related hardware.
If desired, one or more of any of the following may be monitored and / or determined: the presence of a filter element, the part number of the filter element, the quality of the element, hours of service life of the filter (operating time), differential pressure, water ingress and fluid condition (eg contamination, dilution, oxidation, additive depletion and / or presence of particulate (s), fluid temperature, fluid viscosity, fluid, fluid dielectric and flow rate). In some embodiments, established filter element performance points and / or operating limits are stored and monitoring includes determining whether one or more stored performance points and / or operating limits have been exceeded.
Applications for embodiments of the invention include, for example, implant fluid processing (e.g. filtration), mobile equipment and remote installations. If desired, if there is an indication that a “defect” exists, for example, a monitored parameter or condition is outside a desired range, value and or set point of performance or, for example, the wrong filter element has been installed, the Filter set can be automatically deactivated until the “defect” has been addressed.
Preferably, the information may be sent wirelessly to the Internet, allowing an end user to securely access the information and / or the information may be sent wirelessly to a local smart phone or tablet device. , any option allowing, for example, a site technician or engineer to review the information and take action if appropriate. Providing information to an end user can produce an early warning that more elaborate laboratory analysis is timely or required. A demand satisfaction capability can be provided to automatically order replacement filter elements.
[038] The RFID tag may be programmed and / or recorded with any information as desired, for example, but not limited to, one or more of any of the following: filter element part number, filter quality, number the manufacturing batch, one or more physical parameters of the filter agents and filter service hours (operating time), differential pressure, water ingress, fluid condition (eg contamination, dilution, oxidation, additive depletion and / or presence of particulate (s), fluid temperature, fluid viscosity, fluid density, fluid dielectric and flow rate), established filter element performance points and / or operating limits .
[039] The RFID tag may be mounted on (including inside), or near (for example, adjacent to) an end cap (for example, directly mounted or mounted via a bracket or embedded within an end cap ). Typically, the RFID tag is arranged near the center of an end cap (for example, the center of the main surface of a closed end cap or the center of the opening of an open end cap).
Using processes known in the art, the RFID tag may be attached by injection molding to a holder or end cap or may be attached to the holder or end cap via an epoxy sealer, ultrasonic solder, adhesives , etc..
[041] The RFID signal generator / controller may include functionality allowing it to record information (e.g. data) on the RFID tag. The RFID signal generator / controller can interface with various sensors, such as, but not limited to, a fluid property sensor and / or a differential pressure sensor and is capable of electromagnetic wireless connection to a data receiver. , such as one or more of any of the following: the Internet, a smart phone, and a tablet device. The RFID signal generator / controller can use Bluetooth® or WiFi as a wireless interface. Data may be streamed to the network (eg network application programming interface (API)) or the cloud where the end user may securely configure access to authorized site personnel via any network enabled device or a cloud. If desired, the RFID signal generator / controller may be programmed (e.g., with access to prophetic algorithms) and may report, for example, historical data trends as reported by the various sensors.
In some embodiments, the filter assembly includes a signal device, for example a variable visual signal indicator, such as a localized illuminable light associated with the filter housing, for example disposed between one end. of the housing and the housing body. The indicator alerts the user or operator to an emission with the filter device, such as loss of communication or Internet connectivity. In some embodiments, a single 2 or 3 color LED signal is provided. A steady green LED signal light indicates that there are no problems with the filter, for example a healthy uninterrupted connection to the network; a flashing yellow and / or red light indicates that there are problems present, for example connectivity problems, etc. An indicator such as an LED signal light may have a generally annular shape (eg with an outer surface formed generally match the outside diameter of the housing) to produce a 360 degree visibility.
Each of the components of the invention will now be described in more detail below, wherein equal components have equal reference numbers.
Figure 1A is an external perspective view and Figure 1B is a cross-sectional view of a filter assembly 1000 according to one embodiment of the present invention showing a housing 500 for receiving a filter, the housing having a first end of housing 510 comprising a removable cover 510A, a housing first end body 51OB, a housing body 575 and a second housing end 550, an RFID signal generator / controller 910, preferably secured to the housing body (the RFID signal generator / controller having a cover 911) and a sensor 1100. The housing may have various forms for receiving a filter and various configurations for producing at least one input and at least one output (wherein a flow path Fluid flow is defined between at least one inlet and at least one outlet and when a filter is arranged in the housing, the filter is arranged through the flow path d In the fluid, an "outward" fluid flow path is illustrated with the arrows in Figure 1B), and preferably includes one or more sensor holes allowing the attachment of one or more sensors. In the embodiment shown, the second end of housing 550 includes an inlet 551 and an outlet 552 and a sensor 1100 is secured to the second end of the housing via a sensor bore 555.
The illustrated filter assembly also includes a signal device or indicator 700 shown as an annular ring 701 such as an LED signal light disposed between the first housing end cap and the housing body.
Figure 1B is a cross-sectional view of the filter assembly shown in Figure 1A, also showing an RFID signal generator / controller module 915 comprising an electronic circuit assembly, a first antenna 901, a second antenna 902, a third antenna (RFID antenna) 903, a third antenna holder 933, an RFID tag 900, and a filter 8.
Figure 1C is an exploded view of the first end of the housing comprising a removable cover 510A and the first end body of the housing 510B and Figure 1D is a bottom view of the first end body of the housing 510B, also showing the third antenna 903 and the third antenna fastener 933, a bushing 934 (to be located within a hole 930) prior to installing the third antenna, the third antenna fastener and the bushing in the body of the first end of the housing.
[048] Figure 1E is an exploded view showing the second antenna 902, the third antenna 903, the third antenna fastener 933, the bushing 934 and the first cable 950 communicating with the second and third antennas (first cable 950 shown Figure 1E as comprising sub-cables 950A and 950B, connected via spring pole connectors 950A 'and 950B') and Figure 1F is a partial cross-sectional view showing the second antenna, the third antenna, the third antenna holder, the bushing and the first cable communicating with the second and third antennas in the filter assembly.
The filter assembly may include additional elements such as retainer clamps, washers, o-rings, as shown, for example, in Figures 1B and 1F. Figures 1B and 1F also show, at the bottom of each view, connected to the first end of housing 510, a plug that can function as, for example, a drain plug or a vent plug, depending on the orientation of the housing. For example, when the housing is oriented as shown in Figure 1B, the plug covers a drain hole and in reverse orientation, the plug covers a vent hole.
