WO2009032833A1 - Environmental sensor, particle counting system having an environmental sensor, and methods of operating the same - Google Patents

Environmental sensor, particle counting system having an environmental sensor, and methods of operating the same Download PDF

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Publication number
WO2009032833A1
WO2009032833A1 PCT/US2008/075100 US2008075100W WO2009032833A1 WO 2009032833 A1 WO2009032833 A1 WO 2009032833A1 US 2008075100 W US2008075100 W US 2008075100W WO 2009032833 A1 WO2009032833 A1 WO 2009032833A1
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WIPO (PCT)
Prior art keywords
count
particle
total
environmental sensor
particles
Prior art date
Application number
PCT/US2008/075100
Other languages
French (fr)
Inventor
David L. Chandler
Daniel Edward Cain
Glenn Y. Kozuma
Joe Somoza
Original Assignee
Venturedyne, Ltd./Carnes Company, Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Venturedyne, Ltd./Carnes Company, Inc. filed Critical Venturedyne, Ltd./Carnes Company, Inc.
Priority to CN200880114662.4A priority Critical patent/CN101849176A/en
Priority to EP08799107.1A priority patent/EP2188617B1/en
Publication of WO2009032833A1 publication Critical patent/WO2009032833A1/en

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Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N15/00Investigating characteristics of particles; Investigating permeability, pore-volume or surface-area of porous materials
    • G01N15/02Investigating particle size or size distribution
    • G01N15/0205Investigating particle size or size distribution by optical means
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N35/00Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor
    • G01N35/00584Control arrangements for automatic analysers
    • G01N35/00722Communications; Identification
    • G01N35/00871Communications between instruments or with remote terminals
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N15/00Investigating characteristics of particles; Investigating permeability, pore-volume or surface-area of porous materials
    • G01N15/06Investigating concentration of particle suspensions
    • G01N15/075Investigating concentration of particle suspensions by optical means
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/02Devices for withdrawing samples
    • G01N1/22Devices for withdrawing samples in the gaseous state
    • G01N1/2202Devices for withdrawing samples in the gaseous state involving separation of sample components during sampling
    • G01N2001/222Other features
    • G01N2001/2223Other features aerosol sampling devices
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N15/00Investigating characteristics of particles; Investigating permeability, pore-volume or surface-area of porous materials
    • G01N15/10Investigating individual particles
    • G01N15/14Optical investigation techniques, e.g. flow cytometry
    • G01N2015/1486Counting the particles
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N35/00Automatic analysis not limited to methods or materials provided for in any single one of groups G01N1/00 - G01N33/00; Handling materials therefor
    • G01N35/00584Control arrangements for automatic analysers
    • G01N35/00722Communications; Identification
    • G01N2035/00891Displaying information to the operator

Definitions

  • the invention relates to environmental sensors, such as particle counters that are used to detect particles in air or liquid environments.
  • the invention also relates to particle counting systems having an environmental sensor, methods of operating the particle counting systems, and methods of operating the environmental sensor.
  • Particle detection allows for monitoring the manufacturing of a product that would be unsuitable for its intended purpose if contamination is present, even at the molecular level.
  • pharmaceutical manufacturers require environments that are sterile to avoid viable organisms from contacting a product being manufactured or packaged.
  • pharmaceutical manufacturers monitor specified areas to insure compliance with cleanliness standards.
  • the invention provides a method of communicating particle count information from an environmental sensor to a remote data acquisition system.
  • the method includes creating a flow of fluid from a space through the environmental sensor, detecting particles in the fluid, determining a first particle count having a relation to the number of detected particles in a first time interval, determining a second particle count having a relation to the number of detected particles in a second time interval, determining a total particle count based on the first particle count and the second particle count, and communicating the total particle count from the environmental sensor to the remote data acquisition system.
  • the communicating act includes wirelessly communicating the total particle count from the environmental sensor.
  • the invention provides a particle counting system.
  • the particle counting system includes a remote data acquisition system, and an environmental sensor to be placed in a space.
  • the environmental sensor includes an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet, a particle detection portion to detect particles in the fluid, and a controller connected to the particle detection portion.
  • the controller is configured to determine a plurality of counts of particles having a predetermined characteristic during a plurality of time intervals, respectively, store at least a count of the plurality of counts detected during one interval, and continuously update a total count using a rolling count technique for the plurality of counts.
  • the environmental sensor also includes a communication layer connected to the controller to communicate the count to the remote data acquisition system.
  • the communication layer includes an antenna to wirelessly communicate the count.
  • the invention provides an environmental sensor adapted to be placed in a space.
  • the environmental sensor includes an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet, a particle detection portion to detect particles in the fluid, and a controller connected to the particle detection portion.
  • the controller is configured to determine a plurality of particle counts, each particle count indicative of the number of particles detected during a corresponding time interval, and determine a total particle count indicative of the particles detected during a number of time intervals.
  • the environmental sensor also includes a wireless communication layer connected to the controller to wirelessly transmit the total particle count and at least one of the plurality of particle counts.
  • Fig. 1 is a schematic representation of a particle counting system.
  • Fig. 2 is a schematic representation of a second particle counting system.
  • Fig. 3 is a schematic representation of a particle counter.
  • Fig. 4 is a partial schematic representation of the particle counter illustrated in Fig. 3.
  • Fig. 5 is a schematic representation of an alternative construction for the controller illustrated in Fig. 4.
  • Fig. 6 is a schematic representation of an alternative construction for the communication layer illustrated in Fig. 4.
  • Fig. 7 is a schematic representation of a data acquisition system.
  • Fig. 8 is an information display in the form of a webpage.
  • Fig. 9 is a schematic representation of a status register.
  • Fig. 10 is a table illustrating a plurality of memory addresses.
  • embodiments of the invention include hardware, software, and electronic components or modules that, for purposes of discussion, may be illustrated and described as if the majority of the components were implemented solely in hardware.
  • the electronic based aspects of the invention may be implemented in software.
  • a plurality of hardware and software based devices, as well as a plurality of different structural components may be utilized to implement the invention.
  • the specific mechanical configurations illustrated in the drawings are intended to exemplify embodiments of the invention and that other alternative mechanical constructions are possible.
  • Fig. 1 is a schematic representation of a particle counting system 10 configured in a wireless access point topology.
  • the particle counting system 10 includes an environmental sensor 15, a wireless access point (WAP) 20, and a data acquisition system (DAS) 25 connected to the WAP 20 via a network 30. It is envisioned that the number of environmental sensors 15, WAPs 20, etc. can vary from the construction shown.
  • the environmental sensor 15 wirelessly communicates with the WAP 20 to send and receive information via wireless protocols (e.g., standard wireless protocols).
  • the WAP 20 is connected to the network 30 via a "wired" connection.
  • the WAP 20 can include a NETGEAR WGR614 wireless router.
  • the term "wired" is intended to define means of connection such as USB cable, DSL cable, Ethernet cable, and others.
  • the network 30 is intended to broadly cover either a connection to the Internet or also an intranet or internal network. It is also envisioned that the network 30 can include wireless connections.
  • the particle counting system 10 can also include other elements connected to the network 30, such as a computer 35.
  • Fig. 2 is a schematic representation of a particle counting system 40 configured with an ad-hoc topology. More specifically, the particle counting system 40 includes one or more environmental sensors 15 (only one environmental sensor 15 shown in Fig. 2) wirelessly connected to a DAS 25, which can alternatively be connected to a network 30. In constructions where the particle counting system 40 includes more than one environmental sensor 15, each environmental sensor 15 includes an address which is recognized by the DAS 25. Each environmental sensor 15 has a unique address that allows the DAS 25 to receive, store, and communicate information from the various environmental sensors 15, which may be located in distinct and remote environments.
  • the particle counting system 40 includes one or more environmental sensors 15 (only one environmental sensor 15 shown in Fig. 2) wirelessly connected to a DAS 25, which can alternatively be connected to a network 30.
  • each environmental sensor 15 includes an address which is recognized by the DAS 25.
  • Each environmental sensor 15 has a unique address that allows the DAS 25 to receive, store, and communicate information from the various environmental sensors 15, which may be located in distinct and remote environments.
  • information is broadly construed to comprise signals (e.g., analog signals, digital signals, etc.), states, data (e.g., packet data, non-packet data, etc.), etc., for providing knowledge, values, events, facts, measures, outcomes, and similar items.
  • signals e.g., analog signals, digital signals, etc.
  • states e.g., states, data (e.g., packet data, non-packet data, etc.), etc., for providing knowledge, values, events, facts, measures, outcomes, and similar items.
  • the particle counting systems 10 and 40 are configured to communicate information from the environmental sensor 15 to the DAS 25 to exchange information regarding the space in which the environmental sensor 15 is located, also defined an environmental zone (e.g., a "clean" zone).
  • an environmental zone e.g., a "clean" zone.
  • the DAS 25 can access the environmental sensor 15 remotely through the network 30, and in the particle counting system 40, the DAS 25 directly accesses the environmental sensor 15 through a wireless connection.
  • the topologies and/or configurations described in Figs. 1 and 2 are for exemplary purposes and that other configurations of the particle counting system may fall within aspects of the invention.
  • the sensor 15 can communicate with the WAP 20 or the DAS 25 via wire means.
  • Fig. 3 is a schematic representation of an exemplary environmental sensor. More specifically, the environmental sensor shown in Fig. 3 is a particle counter 50 configured to detect particles within a predetermined size range.
  • the particle counter 50 is an aerosol particle counter that operates under the principle of light scattering detection. However, other aerosol particle counters (e.g., a particle counter that operates under the principle of light obscuration) and liquid particle counters can be used, among others.
  • the particle counter 50 includes a fluid movement portion 55 and a control portion 60.
  • the fluid movement portion 55 includes a fluid (e.g., air) inlet 65, a particle detection portion 70, a vacuum source 75, a filter 80, and a fluid outlet 85.
  • a fluid e.g., air
  • a flow of air is created by the vacuum source 75 (e.g., an air pump or blower).
  • the flow enters the particle counter 50 through the inlet 65, as shown by arrows 90, and traverses to the particle detection portion 70 where the portions 70 detects particles in the air, as explained in more detail below.
  • the flow then traverses to the filter 80 and exits through the outlet 85.
  • the vacuum source 75 is shown as being part of the flow path.
  • the particle counter 50 can include a vacuum source not directly in the path of the flow or, alternatively, the particle counter 50 can include an external vacuum source.
  • Fig. 3 illustrates one filter 80 located near the outlet 85.
  • the particle counter 50 can include a different number of filters (including zero) and the location of the filter may vary.
  • the fluid movement portion 75 can include a tube or hose with one end connected to the inlet 65 such that the vacuum source (internal or external) generates a flow from the other end of the tube and through the particle counter 50 as explained above.
  • the control portion 60 of the particle counter 50 includes a controller 100 operable to control and operate the particle counter 50.
  • the control portion 60 also includes a power source 105, a flow sensor 110, a light source 115 (e.g., a laser beam generator), an optical detector 120, a communication layer 125, a display system 130, and an I/O layer 135.
  • the flow sensor 110 is operable to generate a signal indicative of the mass of the air flowing through the particle counter 50.
  • the signal generated by the flow sensor 110 allows the controller 100 to operate the vacuum source 75 to maintain a constant flow through the particle counter 50.
  • the controller 100 can operate the vacuum source 75 to maintain a constant flow rate of 1 cubic foot per minute (ft 3 /min), which is substantially equal to 28.3 liters per minute (It/min).
  • the vacuum source 75 can generate other flow rates based on desired parameters or the particular application of the particle counter 50.
  • the environmental sensor 50 can include an external vacuum source not connected to the control portion 60 such that the external vacuum source is controlled independently with respect to the control portion to generate a fluid flow through the particle counter 50.
  • the display system 130 includes a multiple light display to indicate the status of the particle counter 50. More particularly, the display system 130 includes an "on/off type display related to the power source, an alarm system, a particle count interval, the light source, and the flow status. For example, the display system 130 can indicate whether the particle counter is on or off, whether a fault related to the air flow or light source 115 is detected, whether the counter 50 is detecting a particle, whether the light source 115 is operating, and whether the flow rate remains constant. Other constructions of the particle counter 50 can include the display system 130 with a different number and combination of lights, or alternatively a different display element (e.g., an LCD screen). Though not particularly described, the I/O layer 135 illustrates alternative input/output connections, displays, and/or switches allowing a user to control and/or interact with the particle counter 50.
  • the display system 130 includes an "on/off type display related to the power source, an alarm system, a particle count interval, the light source, and the flow status.
  • the display system 130
  • the light source 115 generates a laser beam 140 within the particle detection portion 70 of the particle counter 50. Particles flow through the particle detection portion 70, as shown by arrow 145, and through the laser beam 140. The particles traversing the particle detection portion 70 result in light scattering (represented by 150), which is detected by the optical detector 120.
  • the optical detector 120 generates a voltage pulse as a result of detecting the light scattering 150 and sends the voltage pulse to the controller 100.
  • the controller 100 is operable to determine information regarding the particles (e.g., particle size, velocity, composition) based on the voltage pulse generated by the optical detector 120. The information determined by the controller 100 can be saved in memory and/or sent to the DAS 25, for example, by the communication layer 125 of the particle counter 50.
  • Fig. 4 is a schematic representation of the control portion 60 as it relates more specifically to the detection of particles, and to the processing and transmitting of information related to the detected particles. Accordingly, Fig. 4 illustrates in more detail the optical detector 120, the controller 100, and the communication layer 125.
  • the vacuum source 75, power source 105, flow sensor 110, light source 115, display system 130, and I/O layer 135 are also shown connected to the controller 100 for illustration purposes.
  • the optical detector 120 includes a photo detector and optics 155 to detect the scattering light 150, and an amplifier 160 to generate a voltage pulse as a result of detecting the scattering 150.
  • the controller 100 includes additional amplifiers 165, a processor 170, and a memory 175.
  • the processor 170 includes an analog-to-digital converter (A/D) 180 and a pulse height analyzer or voltage comparator 185.
  • the processor 170 may take the form of a microprocessor, a digital signal processor, a microcontroller, or similar devices that can execute instructions.
  • the A/D converter 180 and/or voltage comparator 185 can be distinct from the processor 170, and the memory 175 can be combined with the processor 170.
  • the voltage pulse generated by the optical detector 120 is received for processing at the controller 100 by the amplifier(s) 165 and the processor 170. More specifically, the amplifier(s) 165 can amplify and filter the voltage pulse, and the A/D 180 can transform the voltage pulse into a digital signal for the voltage comparator 185 to analyze. The voltage comparator 185 analyzes the digital signal by comparing the signal to predetermined values or voltage thresholds. Based on the comparison, the processor 170 can determine whether the voltage pulse was greater than a voltage threshold, for example, and save the information in the memory 175. As the controller 100 receives pulses generated by the optical detector 120, a count of particles with predetermined characteristics (e.g., particle size) can be stored in the memory 175.
  • predetermined characteristics e.g., particle size
  • Fig. 5 is a schematic representation of a controller 100A, which is an alternative construction of the controller 100 shown in Fig. 4.
  • the controller 100A includes the amplifier(s) 165 and the memory 175.