[050] Figure 2 is a diagrammatic cross-sectional view showing an arrangement of the first, second and third antennas (901, 902, 903), RFID tag 900 and RFID signal generator / controller 910 according to with one embodiment of the present invention. In this illustrated view, the RFID tag is arranged near a closed filter end cap 40 of a filter 8 having a porous filter element 10. In this illustrative arrangement, the second antenna is disposed on the removable cover 510A; the first antenna is arranged in the housing body 575, wherein the first antenna 901 and the second antenna 902 are generally coaxially arranged and separated by a gap 925 (typically in the range of approximately 0.5 mm to approximately 10 mm), such that the first antenna and the second antenna are inductively coupled, allowing a wireless signal to pass through; the third antenna 903 is disposed in the housing of the first end of the housing, wherein the third antenna (RFID antenna) 903 is spaced (935) from (typically a range in the range of approximately 5 mm to approximately 15 mm), and near a, the RFID tag, and the third antenna is arranged to wirelessly send a signal to and wirelessly receive a RFID tag signal.
Thus, using Figures 1B and 2 for reference, filter assembly 1000 includes an RFID signal generator / controller 910, wherein the filter assembly is arranged to allow a signal to pass from the RFID generator / controller. RFID 910 signal to the RFID tag 900 via the first antenna 901, the second antenna 902, and the third antenna 903, and to allow a signal to pass from the RFID tag to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
[052] A variety of RFID signal generators / controllers are suitable for use in accordance with embodiments of the invention.
[053] A variety of RFID tags (including microelectromechanical system (MEMS) tags) are suitable for use in accordance with embodiments of the invention. The RFID tag, which is preferably passive (no power source (such as a battery)), but can be either semi-passive (with power source, but withdraw power from reader) or active (with transmitter and power source) can be arranged in a variety of locations. The RFID tag may be chipless (for example, using time domain reflectivity or frequency signature techniques) or the RFID tag may include a microchip, which may comprise a "read and write microchip", a " read microchip ”or a“ single read, multiple read microchip ”. The RFID tag may be mounted on, on or within an end cap (for example, directly mounted or mounted via a bracket, or embedded during or after the end cap molding process within an end cap). ). Typically, the RFID tag is arranged near the center of an end cap (for example, the center of the main surface of a closed end cap or the center of the opening of an open end cap).
Figures 3A and 3B show perspective views illustrating filters 8 including a porous filter element 10 and first end cap 40 (wherein the first end cap is a closed end cap) and a second end cap 41 (wherein the second end cap is an open end cap) for use in accordance with an embodiment of the invention. The filters shown comprise a bent porous filter element with a spiral wrap member surrounding the outer surface of the folds.
[055] Figure 3D shows an inward end view of the filter 10 shown in figure 3A showing the RFID tag 900 attached directly within the first (closed) end cap 40. Figures 3C, 3D and 3E show direct attachments Fig. 3C shows a "cavity" on the surface of the end cap for receiving the RFID tag and Figure 3D shows the RFID tag attached in place. Figure 3E shows the first (closed) and second (open) end caps, including the first end cap as shown in figure 3D.
If desired, the RFID tag may be mounted on a holder for use in accordance with an embodiment of the invention and the holder may be associated with an open or closed end cap.
Figures 4C and 4F show an RFID tag 900 mounted on a holder 975 for use in accordance with an embodiment of the invention (Figure 4B shows an exploded view of the holder and tag). The illustrated support 975 includes an outer surface, a top, a bottom, a mounting surface 976 and one or more legs 977, and the illustrated support has a generally annular shape. The top of the bracket includes mounting surface 976, wherein the RFID tag 900 is located on the mounting surface. One or more legs may extend from the bottom of the support (as shown) or from the outer surface. The legs may extend outwards in a generally axial direction. The legs may also include one or more feet or protrusions for engaging a filter surface and / or the end cap.
Figures 5A and 5B show an RFID tag and holder inserted in the filter through the open end cap to a position near the second end cap, where the RFID tag faces (in some embodiments, it touches ) surface of the second (closed) end cap facing the interior of the filter.
[059] A variety of antennas are suitable for use in accordance with embodiments of the invention. Typically, each of the first and second antennas have an annular (ring-shaped) or generally annular shape, wherein the inside diameters of the ring-shaped antennas are individually at least slightly larger than the outside diameter of the filter.
[060] In some embodiments, the filter assembly includes one or more cables. For example, Figure 2 shows a first cable 950, having a first end of first cable 951 and a second end of first cable 952, wherein the first end of first cable is coupled to second antenna 902, and the second end of first cable. The cable is coupled to the third antenna 903 (in the embodiment shown in Figure 1E, the first cable 950 comprises subcords 950A and 950B, connected via spring-loaded column connectors 950A 'and 950B'). Figure 2 also shows a second cable 960 having a first end of second cable 961 and a second end of second cable 962, wherein the first end of second cable is coupled to RFID signal generator / controller 910 and the second end of the second cable is coupled to the first antenna 901.
Preferably, the filter assembly includes at least one sensor, such as a fluid condition sensor, which communicates with the RFID signal generator / controller, such as a differential pressure sensor (e.g. arranged between inlet and outlet) and / or a fluid property sensor, and a variety of sensors are suitable for use. For example, using Figures 1A and 2 by reference, the illustrated filter assembly includes a sensor 1100, such as a differential pressure transducer. Alternatively, or additionally, illustratively, in one embodiment, the filter assembly may include a fluid density sensor and / or a volumetric flow rate sensor (e.g. arranged in a orifice and / or a fluid passageway). within the housing) and in such embodiments including both a fluid density sensor and a volumetric flow rate sensor, the use of both signals enables the determination of mass flow.
The information may be transmitted to and from the filter assembly and a plurality of sets may be operated in one system. For example, Figures 6A and 6C are diagrammatic views showing signal transmission through illustrative systems 2000 according to exemplary embodiments of the invention, including first and second filter assemblies 1000, 1000 '(Figures 6A and 6B; Figure 6C shows filter set 1000 '), the transmission of the signals from the respective RFID signal generators / controllers 910, 910' via a local router 3000 gateway with Internet access such that the signal is broadcast to, for example, a cloud-based application or network application programming interface (API), where an end user can configure access through a secure system to authorized site personnel via any cloud or enabled device on the 3100 network.
If desired, the system may further comprise at least one sensor node, which may be disposed external to the filter assembly or assemblies, wherein the sensor node comprises one or more sensors, such as, for example, a sensor. fluid condition and / or a water sensor (e.g., to monitor dissolved water), preferably wherein the one or more sensor nodes communicate via the gateway gateway.
The first end of the housing comprising a removable cover and a body of the first end of the housing may have a variety of configurations. In the embodiment illustrated in FIGS. 1B, 1D and 1F, the first end of housing 510 comprising a removable housing 510A and a first end body of removable housing 510B comprising an outer cylindrical surface (preferably including threads and one or more slots for receiving the o-rings, wherein the rings help you to seal against pressurized flow (ring ο 505A) and keep dirt out of the threads on the inner cylindrical surface of housing body 575 (ring ο 505B)). Although Figure 1C shows the detachable cover 510A of body 510B, they may be combinable and thus removable from housing 575 (and, if desired, insertable into housing 575) as a combined unit or a unitary (e.g. integral) component.