  • the controller 100A also includes a processor 170A with a voltage comparator 185A that compares analog voltage pulses generated by the optical detector 120 (not shown in Fig. 5). Accordingly, the controller 100A analyses and determines particle size information based on analog signals, whereas the controller 100 analyzes and determines particle size information based on digital signals.
  • the first particle count is a count of particles with a size greater than 0.5 microns.
  • the second particle count is a count of particles with a size greater than 5 microns.
  • a different particle counts can be stored in the memory 175.
  • the voltage thresholds related to each particle size e.g., 0.5 microns and 5 microns
  • the calibration process can include creating an aerosol cloud of particles with a known size, such as 0.5 microns or 5 microns, and allowing the aerosol cloud to flow through particle counter 50.
  • the DAS 25 can be used in the calibration process to observe the particle size detected by the particle counter 50 such that an operator can adjust the particle counter 50 until the correct information is generated.
  • the particle counter 50 can be calibrated to detect a wide range of particle sizes, the particle counter 50 is usually calibrated to sense particles with a size of 0.5 microns and 5 microns because 0.5 microns relates to a specific cleanliness level for a clean zone, and 5 microns relates to the size of bacteria or similar elements that are of interest for a clean zone.
  • the communication layer 125 includes a processor 190, a memory 195, a modulator/demodulator circuit 200, and an antenna 205.
  • the communication layer 125 includes a Digi Connect wireless module to allow communication between the particle counter 50 and a second device. More specifically, the communication layer 125 receives the particle size information from the controller 100 and is operable to wirelessly transmit the information to the WAP 20, as shown in Fig. 1 , or directly to the DAS 25 in an ad-hoc topology, as shown in Fig. 2.
  • the communication layer 125 can include a web page design stored in the memory 195, be operable to combine particle count information and/or status information (of the particle counter 50) with the web page design, and transmit the combined information.
  • the communication layer 125 also receives information and/or instructions to operate the particle counter 50.
  • the communication layer 125 can receive particle count requests from the DAS 25 or a status request from a computer (e.g., computer 35 shown in Fig. 1 ).
  • Fig. 6 is a schematic representation of a communication layer 125A, which is an alternative construction of the communication layer 125 shown in Fig. 4.
  • the communication layer 125A includes the processor 190 and the memory 195.
  • the communication layer 125A also includes a wire connector, such as an RJ-45 connector 210, for communication with another device or network.
  • the particle counter 50 can include a communication layer that is integrally manufactured with a controller. The controller would then be operable to control and communicate as described in regards to the controller 100 and the communication layers 125 or 125A.
  • Fig. 7 is a schematic representation of the DAS 25 shown in Figs. 1 and 2.
  • the DAS 25 includes a computer system 215 having a processor 220, a communication layer 225, a memory 230, a display system 235, and an I/O layer 240.
  • the computer system 215 is described herein as it relates to the particle counter 50.
  • the computer system 215 can communicate with other devices, such as the sensing devices illustrated in Fig. 7.
  • the sensing devices can include a temperature sensor 245, a humidity sensor 250, and a pressure sensor 255.
  • the DAS 25 is configured to communicate with the environmental sensor 15 to send information, such as control commands or data requests, and to receive information, such as particle counts and status of the environmental sensor 15.
  • the DAS 25 includes a set of instructions identified as a driver 260 that are designed specifically to operate the environmental sensor 15.
  • the driver 260 can take data collected by the particle counter 50, and alternatively take data from other sensors such as the temperature sensor 245, humidity sensor 250, and pressure sensor 255, and send the data to a database for storage.
  • the driver 260 can also transfer the data to a memory location where it can be retrieved for further processing.
  • Processing of the data by the DAS 25 can include comparing the data to predetermined thresholds and to present the data through the display system 235 in a manner that is significant to the user.
  • the driver 260 can also include instructions to operate specific elements of the particle counter 50. For example, the driver 260 can individually operate and monitor the vacuum source 75, light source 115, and display system 130.
  • the particle counting system 10, 40 can include the particle counter 50 calibrated to detect particles with a size larger than 0.5 microns.
  • the computer system 215 with the driver 260 can be configured to move data related to particle counts to specific memory addresses in the particle counter 50, to retrieve data related to particle counts combined with web page information from the communication layer 125, and to display the retrieved data with the display system 235.
  • Fig. 8 is an exemplary information display 265 generated by the display system 235.
  • the information display 265 displays various information, which may include system information 270, status information 275, and count information 280.
  • the information display 265 is illustrated in the form of a webpage accessed by the computer system 215 though the network 30, for example.
  • the display 265 can take the form of the webpage shown in Fig. 8 when the particle counter 50 and computer system 215 are in an ad-hoc topography, as shown in Fig. 2.
  • the system information 270 refers to the specific type of particle counter 50 and network connection.
  • the status information 275 refers to the status of the particle counter 50 as well as the status of specific elements of the particle counter 50, such as the light source 115 and vacuum source 75.
  • the count information 280 refers to data detected by the particle counter 50, such as flow rate and particle counts.
  • Fig. 9 is a schematic representation of the status information 275 stored in a memory location of the memory 175. More specifically, the status information 275 is shown in a first memory address 285 and a second memory address 290, each address being a 16-bit memory address.
  • the driver 260 needs only to retrieve information in memory addresses 285, 290.
  • the computer system 215 matches specific bits of the memory addresses 285, 290 to the status of a corresponding element of the particle counter 50, and displays the status information 275 (e.g., light source being on or off) accordingly.
  • Fig. 9 is a schematic representation of the status information 275 stored in a memory location of the memory 175. More specifically, the status information 275 is shown in a first memory address 285 and a second memory address 290, each address being a 16-bit memory address.
  • the driver 260 needs only to retrieve information in memory addresses 285, 290.
  • the computer system 215 matches specific bits of the memory addresses 285, 290 to the status of a corresponding element of the particle counter
  • 10 is a schematic representation of the memory 175 including a number of memory addresses 300 dedicated to different types of counts and information related to the particle counter 50 (e.g., status information).
  • the driver 260 retrieves the count information 280 from specific memory addresses (e.g., memory addresses 12 and 13) in the memory 175 of the particle counter 50.
  • the computer system 215 is operable to display the count information 280 (e.g., the number of particles with particle size larger than 0.5 microns) as a result of retrieving the count from a dedicated memory address in memory 175. Therefore, size information of the particle is not sent or generated by the particle counter 50.
  • the display system 235 can display size information with the count information 280 based on the known calibration of the particle counter 50 and the dedicated address in the memory 175 where the count information 280 was retrieved. Similarly, status information 275 can be retrieved from a specific address in the memory 175 of the particle counter 50. As a result, data transfer between the particle counter 50 and the computer system 215 is improved.
  • the particle counter 50 is calibrated to establish, among other parameters, the size of the particles to be detected and the flow rate.
  • the particle counter 50 can be calibrated to detect particles of two particle sizes (e.g., particle size larger than 0.5 microns and particle size larger than 5 microns).
  • the particle counter 50 is also calibrated to have a substantially constant flow rate.
  • the particle counter 50 can be calibrated to generate a flow rate of about 1 ft 3 /min (about 28.3 It/min).
  • the particle counter 50 can be calibrated to generate different flow rates, such as 25 It/min, 50 It/min, 75 It/min, and 100 It/min.
  • the particle counter 50 Based on the calibrated flow rate, it is possible to determine the amount of time it takes for the particle counter 50 to sample the complete volume of a clean zone. For analysis purposes, predetermined sample volumes are established such that a particle count can be displayed as a function of a standard unit of volume (e.g., 1 m 3 or 1 ft 3 . Accordingly, for a particle counter 50 calibrated to generate a flow rate of 1 ft 3 /min, it is determined that the particle counter 50 can sample a sample volume of 1 m 3 in about 35.3 minutes, and a sample volume of 1 ft 3 in about 1 minute.
  • a standard unit of volume e.g., 1 m 3 or 1 ft 3
  • the particle counter 50 is further configured to sample a sample volume in intervals. More specifically, the particle counter 50 is configured to sample a sample volume in sixty intervals. Accordingly, if the sample volume is established to be 1 m 3 , the particle counter 50 can sample 1/60 m 3 in about 35.3/60 minutes. Similarly, if the sample volume is established to be 1 ft 3 , the particle counter 50 can sample 1/60 ft 3 in about one second. Based on the application and/or desired characteristics of the particle counter 50, other constructions can include the particle counter 50 being calibrated to sample full sample volumes with a different number of intervals. Sampling the sample volume using time intervals allows the particle counter 50 to store information related to partial counts in the memory 175.
  • the memory 175 can include dedicated memory addresses (e.g., memory addresses 300) for partial count information, such as the number of particles for one time interval or the total particle count retrievable by the DAS 25 before the full sample volume has been sampled or the particle count for a previously completed sample.
  • dedicated memory addresses e.g., memory addresses 300
  • partial count information such as the number of particles for one time interval or the total particle count retrievable by the DAS 25 before the full sample volume has been sampled or the particle count for a previously completed sample.
  • sampling the sample volume using intervals allows the particle counter 50 to include operational features, defined as rolling counts, forced counts, and fault detection/salvaging data.
  • the rolling counts feature allows the particle counter 50 to determine and store a particle count for the most recent sample volume. More specifically, the rolling counts feature is implemented by the particle counter 50 continuously adding the particle counts of time intervals. As indicated above, once sixty time intervals have elapsed, the particle count of the full sample volume is available at a predetermined memory address 300. As the particle counter 50 continues to sample the clean zone, the particle counter 50 uses the particle count taken during the latest interval and discards the particle count taken from the oldest interval to update the particle count of the full sample volume. Consequently, the particle count saved in the memory address corresponding to the particle count of the full sample volume is the count obtained during the most recent sample volume. In the illustrated construction, memory addresses 300 identified as 0 and 1 in Fig.
  • the forced counts feature allows the DAS 25 to utilize the particle counter 50 to test the operation of the programming logic of the DAS under fault conditions.
  • the forced counts feature also tests an alarm system (not shown) that actuates as a result of a fault condition, or as a result of comparing the particle counts obtained from the particle counter 50 to predetermined threshold values.
  • memory addresses 300 defined by numerals 26 through 51 correspond to forced count information saved in the memory 175.
  • the driver 260 of the DAS 25 includes instructions to command the particle counter to take information from addresses 300 dedicated to forced count information and copy (also sometimes referred to as move) the information to corresponding memory addresses 300 where actual or detected information is saved during operation of the particle counter 50.
  • the driver 260 then reads the information from the memory 175 as if the DAS 25 is retrieving actual detected information.
  • the driver 260 commands the particle counter to take the count from memory addresses 300 corresponding to forced count information, and copy the information to the memory addresses 300 where the particle count is saved during operation of the particle counter 50, and retrieves the information to the DAS 25.
  • the test is considered successful when the alarm is activated as a result of the DAS 25 receiving and processing the forced count information. As shown in Fig. 10, every memory address 300 that includes forced count information has a corresponding memory address 300 that includes information stored during operation of the particle counter 50.
  • an auxiliary computer or controller e.g., computer 35 of the particle counting system 10 illustrated in Fig. 1
  • the auxiliary computer may be equipped with a program operable to control the particle counter and communicate with the particle counter over the network.
  • the auxiliary computer sends commands to cause the particle counter to send forced counts and status information to the DAS under test.
  • the DAS programming is tested in this scenario without the necessary test programs being run in the DAS itself.
  • the fault detection feature allows the particle counter 50 to provide accurate, as well as timely count information. More specifically, the particle counter 50 can detect a fault condition and can react to the fault condition such that the particle count information is uncorrupted. The particle counter 50 can detect fault conditions such as malfunction of the light source 115 or air flow interruption, for example. In the case of a fault condition, the memory address corresponding to status information 275, as shown in Fig. 9, are updated. Consequently, the particle counter 50 discards the count information obtained in the interval during which the fault condition occurred. Once the status information 275 indicates the fault condition does not exist, the particle counter 50 updates the total particle count with the counts detected in the interval during which the fault condition is no longer detected.
  • This procedure allows the particle counter 50 to provide count information for a full sample volume without having to discard all the counts corresponding to that sample volume in the situation where a fault condition is detected. For example, if the sample volume is determined to be 1 ft 3 and a fault condition was detected during one of the sixty intervals, the particle counter 50 can provide with a particle count of the full sample volume in about 61 seconds (one additional second than the case in which no fault condition is detected). Accordingly, the count detected during one faulty interval is discarded instead of discarding the particle count determined for the whole sample volume.

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Abstract

An environmental sensor including an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet, a particle detection portion to detect particles in the fluid, and a controller connected to the particle detection portion. The environmental sensor can be in communication with a data acquisition system (e.g., via a wireless access point) to form a particle counting system. Also disclosed are methods of operating the environmental sensor and methods of operating the particle detection system.

Description

ENVIRONMENTAL SENSOR, PARTICLE COUNTING SYSTEM HAVING AN ENVIRONMENTAL SENSOR, AND METHODS OF OPERATING THE SAME
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the priority benefit of U.S. Application No.
11/849,421 , filed September 4, 2007, which is incorporated herein by reference in its entirety.
BACKGROUND
[0002] The invention relates to environmental sensors, such as particle counters that are used to detect particles in air or liquid environments. The invention also relates to particle counting systems having an environmental sensor, methods of operating the particle counting systems, and methods of operating the environmental sensor.
[0003] Particle detection, among other uses, allows for monitoring the manufacturing of a product that would be unsuitable for its intended purpose if contamination is present, even at the molecular level. For example, pharmaceutical manufacturers require environments that are sterile to avoid viable organisms from contacting a product being manufactured or packaged. Also, pharmaceutical manufacturers monitor specified areas to insure compliance with cleanliness standards.
[0004] Another industry that generally requires the use of a particle counting system in an environment is the semiconductor manufacturing industry. Semiconductor manufacturers monitor the cleanliness of their process fluids, gasses, and environments to identify and eliminate sources of contamination. Other industries can use particle counting systems to detect and control contamination that affects product performance and quality. For example, manufacturers of automotive products, portable equipment, micro-machined structures, and optical assemblies may rely on the use of particle counting systems for some of their manufacturing processes. [0005] Accordingly, there is the need for an environmental sensor that performs, among other things, reliable particle counts and allows for access and distribution of information related to the particle counts. There is also a need for a particle counting system incorporating such an environmental sensor.
SUMMARY
[0006] In one embodiment, the invention provides a method of communicating particle count information from an environmental sensor to a remote data acquisition system. The method includes creating a flow of fluid from a space through the environmental sensor, detecting particles in the fluid, determining a first particle count having a relation to the number of detected particles in a first time interval, determining a second particle count having a relation to the number of detected particles in a second time interval, determining a total particle count based on the first particle count and the second particle count, and communicating the total particle count from the environmental sensor to the remote data acquisition system. The communicating act includes wirelessly communicating the total particle count from the environmental sensor.