The illustrated cover includes an annular channel for receiving the second antenna 902 and, using figures 1D and 1F for reference, the housing of the first end of housing 510B comprising a hole 930 for receiving a bushing 934 therein, the bushing comprising a central hole for receiving a cable 960 communicating with the second antenna 902 and the third antenna 903, a recess for receiving a fastener 933 holding the third antenna, such that the third antenna faces into the housing body 575, and a lower end body housing first end 525 with a lower end surface 525A facing the interior housing body space.
The housing body illustrated 575 comprises a mounting surface 579A (shown on an edge 579) for receiving the first antenna, an internal cylindrical surface comprising threads that may engage with the removable body threads 51OB and an inner wall 585 surrounding it. the filter assembly and producing an interior space for the filter assembly.
The second end of the illustrated housing 550 comprises an inlet 551 and an outlet 552 defining a fluid flow path where, when the filter 8 is disposed in the housing, the filter is disposed through the fluid flow path. Preferably, the second end of the housing further comprises one or more sensor holes 555 for receiving one or more sensors 1100, such as fluid condition sensors.
The housing 500 may be made of any suitable rigid impermeable material, including any impermeable thermoplastic material, which is compatible with the fluid being processed. For example, the housing may be made of a polymer such as an acrylic, polypropylene, polystyrene or a polycarbonate resin.
[069] A variety of fluids may be filtered according to embodiments of the invention. Preferably, the fluid is a liquid of any suitable viscosity. In some embodiments, the fluid is, for example, a hydraulic fluid or a diesel fuel.
According to embodiments of the invention, the filter and / or the porous filter element may have a variety of configurations, including planar, folded and hollow cylindrical. A variety of filters and porous filter elements are suitable for use in embodiments of the invention. Fluid flow through the filter can be from the outside in or from the inside out.
The porous filter element, which in the illustrated embodiments has a hollow, generally cylindrical or tubular shape, may have any suitable pore structure, for example, a pore size (e.g. as evidenced by the bubble dot, or by K1 as described, for example, in US Patent 4,340,479, or evidenced by capillary condensation flow porometry), an evaluation of the pore, a pore diameter (e.g., when characterized using the modified OSU F2 test as described by U.S. Patent 4,925,572) or removal evaluation which reduces or permits passage through it of one or more materials of interest when fluid is passed through the element. The structure of the pore used depends on the composition of the fluid to be treated and the desired effluent level of the treated fluid.
In the illustrated embodiments, the porous filter element comprises a folded filter element including a plurality of longitudinally extending folds. The folds may be in a curved or generally covered shape or may extend radially outward (such as, for example, in fan folds). The filter element may also include a wrapping member (e.g. as described above) that extends around the exterior of the filter element. A variety of porous filter elements are suitable for use in embodiments of the invention, for example as disclosed in U.S. Patent Application Publication 2015/0375143 A1.
The filter and / or porous filter element may include additional elements, layers or components that may have different structures and / or functions, for example at least one of any of the following: prefilter, support , flow, spacing and damping. Illustratively, the filter may also include at least one additional element such as a mesh and / or screen.
According to embodiments of the invention, the porous member comprises at least one porous filtering agent, such as a paper filtering agent, a fibrous filtering agent and / or a membrane, for example a nano-porous membrane. for example, a membrane having pores in diameter between 1 nm and 100 nm or a microporous membrane or microporous fibrous agent having pores in diameter between 1 μπ and 10 μπι. The porous element may comprise a reverse osmosis or ultrafiltration membrane.
The porous filter element may have any desired critical wetting surface tension (CWST, as defined, for example, in U.S. Patent 4,925,572). CWST may be selected as known in the art, for example as further disclosed, for example, in U.S. Patent Nos. 5,152,905, 5,443,743, 5,472,621 and 6,074,869. Typically, the filter element has a CWST greater than approximately 58 dynes / cm (approximately 58 x 10-5 N / cm) or approximately 66 dynes / cm (approximately 66 x 10-5 N / cm) or more or approximately 75 dynes / cm (approximately 75 x 10-5 N / cm) or more.
[076] The surface characteristics of the porous filter element may be modified (eg to affect CWST, to include a surface charge, for example a positive or negative charge and / or to change the polarity or hydrophilic capacity of the surface) by wet or dry oxidation, coating or depositing a polymer on the surface or a graft reaction. Modifications include, for example, irradiation, a polar or charged monomer, coating and / or curing the surface with a charged polymer and performing chemical modification to trap functional groups on the surface.
Figures 3A and 3B illustrate two exemplary embodiments of filters 8 useful in accordance with the present invention. The filter 8 has a generally cylindrical shape and two end caps 40, 41 which seal the ends of a filter element 10. A portion of the upper end cap 40 and filter element 10 is partially cut out to show the interior of the filter 8. A helical wrap member 50 may be disposed along the outer periphery of the filter element 10. In a preferred embodiment, the filter element 10 may comprise a plurality of longitudinally curved folds 12 or radial folds (not shown). Those skilled in the art will also appreciate that the wrapping member 50 could also be used for unfolded filter elements, such as a hollow cylindrical mass of fibers.
As shown in Figure 3A, a cylindrical core 20 may be coaxially disposed along the inner periphery of the filter element 10. A core 20 is typically used when the filter is subjected to radially inward fluid flow (from outside in). Alternatively, when the filter element 10 is subjected to radially outward (inwardly outward) fluid flow, a cylindrical core may not be required as shown in Figure 3B.
As shown in figures 3A and 3B, each fold 12 has two legs 12a which are joined, (1) on the crown or crest 12b of the outer periphery of the filter element 10, and (2) on one leg 12a of a fold. adjacent 12 at the root 12c of the inner periphery of the filter element 10. Each leg 12a has an inner surface 12d that opposes the inner surface 12d of the other leg 12a at the same fold 12. Each leg 12a also has an opposing outer surface 12e to the outer surface 12e of a leg 12a of an adjacent fold 12. When the filter element 10 is being used such that fluid flows radially inwardly through the element 10, the inner surfaces 12d of the legs 12a form the downstream surface of the filter element 10, while outer surfaces 12e form the upstream surface of filter element 10. Alternatively, when filter element 10 is subjected to radially outward fluid flow, inner surfaces 12d and outer surfaces 12e form the upstream and downstream surfaces respectively of the filter element 10.
Those skilled in the art will appreciate that the filter element 10 may comprise curved or covered folds which are illustrated in conventional radial figures or folds (not shown). In one embodiment, the bend legs 12a may have equal leg lengths. In another embodiment, the bend legs 12a may have legs of slightly different lengths or unequal length. For many filter elements 10, especially those formed of a multilayer composite, it is easier and more reliable to form the folded filter element 10 if the adjacent legs 12a of each curved fold have slightly different lengths. Such folds 12 will be called as uneven leg folds.