[0007] In another embodiment, the invention provides a particle counting system. The particle counting system includes a remote data acquisition system, and an environmental sensor to be placed in a space. The environmental sensor includes an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet, a particle detection portion to detect particles in the fluid, and a controller connected to the particle detection portion. The controller is configured to determine a plurality of counts of particles having a predetermined characteristic during a plurality of time intervals, respectively, store at least a count of the plurality of counts detected during one interval, and continuously update a total count using a rolling count technique for the plurality of counts. The environmental sensor also includes a communication layer connected to the controller to communicate the count to the remote data acquisition system. The communication layer includes an antenna to wirelessly communicate the count. [0008] In another embodiment, the invention provides an environmental sensor adapted to be placed in a space. The environmental sensor includes an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet, a particle detection portion to detect particles in the fluid, and a controller connected to the particle detection portion. The controller is configured to determine a plurality of particle counts, each particle count indicative of the number of particles detected during a corresponding time interval, and determine a total particle count indicative of the particles detected during a number of time intervals. The environmental sensor also includes a wireless communication layer connected to the controller to wirelessly transmit the total particle count and at least one of the plurality of particle counts.
[0009] Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] Fig. 1 is a schematic representation of a particle counting system.
[0011] Fig. 2 is a schematic representation of a second particle counting system.
[0012] Fig. 3 is a schematic representation of a particle counter.
[0013] Fig. 4 is a partial schematic representation of the particle counter illustrated in Fig. 3.
[0014] Fig. 5 is a schematic representation of an alternative construction for the controller illustrated in Fig. 4.
[0015] Fig. 6 is a schematic representation of an alternative construction for the communication layer illustrated in Fig. 4.
[0016] Fig. 7 is a schematic representation of a data acquisition system.
[0017] Fig. 8 is an information display in the form of a webpage. [0018] Fig. 9 is a schematic representation of a status register.
[0019] Fig. 10 is a table illustrating a plurality of memory addresses.
DETAILED DESCRIPTION
[0020] Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of "including," "comprising," or "having" and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items.
[0021] Although directional references, such as upper, lower, downward, upward, rearward, bottom, front, rear, etc., may be made herein in describing the drawings, these references are made relative to the drawings (as normally viewed) for convenience. These directions are not intended to be taken literally or limit the invention in any form. In addition, terms such as "first", "second", and "third" are used herein for purposes of description and are not intended to indicate or imply relative importance or significance.
[0022] In addition, it should be understood that embodiments of the invention include hardware, software, and electronic components or modules that, for purposes of discussion, may be illustrated and described as if the majority of the components were implemented solely in hardware. However, one of ordinary skill in the art, and based on a reading of this detailed description, would recognize that, in at least one embodiment, the electronic based aspects of the invention may be implemented in software. As such, it should be noted that a plurality of hardware and software based devices, as well as a plurality of different structural components, may be utilized to implement the invention. Furthermore, and as described in subsequent paragraphs, the specific mechanical configurations illustrated in the drawings are intended to exemplify embodiments of the invention and that other alternative mechanical constructions are possible.
[0023] Fig. 1 is a schematic representation of a particle counting system 10 configured in a wireless access point topology. The particle counting system 10 includes an environmental sensor 15, a wireless access point (WAP) 20, and a data acquisition system (DAS) 25 connected to the WAP 20 via a network 30. It is envisioned that the number of environmental sensors 15, WAPs 20, etc. can vary from the construction shown.
[0024] In the illustrated construction, the environmental sensor 15 wirelessly communicates with the WAP 20 to send and receive information via wireless protocols (e.g., standard wireless protocols). The WAP 20 is connected to the network 30 via a "wired" connection. In one construction, the WAP 20 can include a NETGEAR WGR614 wireless router. The term "wired" is intended to define means of connection such as USB cable, DSL cable, Ethernet cable, and others. Similarly, the network 30 is intended to broadly cover either a connection to the Internet or also an intranet or internal network. It is also envisioned that the network 30 can include wireless connections. In addition to the specified DAS 25 shown in Fig. 1 , the particle counting system 10 can also include other elements connected to the network 30, such as a computer 35.
[0025] Fig. 2 is a schematic representation of a particle counting system 40 configured with an ad-hoc topology. More specifically, the particle counting system 40 includes one or more environmental sensors 15 (only one environmental sensor 15 shown in Fig. 2) wirelessly connected to a DAS 25, which can alternatively be connected to a network 30. In constructions where the particle counting system 40 includes more than one environmental sensor 15, each environmental sensor 15 includes an address which is recognized by the DAS 25. Each environmental sensor 15 has a unique address that allows the DAS 25 to receive, store, and communicate information from the various environmental sensors 15, which may be located in distinct and remote environments. As used herein, the term "information" is broadly construed to comprise signals (e.g., analog signals, digital signals, etc.), states, data (e.g., packet data, non-packet data, etc.), etc., for providing knowledge, values, events, facts, measures, outcomes, and similar items.
[0026] With reference to Figs. 1 and 2, the particle counting systems 10 and 40 are configured to communicate information from the environmental sensor 15 to the DAS 25 to exchange information regarding the space in which the environmental sensor 15 is located, also defined an environmental zone (e.g., a "clean" zone). One difference between the particle counting systems 10 and 40 is that, in the particle counting system 10, the DAS 25 can access the environmental sensor 15 remotely through the network 30, and in the particle counting system 40, the DAS 25 directly accesses the environmental sensor 15 through a wireless connection. It is to be understood, however, that the topologies and/or configurations described in Figs. 1 and 2 are for exemplary purposes and that other configurations of the particle counting system may fall within aspects of the invention. For example, it is envisioned that the sensor 15 can communicate with the WAP 20 or the DAS 25 via wire means.
[0027] Fig. 3 is a schematic representation of an exemplary environmental sensor. More specifically, the environmental sensor shown in Fig. 3 is a particle counter 50 configured to detect particles within a predetermined size range. The particle counter 50 is an aerosol particle counter that operates under the principle of light scattering detection. However, other aerosol particle counters (e.g., a particle counter that operates under the principle of light obscuration) and liquid particle counters can be used, among others. The particle counter 50 includes a fluid movement portion 55 and a control portion 60. The fluid movement portion 55 includes a fluid (e.g., air) inlet 65, a particle detection portion 70, a vacuum source 75, a filter 80, and a fluid outlet 85.
[0028] In the construction shown in Fig. 3, a flow of air is created by the vacuum source 75 (e.g., an air pump or blower). The flow enters the particle counter 50 through the inlet 65, as shown by arrows 90, and traverses to the particle detection portion 70 where the portions 70 detects particles in the air, as explained in more detail below. The flow then traverses to the filter 80 and exits through the outlet 85. In Fig. 3, the vacuum source 75 is shown as being part of the flow path. However, other constructions of the particle counter 50 can include a vacuum source not directly in the path of the flow or, alternatively, the particle counter 50 can include an external vacuum source. Similarly, Fig. 3 illustrates one filter 80 located near the outlet 85. However, other constructions of the particle counter 50 can include a different number of filters (including zero) and the location of the filter may vary. In yet other constructions, the fluid movement portion 75 can include a tube or hose with one end connected to the inlet 65 such that the vacuum source (internal or external) generates a flow from the other end of the tube and through the particle counter 50 as explained above.
[0029] The control portion 60 of the particle counter 50 includes a controller 100 operable to control and operate the particle counter 50. The control portion 60 also includes a power source 105, a flow sensor 110, a light source 115 (e.g., a laser beam generator), an optical detector 120, a communication layer 125, a display system 130, and an I/O layer 135. During operation of the particle counter 50, the flow sensor 110 is operable to generate a signal indicative of the mass of the air flowing through the particle counter 50. The signal generated by the flow sensor 110 allows the controller 100 to operate the vacuum source 75 to maintain a constant flow through the particle counter 50. For example, the controller 100 can operate the vacuum source 75 to maintain a constant flow rate of 1 cubic foot per minute (ft3/min), which is substantially equal to 28.3 liters per minute (It/min). However, the vacuum source 75 can generate other flow rates based on desired parameters or the particular application of the particle counter 50. In other constructions, the environmental sensor 50 can include an external vacuum source not connected to the control portion 60 such that the external vacuum source is controlled independently with respect to the control portion to generate a fluid flow through the particle counter 50.
[0030] Still with reference to Fig. 3, the display system 130 includes a multiple light display to indicate the status of the particle counter 50. More particularly, the display system 130 includes an "on/off type display related to the power source, an alarm system, a particle count interval, the light source, and the flow status. For example, the display system 130 can indicate whether the particle counter is on or off, whether a fault related to the air flow or light source 115 is detected, whether the counter 50 is detecting a particle, whether the light source 115 is operating, and whether the flow rate remains constant. Other constructions of the particle counter 50 can include the display system 130 with a different number and combination of lights, or alternatively a different display element (e.g., an LCD screen). Though not particularly described, the I/O layer 135 illustrates alternative input/output connections, displays, and/or switches allowing a user to control and/or interact with the particle counter 50.
[0031] During operation of the particle counter 50, particles are detected by light scattering. More specifically, the light source 115 generates a laser beam 140 within the particle detection portion 70 of the particle counter 50. Particles flow through the particle detection portion 70, as shown by arrow 145, and through the laser beam 140. The particles traversing the particle detection portion 70 result in light scattering (represented by 150), which is detected by the optical detector 120. The optical detector 120 generates a voltage pulse as a result of detecting the light scattering 150 and sends the voltage pulse to the controller 100. The controller 100 is operable to determine information regarding the particles (e.g., particle size, velocity, composition) based on the voltage pulse generated by the optical detector 120. The information determined by the controller 100 can be saved in memory and/or sent to the DAS 25, for example, by the communication layer 125 of the particle counter 50.
[0032] Fig. 4 is a schematic representation of the control portion 60 as it relates more specifically to the detection of particles, and to the processing and transmitting of information related to the detected particles. Accordingly, Fig. 4 illustrates in more detail the optical detector 120, the controller 100, and the communication layer 125. The vacuum source 75, power source 105, flow sensor 110, light source 115, display system 130, and I/O layer 135 are also shown connected to the controller 100 for illustration purposes. The optical detector 120 includes a photo detector and optics 155 to detect the scattering light 150, and an amplifier 160 to generate a voltage pulse as a result of detecting the scattering 150. The controller 100 includes additional amplifiers 165, a processor 170, and a memory 175. The processor 170 includes an analog-to-digital converter (A/D) 180 and a pulse height analyzer or voltage comparator 185. The processor 170 may take the form of a microprocessor, a digital signal processor, a microcontroller, or similar devices that can execute instructions. Of course, the A/D converter 180 and/or voltage comparator 185 can be distinct from the processor 170, and the memory 175 can be combined with the processor 170.
[0033] The voltage pulse generated by the optical detector 120 is received for processing at the controller 100 by the amplifier(s) 165 and the processor 170. More specifically, the amplifier(s) 165 can amplify and filter the voltage pulse, and the A/D 180 can transform the voltage pulse into a digital signal for the voltage comparator 185 to analyze. The voltage comparator 185 analyzes the digital signal by comparing the signal to predetermined values or voltage thresholds. Based on the comparison, the processor 170 can determine whether the voltage pulse was greater than a voltage threshold, for example, and save the information in the memory 175. As the controller 100 receives pulses generated by the optical detector 120, a count of particles with predetermined characteristics (e.g., particle size) can be stored in the memory 175.
[0034] Fig. 5 is a schematic representation of a controller 100A, which is an alternative construction of the controller 100 shown in Fig. 4. The controller 100A includes the amplifier(s) 165 and the memory 175. The controller 100A also includes a processor 170A with a voltage comparator 185A that compares analog voltage pulses generated by the optical detector 120 (not shown in Fig. 5). Accordingly, the controller 100A analyses and determines particle size information based on analog signals, whereas the controller 100 analyzes and determines particle size information based on digital signals.
[0035] In one exemplary construction of the particle counter 50, two particle counts are stored in the memory 175. The first particle count is a count of particles with a size greater than 0.5 microns. The second particle count is a count of particles with a size greater than 5 microns. In other constructions, a different particle counts can be stored in the memory 175. The voltage thresholds related to each particle size (e.g., 0.5 microns and 5 microns) are determined through a calibration process of the particle counter 50. The calibration process can include creating an aerosol cloud of particles with a known size, such as 0.5 microns or 5 microns, and allowing the aerosol cloud to flow through particle counter 50. The DAS 25 can be used in the calibration process to observe the particle size detected by the particle counter 50 such that an operator can adjust the particle counter 50 until the correct information is generated. Though the particle counter 50 can be calibrated to detect a wide range of particle sizes, the particle counter 50 is usually calibrated to sense particles with a size of 0.5 microns and 5 microns because 0.5 microns relates to a specific cleanliness level for a clean zone, and 5 microns relates to the size of bacteria or similar elements that are of interest for a clean zone.
[0036] Referring again to Fig. 4, the communication layer 125 includes a processor 190, a memory 195, a modulator/demodulator circuit 200, and an antenna 205. In one exemplary construction of the particle counter 50, the communication layer 125 includes a Digi Connect wireless module to allow communication between the particle counter 50 and a second device. More specifically, the communication layer 125 receives the particle size information from the controller 100 and is operable to wirelessly transmit the information to the WAP 20, as shown in Fig. 1 , or directly to the DAS 25 in an ad-hoc topology, as shown in Fig. 2. In some constructions, the communication layer 125 can include a web page design stored in the memory 195, be operable to combine particle count information and/or status information (of the particle counter 50) with the web page design, and transmit the combined information. The communication layer 125 also receives information and/or instructions to operate the particle counter 50. For example, the communication layer 125 can receive particle count requests from the DAS 25 or a status request from a computer (e.g., computer 35 shown in Fig. 1 ).
[0037] Fig. 6 is a schematic representation of a communication layer 125A, which is an alternative construction of the communication layer 125 shown in Fig. 4. The communication layer 125A includes the processor 190 and the memory 195. The communication layer 125A also includes a wire connector, such as an RJ-45 connector 210, for communication with another device or network. In yet another construction, the particle counter 50 can include a communication layer that is integrally manufactured with a controller. The controller would then be operable to control and communicate as described in regards to the controller 100 and the communication layers 125 or 125A.
[0038] Fig. 7 is a schematic representation of the DAS 25 shown in Figs. 1 and 2. In the illustrated construction, the DAS 25 includes a computer system 215 having a processor 220, a communication layer 225, a memory 230, a display system 235, and an I/O layer 240. The computer system 215 is described herein as it relates to the particle counter 50. However, the computer system 215 can communicate with other devices, such as the sensing devices illustrated in Fig. 7. The sensing devices can include a temperature sensor 245, a humidity sensor 250, and a pressure sensor 255.
[0039] With reference to Figs. 1 , 2 and 7, the DAS 25 is configured to communicate with the environmental sensor 15 to send information, such as control commands or data requests, and to receive information, such as particle counts and status of the environmental sensor 15. In the illustrated construction, the DAS 25 includes a set of instructions identified as a driver 260 that are designed specifically to operate the environmental sensor 15. For example, the driver 260 can take data collected by the particle counter 50, and alternatively take data from other sensors such as the temperature sensor 245, humidity sensor 250, and pressure sensor 255, and send the data to a database for storage. The driver 260 can also transfer the data to a memory location where it can be retrieved for further processing. Processing of the data by the DAS 25 can include comparing the data to predetermined thresholds and to present the data through the display system 235 in a manner that is significant to the user. The driver 260 can also include instructions to operate specific elements of the particle counter 50. For example, the driver 260 can individually operate and monitor the vacuum source 75, light source 115, and display system 130.