As shown in figures 3A and 3B, the opposing inner surfaces 12d of the legs 12a of each fold 12 touch substantially the entire height of the legs 12a and fold 12 and over a continuous region extending over a significant portion of the In addition, the opposing outer surfaces 12e of the adjacent folds legs 12a touch substantially the entire height of the adjacent folds 12 and legs 12a and a continuous region extending over a significant portion of the axial length of the filter element. The height of the folds 12 and the legs 12a is measured in one direction along the surfaces of the legs 12a and extends from the inner periphery to the outer periphery of the filter element 10.
The filter element 10 includes a filter agent 14 and flow agent arranged on at least one side, preferably the upstream side and more preferably on both upstream and downstream sides of the filter agent 14. When radial folds are used in the filter element 10, there is typically sufficient space between the upstream and downstream sides of the bend legs so that fluid can flow equally to or substantially all portions of the filter agent surface 14 In a preferred embodiment of the present invention, opposite surfaces of curved folds 12 are pressed into contact with each other. Consequently, the flow mesh filaments of each leg 12a of the folds 12 are pressed against the flow mesh filaments of an adjacent leg 12a of the folds 12. The flow device prevents opposite surfaces of the filter agent 14 from contacting each other. each other and enables fluid to flow equally to or substantially all portions of the surface of filter agent 14 when curved folds 12 are used in the filter element. Thus, virtually the entire surface area of filter agent 14 can be effectively used for filtration.
In the illustrated embodiments, the filter element 10 comprises a three layer composite of a filter agent 14, upstream flow in the form of an upstream flow layer 16 disposed on the upstream surface of filter agent 14 and downstream flow in the form of a downstream flow layer 18 disposed on the downstream surface of the filter agent 14. Here, the upstream and downstream surfaces refer to a filter that is subjected to fluid flow radially inwardly. When the filter is radially outflowed, the upstream and downstream surfaces are reversed. The layers forming the filter element 10 may be formed into a composite by conventional filter making techniques prior to or simultaneously with corrugation.
It is possible for filter agent 14 to include two or more layers having different filtering characteristics, for example with one layer acting as a prefilter for the second layer.
In another embodiment, the filter element 10 may comprise several integral regions, including a single unitary porous sheet having a thin pore center region serving as a filter agent, and upstream and / or downstream regions. thick pores that serve as the flow layers. However, the flow layers are preferably separate separate layers of the filtering agent. Upstream and downstream flow layers 16 and 18 may be of the same or different construction. Upstream and downstream flow layers 16 and 18 may be made of any materials having laterally suitable flow characteristics, i.e., adequate resistance to flow of fluid through the layer in a direction parallel to its surface. The flow resistance laterally of the flow layer is preferably low enough that the pressure drop in the flow layer is less than the pressure drop through the filtering agent, thereby producing a uniform distribution of fluid across the surface. of the filter agent. The flow layers may be in the form of a mesh or screen or a porous woven or nonwoven sheet.
Meshes are particularly suitable as flow layers when the filtering agent is a fibrous deposited agent. On the other hand, when the filtering agent is a membrane, a woven or non-woven cloth may be more suitable for use as the flow layer because a cloth is generally softer than a mesh and produces less abrasion of adjacent composite layers. filter
The filter composite forming the filter element 10 may include layers other than filter agent 14 and flow layers 16 and 18. For example, to prevent abrasion of the filter agent due to contact with Friction with the Flow Layers When the folds expand and contract during pressure fluctuations of the fluid system in which the filter is installed, a damping layer may be arranged between the filter agent and one or both of the flow layers. The damping layer is preferably made of a softer material than the flow layers and having a higher abrasion resistance than filter agent 14. For example, when the flow layers are made of an extruded nylon mesh. An example of a suitable cushioning layer is a non-woven polyester cloth.
The filter element 10 illustrated in figures 3A and 3B may be manufactured by a variety of techniques. In one technique, the filter composite is first corrugated to form a corrugated sheet, cut to a suitable length or number of folds and then transformed into a cylindrical shape. The longitudinal edges of the corrugated sheet are then sealed together in conventional manner to form a cylindrical filter element 10. When the filter is subjected to radially inward fluid flow, the folds of the filter element 10 are then covered when the filter element filter 10 is inserted into a cage 30. After filter element 10 has been mounted within cage 30, a core 20 is inserted into the hollow center of filter element 10 and then end caps 40 are secured to the ends of the element. 10 to form a complete filter.
Preferably, a filter according to the present invention will be equipped with end caps 40, 41 at one or both ends of the filter element 10. End caps 40, 41 may be blind or open end caps. and may be made of a material that is suitable for filter conditions and the other materials of the filter components to which the end caps are to be joined. Preferably, end caps 40, 41 are secured to filter element 10, but they may also be attached to core 20 or cage 30. Conventional techniques may be used to secure end caps to filter element 10, such as as by the use of an epoxy, polyamping or rotational welding.
When the filter element 10 is subjected to radially inward flow of fluid, the presence of a core 20 is generally desirable because the core 20 supports the inner periphery of the filter element 10 against forces in the radial direction and also helps. give the filter axial strength and stiffness against bending. Core 20 may be of conventional design and may be made of any material having sufficient strength and that is compatible with the fluid being filtered. The openings 21 are formed through the core wall 20 to allow fluid to pass between the exterior and the center of the core 20.
However, depending on the forces acting on the filter element 10 during filtering, it may be possible to omit the core 20. For example, when the flow of fluid through the filter element 10 is primarily from the inside out, Radially inward forces on the filter element 10 may not exist or be so low that a core 20 becomes unnecessary, reducing the weight and cost of the filter. The curved bend configuration shown in Figures 3A and 3B allows uniform bend support and acts to distribute concentrated loads evenly across the filter element. This minimizes bend movement and increases the ability of bends to retain particles in pulsating flow systems.
A filter according to the present invention preferably includes a component for retaining the filter element 10 in a cylindrical configuration. A suitable component for retaining the folds is a sheet of material wrapped around the filter element with sufficient tension to prevent the folds from unfolding from its folded state. In Figures 3A and 3B, a helical wrapping member 50 comprising a parallel side strip of a flexible material that is helically wound around the filter element 10 in a plurality of turns is provided. The wrapping member 50 may be made of any material that is compatible with the fluid being filtered. If the wrapping member 50 completely surrounds the outer periphery of the filter element 10, the wrapping member 50 is preferably porous. Although the filter element preferably comprises folds, the wrapper could also be useful for unfolded filter packages, such as a hollow cylindrical mass of fibers.
The wrapping member 50 is made of a material strong enough to produce sufficient support against radially outward forces and to withstand the stresses of inward outward flow. The wrap member tension 50 can be selected according to the expected filtering conditions.