[0040] In the constructions shown in Figs. 1 and 2, the particle counting system 10, 40 can include the particle counter 50 calibrated to detect particles with a size larger than 0.5 microns. Further, the computer system 215 with the driver 260 can be configured to move data related to particle counts to specific memory addresses in the particle counter 50, to retrieve data related to particle counts combined with web page information from the communication layer 125, and to display the retrieved data with the display system 235. Fig. 8 is an exemplary information display 265 generated by the display system 235. The information display 265 displays various information, which may include system information 270, status information 275, and count information 280. The information display 265 is illustrated in the form of a webpage accessed by the computer system 215 though the network 30, for example. Because the communication layer 125 of the particle counter 50 can include web page design information, the display 265 can take the form of the webpage shown in Fig. 8 when the particle counter 50 and computer system 215 are in an ad-hoc topography, as shown in Fig. 2. The system information 270 refers to the specific type of particle counter 50 and network connection. The status information 275 refers to the status of the particle counter 50 as well as the status of specific elements of the particle counter 50, such as the light source 115 and vacuum source 75. The count information 280 refers to data detected by the particle counter 50, such as flow rate and particle counts.
[0041] Fig. 9 is a schematic representation of the status information 275 stored in a memory location of the memory 175. More specifically, the status information 275 is shown in a first memory address 285 and a second memory address 290, each address being a 16-bit memory address. For the computer system 215 to display the status information 275, the driver 260 needs only to retrieve information in memory addresses 285, 290. The computer system 215 matches specific bits of the memory addresses 285, 290 to the status of a corresponding element of the particle counter 50, and displays the status information 275 (e.g., light source being on or off) accordingly. Fig. 10 is a schematic representation of the memory 175 including a number of memory addresses 300 dedicated to different types of counts and information related to the particle counter 50 (e.g., status information). With specific reference to the count information 280, the driver 260 retrieves the count information 280 from specific memory addresses (e.g., memory addresses 12 and 13) in the memory 175 of the particle counter 50. The computer system 215 is operable to display the count information 280 (e.g., the number of particles with particle size larger than 0.5 microns) as a result of retrieving the count from a dedicated memory address in memory 175. Therefore, size information of the particle is not sent or generated by the particle counter 50. The display system 235 can display size information with the count information 280 based on the known calibration of the particle counter 50 and the dedicated address in the memory 175 where the count information 280 was retrieved. Similarly, status information 275 can be retrieved from a specific address in the memory 175 of the particle counter 50. As a result, data transfer between the particle counter 50 and the computer system 215 is improved.
[0042] With specific reference to the operation of the particle counter 50, the particle counter 50 is calibrated to establish, among other parameters, the size of the particles to be detected and the flow rate. As indicated above, the particle counter 50 can be calibrated to detect particles of two particle sizes (e.g., particle size larger than 0.5 microns and particle size larger than 5 microns). The particle counter 50 is also calibrated to have a substantially constant flow rate. For example, the particle counter 50 can be calibrated to generate a flow rate of about 1 ft3/min (about 28.3 It/min). In other constructions, the particle counter 50 can be calibrated to generate different flow rates, such as 25 It/min, 50 It/min, 75 It/min, and 100 It/min. Based on the calibrated flow rate, it is possible to determine the amount of time it takes for the particle counter 50 to sample the complete volume of a clean zone. For analysis purposes, predetermined sample volumes are established such that a particle count can be displayed as a function of a standard unit of volume (e.g., 1 m3 or 1 ft3. Accordingly, for a particle counter 50 calibrated to generate a flow rate of 1 ft3/min, it is determined that the particle counter 50 can sample a sample volume of 1 m3 in about 35.3 minutes, and a sample volume of 1 ft3 in about 1 minute.
[0043] In the illustrated construction, the particle counter 50 is further configured to sample a sample volume in intervals. More specifically, the particle counter 50 is configured to sample a sample volume in sixty intervals. Accordingly, if the sample volume is established to be 1 m3, the particle counter 50 can sample 1/60 m3 in about 35.3/60 minutes. Similarly, if the sample volume is established to be 1 ft3, the particle counter 50 can sample 1/60 ft3 in about one second. Based on the application and/or desired characteristics of the particle counter 50, other constructions can include the particle counter 50 being calibrated to sample full sample volumes with a different number of intervals. Sampling the sample volume using time intervals allows the particle counter 50 to store information related to partial counts in the memory 175. For example, the memory 175 can include dedicated memory addresses (e.g., memory addresses 300) for partial count information, such as the number of particles for one time interval or the total particle count retrievable by the DAS 25 before the full sample volume has been sampled or the particle count for a previously completed sample. In addition, sampling the sample volume using intervals allows the particle counter 50 to include operational features, defined as rolling counts, forced counts, and fault detection/salvaging data.
[0044] Rolling counts
[0045] The rolling counts feature allows the particle counter 50 to determine and store a particle count for the most recent sample volume. More specifically, the rolling counts feature is implemented by the particle counter 50 continuously adding the particle counts of time intervals. As indicated above, once sixty time intervals have elapsed, the particle count of the full sample volume is available at a predetermined memory address 300. As the particle counter 50 continues to sample the clean zone, the particle counter 50 uses the particle count taken during the latest interval and discards the particle count taken from the oldest interval to update the particle count of the full sample volume. Consequently, the particle count saved in the memory address corresponding to the particle count of the full sample volume is the count obtained during the most recent sample volume. In the illustrated construction, memory addresses 300 identified as 0 and 1 in Fig. 10 correspond to the particle count of the full sample volume for particles larger than 0.5 microns. Similarly, memory addresses 300 identified as 2 and 3 in Fig. 10 correspond to the particle count of the full sample volume for particles larger than 5 microns. [0046] Forced Counts
[0047] The forced counts feature allows the DAS 25 to utilize the particle counter 50 to test the operation of the programming logic of the DAS under fault conditions. The forced counts feature also tests an alarm system (not shown) that actuates as a result of a fault condition, or as a result of comparing the particle counts obtained from the particle counter 50 to predetermined threshold values. As shown in Fig. 10, memory addresses 300 defined by numerals 26 through 51 correspond to forced count information saved in the memory 175. More specifically, the driver 260 of the DAS 25 includes instructions to command the particle counter to take information from addresses 300 dedicated to forced count information and copy (also sometimes referred to as move) the information to corresponding memory addresses 300 where actual or detected information is saved during operation of the particle counter 50. The driver 260 then reads the information from the memory 175 as if the DAS 25 is retrieving actual detected information. In one example, if a user tests for actuation of an alarm when the particle count of a sample volume is larger than a predetermined threshold, the driver 260 commands the particle counter to take the count from memory addresses 300 corresponding to forced count information, and copy the information to the memory addresses 300 where the particle count is saved during operation of the particle counter 50, and retrieves the information to the DAS 25. The test is considered successful when the alarm is activated as a result of the DAS 25 receiving and processing the forced count information. As shown in Fig. 10, every memory address 300 that includes forced count information has a corresponding memory address 300 that includes information stored during operation of the particle counter 50.
[0048] Alternatively, an auxiliary computer or controller (e.g., computer 35 of the particle counting system 10 illustrated in Fig. 1 ) other than the DAS may be equipped with a program operable to control the particle counter and communicate with the particle counter over the network. In this scenario, the auxiliary computer sends commands to cause the particle counter to send forced counts and status information to the DAS under test. The DAS programming is tested in this scenario without the necessary test programs being run in the DAS itself.
[0049] Fault Detection/Data Salvaging
[0050] The fault detection feature allows the particle counter 50 to provide accurate, as well as timely count information. More specifically, the particle counter 50 can detect a fault condition and can react to the fault condition such that the particle count information is uncorrupted. The particle counter 50 can detect fault conditions such as malfunction of the light source 115 or air flow interruption, for example. In the case of a fault condition, the memory address corresponding to status information 275, as shown in Fig. 9, are updated. Consequently, the particle counter 50 discards the count information obtained in the interval during which the fault condition occurred. Once the status information 275 indicates the fault condition does not exist, the particle counter 50 updates the total particle count with the counts detected in the interval during which the fault condition is no longer detected. This procedure allows the particle counter 50 to provide count information for a full sample volume without having to discard all the counts corresponding to that sample volume in the situation where a fault condition is detected. For example, if the sample volume is determined to be 1 ft3 and a fault condition was detected during one of the sixty intervals, the particle counter 50 can provide with a particle count of the full sample volume in about 61 seconds (one additional second than the case in which no fault condition is detected). Accordingly, the count detected during one faulty interval is discarded instead of discarding the particle count determined for the whole sample volume.
[0051] Various features and advantages of the invention are set forth in the following claims.

Claims

CLAIMSWhat is claimed is:
1. A method of communicating particle count information from an environmental sensor to a remote data acquisition system, the method comprising creating a flow of fluid from a space through the environmental sensor; detecting particles in the fluid; determining a first particle count having a relation to the number of detected particles in a first time interval; determining a second particle count having a relation to the number of detected particles in a second time interval; determining a total particle count based on the first particle count and the second particle count; and communicating the total particle count from the environmental sensor to the remote data acquisition system, the communicating act including wirelessly communicating the total particle count from the environmental sensor.
2. The method of claim 1 , wherein the environmental sensor includes a vacuum source and creating the flow of fluid comprises creating a vacuum with the vacuum source.
3. The method of claim 1 , wherein detecting particles comprises generating a light beam with a source of light, and detecting a scatter of the light beam as a result of at least one of the particles flowing through the environmental sensor.
4. The method of claim 3, wherein detecting the particles further comprises generating a signal based on the detecting the scatter of the light beam, comparing the signal to a threshold, and determining whether the signal has a relation to the threshold.
5. The method of claim 1 , wherein determining the first particle count includes comparing a characteristic of the detected particles in the first time interval to a value, and increasing the first particle count when the comparison satisfies a relationship.
6. The method of claim 1 , wherein the environmental sensor includes a memory, wherein the method further comprises storing the total count in the memory at an address, wherein determining a first particle count includes updating the total count at the address with the first particle count and updating the total count at the address with the second particle count.
7. The method of claim 1 , further comprising determining a third particle count having a relation to the number of detected particles in a third time interval, and wherein determining the total particle count is further based on the third particle count.
8. The method of claim 7, wherein determining the total particle count includes adding the third particle count to the total particle count, and subtracting the first particle count from the total particle count.
9. The method of claim 1 , wherein determining a total particle count includes determining a count indicative of the number of particles in a sample volume, the sample volume flowing through the environmental sensor during a number of intervals.
10. The method of claim 9, further comprising determining a plurality of particle counts for a plurality of time intervals, respectively, wherein determining a plurality of particle counts includes determining a first particle count and determining a second particle count, and wherein determining a total particle count includes adding to the total particle count the number of particles counted by the environmental sensor during a latest interval of the plurality of time intervals, and subtracting from the total particle count the number of particles counted by the environmental sensor during an earliest interval used in the total particle count.
11. The method of claim 1 , wherein wirelessly communicating the total particle count further comprises combining the total particle count with display information.
12. The method of claim 1 , wherein wirelessly communicating the total particle count information includes sending a signal related to the total particle count to a wireless access point, wherein the wireless access point is connected to the remote data acquisition system via a network.
13. The method of claim 1 , wherein the environmental sensor includes a memory having the total particle count at a memory address, wherein the method further comprises the data acquisition system displaying the total particle count and an indicator corresponding to a characteristic of the particles counted by the environmental sensor based on the memory address where the count was stored in the environmental sensor.
14. A particle counting system comprising: a remote data acquisition system; and an environmental sensor to be placed in a space, the environmental sensor including an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet, a particle detection portion to detect particles in the fluid, a controller connected to the particle detection portion, the controller being configured to determine a plurality of counts of particles having a predetermined characteristic during a plurality of time intervals, respectively, store at least a count of the plurality of counts detected during one interval, and continuously update a total count using a rolling count technique for the plurality of counts, and a communication layer connected to the controller to communicate the count to the remote data acquisition system, the communication layer including an antenna to wirelessly communicate the count.
15. The particle counting system of claim 14, wherein the environmental sensor further includes a vacuum source operable to create the flow of fluid between the inlet and the outlet.
16. The particle counting system of claim 15, wherein the vacuum source is in a space within the environmental sensor and is connected to the controller.
17. The particle counting system of claim 14, wherein the controller includes a memory to store the count detected during one interval at a first memory address and the total count at a second memory address, wherein the controller is further configured to continuously update the first memory address with the count detected during the one interval, and wherein the controller is further configured to continuously update the second memory address with the total count.
18. The particle counting system of claim 14, wherein the total count corresponds to the count of particles in a sample volume, the sample volume flowing through the environmental sensor during a number of intervals.
19. The particle counting system of claim 14, wherein the controller includes a memory having the total count at a memory address, and wherein the controller is configured to store in and update the memory address with the count of particles indicative of the number of particles in a sample volume, the sample volume flowing through the environmental sensor during a number of intervals.
20. The particle counting system of claim 14, wherein the communication layer includes display information, and wherein the communication layer is operable to combine and wirelessly transmit the total count combined with the display information.
21. The particle counting system of claim 20, wherein the controller includes a memory having the total count at a memory address, wherein the remote data acquisition system displays the total count combined with the display information, and wherein the total count combined with the display information includes the total count and an indicator, the indicator corresponding to a characteristic of the particles counted by the environmental sensor based on the memory address where the total count was stored in the environmental sensor.
22. The particle counting system of claim 14, further comprising a wireless access point, the antenna wirelessly communicating the count to the wireless access point, and the wireless access point being configured to communicate the count to the remote data acquisition system via a network.
23. An environmental sensor adapted to be placed in a space, the environmental sensor comprising: an inlet and an outlet such that a flow of fluid moves from the inlet to the outlet; a particle detection portion to detect particles in the fluid; a controller connected to the particle detection portion, the controller being configured to determine a plurality of particle counts, each particle count indicative of the number of particles detected during a corresponding time interval, and determine a total particle count indicative of the particles detected during a number of time intervals; and a wireless communication layer connected to the controller to wirelessly transmit the total particle count and at least one of the plurality of particle counts.
24. The environmental sensor of claim 23, further comprising a vacuum source connected to the controller and operable to create the flow of fluid between the inlet and the outlet.
25. The environmental sensor of claim 24, further comprising a memory to store a current particle count at a first memory address and store the total count at a second memory address, wherein the controller is configured to update the current particle count with a current count of the plurality of particle counts and update the total count based on a rolling count technique with the plurality of particle counts.
26. The environmental sensor of claim 24, wherein the communication layer includes display information, and wherein the communication layer is operable to combine and wirelessly transmit at least one of the plurality of particle counts and the total particle count with the display information.
27. The environmental sensor of claim 26, wherein the controller includes a memory having the total particle count at a memory address, wherein the remote data acquisition system displays the total particle count combined with the display information, and wherein the total particle count combined with the display information includes the total particle count and an indicator, the indicator corresponding to a characteristic of the particles counted by the environmental sensor based on the memory address where the total particle count was stored in the environmental sensor.
PCT/US2008/075100 2007-09-04 2008-09-03 Environmental sensor, particle counting system having an environmental sensor, and methods of operating the same WO2009032833A1 (en)

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US7724150B2 (en) 2010-05-25
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EP2188617A4 (en) 2013-06-05
US20090058668A1 (en) 2009-03-05

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