Wrap member 50 may be wrapped around filter element 10 with or without overlap between adjacent turns of wrap member 50. For example, adjacent turns of wrap member 50 may touch without substantially overlapping, or using In an overlap, it is possible to wrap multiple layers of the wrap member 50 around the filter element 10. However, it has been found that if the wrap member 50 includes an unobstructed opening, the dirt capacity of the filter element 10 can be greatly increased compared to This is an uncoiled folded filter element or compared to a folded filter element completely covered in a wrap member. The apertures may be holes formed in the material of the wrap member 50 itself or they may be spun 52 left between adjacent turns of the wrap member 50.
In the embodiment of figures 3A and 3B, the wrap member 50 is wrapped around the filter element 10 so as to leave openings in the form of a helical gap 52 between adjacent turns. The wrap member 50 comprises a composite strip of two or more layers including at least one outer layer 54 and an inner layer 56. The outer layer 54 serves as a "carrier" enabling the wrap member 50 to be securely secured to the outside of the housing. filter element 10 including, for example, the crowns 12b of folds 12. Outer layer 54 may be formed from a variety of materials including, for example, rotationally joined thermoplastic materials that are compatible with the fluid being filtered and readily readily formed. will attach to an adhesive such as a hot melt adhesive. The outer layer 54 is preferably porous, allowing the hot melt adhesive to penetrate into the layer 54 to form a stronger bond. The outer layer could also be perforated. For many applications, a porous, non-woven, polymeric material available from Reemay Corporation under the tradename Reemay is suitable. Reemay material laminates may also be used. Examples of other suitable materials are oil carton and Mylar film.
[096] The inner layer 56, which provides resistance to the wrap composite, supports radially outward forces and resists stresses from inward flow and pressure drops across the filter element. The inner layer 56 is preferably a carbon fiber or glass reinforced thermoplastic strip including, for example, a carbon fiber or glass reinforced polyphenylene sulfide (PPS) strip. The fiberglass content may preferably be up to approximately 70% by weight and the carbon fiber content may preferably be up to approximately 60% by weight. Polybutylene terephthalate (PUT) reinforced with glass or carbon fibers or uniaxial fabrics or steel strips may also be useful for some fluids. Similarly, glass or carbon fiber reinforced nylon or polypropylene would be useful for mild non-aggressive fluids such as water.
[097] For filter elements 10 having an outer diameter of approximately 10.16 cm (four inches) or less, the inner layer 56 preferably should have an elastic modulus of at least about 20684 MPa (3 million psi (3 MPSI)). ) to withstand a pressure drop of 1.03 MPa (150 psid) (inside out). In a larger filter element 10 including, for example, elements having an outside diameter between 10.16 cm and 15.24 cm (four inches and six inches), an inner layer 56 preferably should be able to withstand a pressure drop of 0.69 MPa (100 psid). To withstand up to 1.03 MPa (150 psid) pressure drop, the inner layer 56 should preferably have an elastic modulus of at least approximately 82737 MPa (12 MPSI). To achieve the desired strength characteristics, the inner layer 56 may be formed by stacking multiple layers of the reinforced strips on top of one another.
[098] The outer and inner layers 54, 56 are preferably joined together for ease of fabrication, although with careful fabrication they need not be joined together. The outer and inner layers 54, 56 may be joined together by (1) a double-sided adhesive tape applied between the two layers, (2) a hot melt adhesive (polyamide hot melt or melt). EVA) applied between the two layers or (3) ultrasonic spot welding of the two layers.
If desired, the wrap member 50 may be secured to the outside of the filter element 10 by applying a drop of hot melt adhesive to both edges of the inner layer. At each edge, the hot melt adhesive can flow to the porous outer layer and the inner layer edge, preventing any fiber migration from the inner layer.
The wrapping member 50 is preferably secured in a manner that prevents it from being unwound from the filter element 10. In a preferred embodiment, the wrapping member 50 is wrapped around the filter element 10 without directly clamping them together. only the two ends of the wrap member 50 on end caps 40, 41. Before the wrap member 50 is secured to end caps 40 and / or 41, the ends of wrap member 50 may be angled so that substantially The entire end length can be joined to the end cap.
After the filter composite (i.e. the filter agent and flow layers) is folded into a cylindrical shape, the longitudinal edges of the folded filter composite are sealed together to form a filter packet. bent cylindrical. Before the drops of hot melt adhesive 58 solidify and before the end closure, the wrap member 50 may be helically wound around the length of the filter packs. The tension applied to the wrap member 50 should be sufficient to prevent movement of the bends 12 or ripples on the wrap member 50 between the bends 12 without crushing or closing the bends 12 of the filter pack. The filter pack may be fabricated to suitable lengths, for example, 42 to 44 inch (106.7 to 111.8 cm) lengths, and wrap member 50 is applied to the entire length of 106.7 to 111.8 cm. (42 to 44 inches). Thereafter, the filter pack may be cut to desired lengths of, for example, 40 inches (40.6 cm), 20 inches (50.8 cm), 13 inches (33.0 cm), 8 inches) or 10.2 cm (4 inches).
It will be found that the outer layer 54 is preferably wider than the inner layer 56. Thus, when the end of the wrap member 50 is joined to the end caps 40, 41, the outer layer 54 will help to prevent the outer layer. inner 56, which is relatively harder than outer layer 54, separate from the end cap 40 and filter pack. Outer layer materials 54 may also come together better in the adhesives and sealing materials used in the fabrication of the filter elements than the materials used in making the inner layer 56. The wider outer layer 54, which is relatively more flexible and typically It has better handling characteristics than the materials used in the inner layer 56, provides better handling and performance during the manufacturing process and minimizes the separation between the inner layer 56 and the end caps 40, 41 and the filter pack while maintaining the relative strength characteristics of the inner layer 56.
The wider outer layer 54 also maintains the spreading of the adhesive within the envelope periphery and minimizes the undesirable mess that may occur if the adhesive spreads out of the envelope periphery. It is preferable for a gap 52 to be formed between adjacent turns of the helical wrap member 50, so that a gap 52 is no larger than the width of the inner layer 56. For some applications, the width X of the gap 52 between the helical wrap member Adjacent 50 is the same distance as the inner envelope width X 56. In one embodiment, it has been found that an inner layer width of approximately 1.02 cm (0.4 inches) is sufficient for many applications. In a preferred embodiment, the outer layer 54 is approximately twice (2x) the width of the inner layer 54, so the total distance from the edge of one inner layer 56 to the edge of the next adjacent inner layer is approximately 2x.
After the combined filter pack and wrap member 50 are cut to the desired length, each filter pack is closed at the end to form filter element 10. End caps 40, 41 may be applied using a sealing compound including, for example, an epoxy or polyurethane, or a hot melt adhesive. End caps 40, 41 may be polymeric. Alternatively, a polymer end cap may be applied to the end of the filter pack / wrap end 60 by melting a portion of the polymer end cap and inserting the end of the filter pack / wrap end 60 into the melted portion of the end caps 40. 41. In either case, the end of the filter pack / wrap end 60 should preferably be inserted at least 0.127 cm (50 milliseconds of an inch) and more preferably 0.254 cm (100 milliseconds of an inch). sealing compound or molten plastic to ensure that the wrap member 50 is properly bonded to the filter pack at end caps 40, 41.
Another method of securing the wrap member 50 is to secure it to the filter element 10 by a bonding agent, such as a hot melt adhesive, which is applied to the wrap member 50 when it is wrapped around the filter member. filter 10. The bonding agent may be applied to the wrap member 50 in the form of a continuous or intermittent droplet spiraling around the filter element 10 parallel to the edges of the wrap member 50. Alternatively, if the wrap member 50 is made of material polymeric, it may be fused together on the filter element 10 by a hot wheel running down the length of the filter element 10 when the filter element 10 is rotated. The wrapping member 50 may be attached directly to the filter element 10 or, if there is overlap between adjacent turns of the wrapping member 50, the adjacent turns may be attached directly to each other.
[0106] The following examples further illustrate the invention, but should not, of course, be construed as limiting its scope in any way. EXAMPLE 1 This example describes a filter assembly according to one embodiment of the invention.
Using figures 1F and 2 for general reference, where the RFID tag 900 is attached to the inner surface of the end cap 40 via a thermally fastening process, the first, second and third antennas (901, 902 903) are tuned to operate at or near 13.56 MHz (wavelength ~ 22.1 m) and are realized as copper traces on circuit boards. Corresponding components on each of the antenna circuit boards allow fine tuning of the impedance (approximately 50 ohms) and resonant frequency. The RFID reader integrated circuit is connected to the first 901 antenna with a coaxial cable. Each of the first and second antenna acts as half of an electromagnetically coupled coil which transfers the RFID reader signal to the lid assembly through a 3.8 mm nominal span (925). The first antenna 901 resides in the housing body 575 and is stationary relative to the housing body. The second antenna 902 is part of the removable cover 510A which is attached to the first end body of the removable housing 510B.
[0109] The RFID signal is routed to the third antenna 903 through a pressure bushing assembly 934 to allow crossover to the high pressure side of the filter housing. The third antenna 903 is located in the fluid chamber and is electromagnetically coupled to the RFID tag 900 located on the filter end cap 40. The distance 935 between the third antenna 903 and the RFID tag 900 is 9.26 mm. . EXAMPLE 2 [0110] This example describes the operation of an illustrative filter system according to an embodiment of the invention, including first and second filter assemblies, wherein the first filter assembly is disposed in a high pressure line (flow pressure). approximately 40 MPa (400 Bar) or less) and the second filter assembly (used for filtration of recycled fluid) is arranged in a low pressure (return) line (working pressure typically approximately 2 MPa (20 Bar) or any less). In some embodiments, use of a second filter assembly disposed at the lower pressure portion of the hydraulic circuit may be desirable to ensure that clean fluid is returned to the reservoir.
Typically, an end user will define an end user process (or “consumer process”) for use in the system, including various target parameters and the parameters may differ depending on the fluid to be filtered, for example hydraulic fluid, lubrication, etc. For example, the process may define hours of filter service life (operating time), differential pressure, water ingress, fluid condition (eg contamination, dilution, oxidation, additive depletion and / or particulate matter ( s), fluid temperature, fluid viscosity, fluid density, fluid dielectric and flow rate). In some embodiments, the established filter element performance points and / or operating limits are stored and monitoring includes determining whether one or more stored performance points and / or operating limits have been exceeded.
[0112] Typically, the consumer's process includes converting the hydraulic energy created by the feed pump to another form of work (force / pressure, rotary or linear motion, etc.) via actuators and performers such as hydraulic cylinders, motors. or in the case of a lubrication system, by circulating the lubricant through rotating machinery such as gearboxes or the consumer process as refrigerant. If desired, the consumer process can be duplicated multiple times - each with its own valves, actuators, machinery, etc.
Using Fig. 6A for general reference, system 2000 includes first and second filter sets as described above, wherein a set 1000 is arranged as a return line filter node (lowest pressure filter assembly / return line) and the other assembly 1000 'is arranged as a high pressure filter node. In this example, the first and second filter sets are configured as described in example 1, wherein the components marked in the second set include "'' as part of their markings (e.g., 1100 '').
The illustrated system further includes a 2500 sensor node, including an electronics box that can automatically collect data and report data wirelessly (eg fluid integrity) to a WiFi 3000 gateway ( which acts as a bridge between one network and another, for example, two wireless communication frequencies) and interfaces with a water sensor 2551 and a fluid property sensor (eg fluid density sensor) 2552, in that the sensors are preferably attached to a 2550 sensor manifold and the sensor node is located on the low pressure side of the system (upstream of the feed pump) within approximately 3 meters of the 2550 sensor manifold including the sensors 2551,2552.
[0115] In this example, the sensor node is electrically connected to the water sensor via a half duplex RS-485 interface using a 6-conductor cable and electrically connected to the fluid property sensor via a CAN bus interface, using a 4-conductor cable.
[0116] The sensor node is connected to a 24V DC power supply using a 2-conductor cable.
Filter sets 1000, 1000 'individually include an RFID 910, 910' signal generator / controller including an electronics box that wirelessly reports differential pressure measurements for WiFi. RFID signal generator / controller 910, 910 'is mounted on the side of the filter housing above differential pressure sensor 1100, 1100' and RFID signal generator / controller 910, 910 'is electrically connected to the sensor. respective differential pressure 1100, 1100 'via a half duplex RS-485 interface using a 6-conductor cable.
[0118] An overview of the operation of a system according to one embodiment of the invention is as follows: [0119] Fluid is pumped out of a reservoir 2100 on the high pressure side and through a sensor node 2550 by a pump 2200 and fluid passes through a first filter assembly 1000 'where the fluid is filtered. The RFID 910 'signal generator / controller wirelessly reports fluid and filter conditions via the cloud gateway 3000, as well as indicates in its electronic indication system (LEDs) its current state (where a red LED indicates that a filter change is required now, a yellow LED indicates that the filter is nearing its end and should be replaced soon, and a green LED indicates that the filter is good) with fluid filtration via the removable filter installed, and the sensor node reports detailed fluid conditions via the cloud gateway 3000.
Data received by the filter and nodes is transmitted to the cloud-based software application via the gateway and algorithms in the application process and determines if anomalous conditions of filter and / or fluid integrity exist. If the monitored health conditions of the filter and fluid are approaching or at an unacceptable level (eg out of specification), an alarm is generated and a notification is sent, which may include a change in the color of the green LED. to yellow or red.
In order to recycle the fluid, the fluid passes through the second fluid assembly 1000, and the RFID signal generator / controller 910 wirelessly reports fluid and filter conditions via the cloud gateway , as well as indicate in your electronic indication system (LEDs) their current state along with fluid filtration via the removable filter installed.
[0122] Fluid passes from the second filter assembly 1000 back to reservoir 2100 to repeat the cycle.
Externally, an operator, technician, and / or consumer (for example) can use their 31000 Internet-capable device (computer, tablet, smart phone, etc.) to connect to the cloud and view reports generated by the suite. filter and sensor nodes. The operator, technician and / or consumer may also visually inspect the indicators on the filter sets for current performance. EXAMPLE 3 This example describes the operation of an illustrative filter system according to one embodiment of the invention, including a filter assembly. The system also includes a reservoir, a pump, a sensor node, a flow meter, pressure gauges and a WiFi connection port.
[0125] In this example, the filter assembly is configured as described in example 1. The RFID tag is programmed with the filter element part number.
[0126] The system further includes a sensor node, including an electronics box that can automatically collect data and report data wirelessly (eg fluid integrity) to a WiFi gateway (which functions as a as a bridge between one network and another, for example, two wireless communication frequencies) and interfaces with a fluid-owned sensor, where the sensor is attached to a sensor manifold and the sensor node is downstream of the feed pump.
[0127] In this example, the sensor node is electrically connected to the fluid property sensor via a CAN bus interface using a 4-conductor cable. The sensor node is connected to a 24V DC power supply using a 2-conductor cable.
[0128] The filter assembly includes an RFID signal generator / controller including an electronics box that wirelessly reports differential pressure measurements for WiFi. The RFID signal generator / controller is mounted on the housing side filter above the differential pressure sensor and the RFID signal generator / controller is electrically connected to the differential pressure sensor via a half duplex RS-485 interface using a 6-conductor cable.
[0129] Hydraulic oil (Mobil DTE24), stored at or near atmospheric pressure, is pumped out of the reservoir by a pump and fluid passes through the filter assembly and sensor node. The flow rate is controlled by varying the pump speed and the flow rate is read from the flow meter, which is arranged downstream of the filter assembly. Pressure gauges mounted upstream and downstream of the filter assembly provide visual confirmation of differential pressure. The RFID signal generator / controller wirelessly reports fluid and filter conditions via the cloud gateway, and the sensor node reports detailed fluid conditions via the cloud gateway.
[0130] The test runs at flow rates ranging from approximately 2 GPM to approximately 10 GPM and supply pressures from approximately 0.14 MPa (20 PSIG) to approximately 0.69 MPa (100 PSIG).
[0131] The readout data from the RFID tag on the filter element is consistent throughout the test and the fluid property sensor and differential pressure sensor data are reported accurately and are consistent with the expected values for oil. Data is accessible by an end user from a laptop or smart device. EXAMPLE 4 [0132] This example describes the operation of an illustrative filter system according to one embodiment of the invention, including a filter assembly as generally illustrated in Figure 6C.
[0133] In this example, the filter assembly is configured as described in example 1. The RFID tag is programmed with the filter element part number.
Commercially available hydraulic oil stored at or near atmospheric pressure in a darkened room is pumped out of the reservoir by a pump and the pressurized fluid to approximately 20.7 MPa (3000 psig (207 bar)) at a rate flow rate of 20 gpm passes through the filter assembly and sensor node.
[0135] The maximum working system pressure is defined by a pressure regulating device such as a bypass regulator. Installed downstream of the pump and on the high pressure side is a filter housing assembly. The filter housing assembly includes the filter element, filter bypass valve, a filter element differential pressure transducer, filter element RFID reader, associated electronics, wireless communications, and an illuminated visual indicator / signal. visible from 360 degrees.
[0136] Electronics monitors the filter element differential pressure, which increases over time when dirt particles or wear debris are captured and checks that the correct element part number is installed via the RFID tag located on the filter element. The electronics also contain wireless communications that transmit sensor data to the gateway, which in turn transmits sensor data to the cloud.
[0137] A bypass valve is included in a filter housing such that the maximum differential pressure across the filter membrane is limited to prevent damage to the filter and to prohibit flow blockage if the element becomes clogged with contaminants. . The bypass valve is set to open at 0.44 MPa (65 psid (4.5 bar)). In a normal operating state where an adequate filter life remains and the filter element differential pressure is below approximately 80% of the bypass valve setting (0.35 MPa (~ 52 psid)), the indicator / Visual signal is illuminated with green LEDs.
[0138] When the filter charges to such an extent that the practical service life of the filter element is nearing its end and the differential pressure exceeds approximately 80% of the bypass valve setting, the visual indicator / signal is illuminated with yellow LEDs. . The end user (s), typically a maintenance supervisor or technician, will also receive a notification on an Internet capable device. At this point, it should be understood by the end user that the filter element must be replaced with a new one of the same part number in the near future. However, if the filter element is not repaired and the filter differential pressure continues to increase to the point where the bypass valve is close to the opening point, which in this case is 0.44 MPa (65 psid), then the indicator / Visual signal is illuminated with red LEDs and an alarm notification will be sent to end user devices.
Installed downstream of the consumer process on the low pressure return line, which is typically about 0.1 MPa (1 bar), is the sensor manifold and associated electronics and communications module. The sensor node communications module wirelessly transmits data to the gateway and finally to the cloud in the same manner as the filter housing. Flow of hydraulic fluid returned from the consumer process passes through or through the fluid property sensor (and optionally a dissolved water sensor). Sensors continuously monitor critical fluid integrity parameters and will alert the end user if these parameters are approaching or exceeding the limits for hydraulic fluid or if a process disorder such as upstream process water ingress or a heat exchanger leaking heat, for example, occurred. In the case where a fluid condition limit is approaching or exceeded, notification will be sent to end user devices of choice in the same manner as previously described filter condition notifications.
All references, including publications, patent applications and patents, cited herein are hereby incorporated by reference to the same extent as if each reference were individually and specifically indicated to be incorporated by reference and were set forth in their entirety. on here.
The use of the terms "one" and "one" and "o" and "a" and "at least one" and similar referents in the context of describing the invention (especially in the context of the following claims) shall be construed to cover both singular and plural unless otherwise indicated herein or clearly contradicted by context. Use of the term “at least one” followed by a list of one or more items (for example, “at least one of A and B”) shall be interpreted as meaning an item selected from the listed items (A or B) or any combination of two or more of the listed items (A and B), unless otherwise indicated herein or clearly contradicted by context. The terms "comprising", "having", "including" and "containing" shall be construed as unlimited terms (that is, meaning "including but not limited to") unless otherwise stated. The recitation of the value ranges here is merely intended to serve as an individual reference handwriting method for each separate value that falls within the range unless otherwise indicated here and each separate value is incorporated into the descriptive report as follows. he had been individually recited. All methods described herein may be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (for example, "as") presented herein is intended merely to further illuminate the invention and not to impose a limitation on the scope of the invention unless otherwise claimed. No language in the descriptive report should be interpreted as indicating any unclaimed element as essential to the practice of the invention.
Preferred embodiments of this invention are described herein, including the best mode known to the inventors for carrying out the invention. Variations of these preferred embodiments may become apparent to those skilled in the art upon reading the foregoing description. The inventors expect those skilled in the art to use such variations as appropriate and the inventors plan that the invention will be practiced otherwise than as specifically described herein. Accordingly, this invention includes all modifications and equivalents of the subject matter recited in the appended claims as permitted by applicable law. Moreover, any combination of the above described elements in all possible variations thereof is encompassed by the invention unless otherwise indicated herein or otherwise clearly contradicted by context.

权利要求:
Claims (21)
[1]
1. Fluid assembly, characterized in that it comprises (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a generally cylindrical filter comprising a porous filter element, in that at least the first end of the housing comprises a removable cover and a body of the first end of the housing, wherein the housing is arranged to produce a fluid flow path through the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
[2]
Filter assembly according to claim 1, characterized in that it further comprises at least one fluid sensor, arranged to sense a fluid condition, wherein the fluid condition sensor communicates with the generator / controller. RFID signal.
[3]
Filter assembly according to claim 1 or 2, characterized in that the first end cap is a closed end cap.
[4]
Filter assembly according to claim 1 or 2, characterized in that the first end cap is an open end cap.
[5]
Filter assembly according to any one of claims 1 to 4, characterized in that the RFID tag is attached to the first end cap.
[6]
Filter assembly according to any one of claims 1 to 4, characterized in that the porous filter element is bent.
[7]
Filter assembly according to any one of claims 1 to 6, characterized in that it further comprises a signal device comprising a variable visual signal indicator attached to the housing.
[8]
8. A fluid processing monitoring system, characterized in that it comprises: (A) a fluid assembly comprising (a) a housing having a first end of the housing, a housing body and a second end of the housing; housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first end of the housing comprises a removable cover and a housing of the first end of the housing, wherein the housing is arranged to produce a fluid flow path through of the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) an RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) an RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna; (B) a router gateway providing internet access, the router gateway communicating with the RFID signal generator / controller, and (C) at least one network or cloud enabled device capable of accessing the Internet and receive information related to the filter set.
[9]
9. Method for monitoring fluid processing in a fluid assembly including an RFID tag and an RFID signal generator / controller, the method comprising: (A) receiving fluid-related information passing through a fluid assembly comprising (a) a housing having a first housing end, a housing body and a second housing end, the housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first end the housing comprises a removable cover and a housing end first body wherein the housing is arranged to produce a fluid flow path through the filter such that fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) the RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) the RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
[10]
Method according to claim 9, characterized in that the information comprises any one or more of: filter differential pressure, flow rate and part number of the filter element.
[11]
A method according to claim 9 or 10, characterized in that it comprises accessing the Internet using a cloud or network enabled device and receiving the information.
[12]
12. Method for monitoring fluid processing in a fluid assembly including an RFID tag and an RFID signal generator / controller communicating with a router gateway providing internet access, the method FEATURED by the fact that comprises: (A) accessing the internet using a cloud or network enabled device and (B) receiving fluid related information passing through a fluid assembly comprising (a) a housing having a first end of the housing, a body of the housing and a second end of the housing, the housing containing a generally cylindrical filter comprising a porous filter element, wherein at least the first end of the housing comprises a removable cover and a body of the first end of the housing, wherein the housing is arranged. to produce a fluid flow path through the filter such that the fluid is filtered as it passes through the porous filter element; (i) the filter comprising a first end cap and a second end cap, and the porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second end of the filter; (ii) the RFID tag attached to or near the first end cap or second end cap; (iii) a first antenna disposed within or on the housing body; (iv) a second antenna arranged within or on the removable cover, wherein the first antenna and the second antenna are generally coaxially arranged and spaced apart such that the first antenna and the second antenna are inductively coupled. allowing a wireless signal to pass through; (v) a third antenna arranged within or on the housing of the first end of the housing, wherein the third antenna is spaced from the RFID tag, and the third antenna is arranged to wirelessly send a signal to and receive from wirelessly forms a signal from the RFID tag; (vi) the RFID signal generator / controller and (vii) a first cable having a first end of the first cable and a second end of the first cable, wherein the first end of the first cable is coupled to the second antenna and the second one. end of the first cable is coupled to the third antenna; wherein the filter assembly is arranged to allow a signal to pass from the RFID signal generator / controller to the RFID tag via the first antenna, the second antenna, and the third antenna, and to allow a signal to pass from the RFID tag. RFID to the RFID signal generator / controller via the third antenna, the second antenna and the first antenna.
[13]
13. Filter, characterized in that it comprises: a first end cap; a second end cap; a hollow cylindrical porous filter element comprising a first filter end and a second filter end, the first end cap sealed at the first filter end and the second end cap sealed at the second filter end and a fastened RFID tag over or near the first end cap or second end cap.
[14]
System according to claim 8, characterized in that it further comprises a fluid density sensor.
[15]
A system according to claim 8 or 14, characterized in that it further comprises a volumetric flow rate sensor.
[16]
Filter assembly according to claim 1, characterized in that it further comprises at least one fluid condition sensor arranged to sense a condition of the fluid passing through the filter assembly, wherein the condition sensor fluid communicates with the RFID signal generator / controller.
[17]
Filter assembly of any one of claims 1 to 7, characterized in that it further comprises a fluid density sensor and a volumetric flow rate sensor arranged to determine the mass flow at which the sensor of the Fluid density and volumetric flow rate sensor communicate with the RFID signal generator / controller.
[18]
Filter assembly of any one of claims 1 to 7, characterized in that it further comprises a fluid density sensor.
[19]
Filter assembly of any one of claims 1 to 7, characterized in that the RFID tag is mounted on a holder inserted in the filter.
[20]
Filter assembly according to claim 19, characterized in that the RFID tag faces the first end cap, wherein the first end cap comprises a closed end cap.
[21]
The system of any of claims 8, 14 or 15, characterized in that it further comprises at least one sensor node communicating through the router's gateway.

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法律状态:
2018-05-15| B03A| Publication of a patent application or of a certificate of addition of invention [chapter 3.1 patent gazette]|

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2021-04-20| B06W| Patent application suspended after preliminary examination (for patents with searches from other patent authorities) [chapter 6.23 patent gazette]|

优先权:

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申请号 | 申请日 | 专利标题

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US15/337,364|US10286343B2|2016-10-28|2016-10-28|Filter including RFID tag|

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US15/337,364|2016-10-28|

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