Thermally activated sealing apparatus and method

Information

  • Patent Grant
  • 6807391
  • Patent Number
    6,807,391
  • Date Filed
    Friday, January 31, 2003
    21 years ago
  • Date Issued
    Tuesday, October 19, 2004
    20 years ago
Abstract
Apparatus include a thermally activatable sealing member. The sealing member can be operatively positioned in or near an opening or passage to control the flow of material therethrough by way of selective thermal activation of the sealing member. Methods include providing a thermally activatable sealing member in or near an opening or passage and selectively thermally activating the sealing member to control the flow of material through the opening or passage.
Description




BACKGROUND OF THE INVENTION




Various types of imaging devices are known in the art. Presently, one of the more popular types of imaging devices is that known as the electrophotographic imaging device which is commonly called a “laser printer.” The fundamental operation of the electrophotographic imaging device is well understood in the art and includes providing a photoconductive surface often in the form of a rotatable drum. A laser, or other suitable light source, is selectively pulsed as it is directed at the moving photoconductive surface.




The selective pulsing of the light source as it is directed at the photoconductive surface causes the formation of the desired image on the surface in a latent, electrostatic form. A dry, powdered ink substance, known as “toner,” is then applied to the photoconductive surface to “develop” the image, wherein the toner adheres essentially only to the latent image on the surface. The developed image, in the form of toner, is ultimately transferred from the photoconductive surface to a carrier media, such as a sheet of paper, and is affixed thereto.




Most conventional electrophotographic imaging devices include one or more reservoirs for containing a supply of the powdered toner. Generally, the toner reservoir is in the form of an enclosed hopper-like container having an opening through which the toner is dispensed during operation of the respective imaging device. In many cases, the toner reservoir is incorporated into a “toner cartridge” which contains a given quantity of toner. The toner cartridge is designed to be conveniently removed from the imaging device when the toner is depleted. A like cartridge having a full supply of toner can then be replaced into the imaging device. As can be appreciated, the “replaceable toner cartridge” concept facilitates efficient operation of the imaging device by reducing down time due to toner depletion.




Many conventional toner cartridge configurations employ a temporary sealing device referred to as a “toner dam.” The general purpose of the toner dam is to prevent toner from coming out of a full toner cartridge before the cartridge is installed into the imaging device. For example, without a toner dam, toner could inadvertently come out of a full toner cartridge during handling and shipment thereof, with undesirable results. The toner dam is generally installed during manufacture, or remanufacture, of the toner cartridge. Toner dams are described in greater detail in U.S. Pat. No. 5,799,712 to Kelly et al.




User instructions are usually provided on the toner cartridge packaging, and/or by other convenient means, which explain to the end-user how and why the toner dam should be removed from the cartridge prior to installation of the cartridge into an imaging device. However, as is the case with regard to nearly any product, the installation instructions go unheeded in a significant number of instances. The primary result of failing to remove the toner dam upon installation of the toner cartridge is, of course, that the imaging device will not function properly, if at all.




As can be expected, a secondary result of failing to remove the toner dam is that the end-user becomes frustrated due to the failure of the imaging device to function properly. This, in turn, often results in the end-user calling the manufacturer of the device, and/or the sales agent, to report an apparent malfunction of the imaging device. The manufacturer, and/or the sales agent, thus oftentimes incurs unnecessary expenses in connection with resolving the issue of the alleged “malfunctioning” device.




Furthermore, as is discussed in U.S. Pat. No. 5,799,712, empty toner cartridges are often recycled by refilling them with toner at specially equipped facilities. However, the reinsertion of a toner dam into a previously used toner cartridge can be a relatively significant undertaking, accounting for a correspondingly significant proportion of the cost of recycling a given toner cartridge.




Additionally, problems are associated with the transport or movement of imaging devices with toner cartridges installed. More specifically, the transport or movement of an imaging device having a toner cartridge installed therein with the toner dam removed therefrom can generally result in damage to the device due to toner coming out of the cartridge. Therefore, it can be desirable to provide a toner cartridge having a sealing device which can alleviate the problems associated with the conventional toner dam as explained above.




More generally, various sealing devices are known in the art. For example, U.S. Pat. No. 3,984,942 to Schroth discloses an inflatable seal which can be employed to seal vehicle doors and the like. Such seals generally include a pliable inflatable member that can be filled with pressurized fluid, thereby causing expansion of the inflatable member. The expansion of the inflatable member, in turn, creates a sealing effect when the inflatable member is disposed between a door and a perimeterical doorframe, for example.




Similar inflatable members have been employed in various production devices and the like as is disclosed by U.S. Pat. No. 4,354,452 to Patterson. More specifically, Patterson discloses an edge dam which includes an inflatable member, wherein the edge dam is employed in an applicator for applying a coating liquid to a moving web of paper carried on a backing roll. While such inflatable members are known to function satisfactorily, such inflatable members are not generally well suited for providing a seal in place of the toner dam in toner cartridges.




This is because such inflatable members generally require a volume of working fluid such as air or hydraulic oil, as well as a pressurization/conveyance system for pressurizing the working fluid and conveying the fluid to and from the inflatable member. Such systems are thus generally too complex and too large for the application at hand.




SUMMARY OF THE INVENTION




In accordance with one embodiment of the present invention, an apparatus includes an object that defines an opening through which a material can selectively flow. The apparatus also includes a thermally activated sealing member that is configured to selectively change shape by way of heat activation, wherein sealing member can move between a first position in which the opening is substantially blocked so as to prevent material flow therethrough, and a second position in which the opening is substantially unblocked so as to enable material flow therethrough.











DESCRIPTION OF THE DRAWINGS





FIG. 1

is an isometric view in which a thermally activated sealing apparatus is depicted in accordance with one embodiment of the present invention, wherein the sealing member is shown in a closed position.





FIG. 2

is another isometric view of the thermally activated sealing member depicted in

FIG. 1

, wherein the sealing member is shown in an open position.





FIG. 3

is a side elevation schematic view in which an imaging device and a toner cartridge are depicted in accordance with another embodiment of the present invention.





FIG. 4

is a side elevation schematic detail view of the imaging device and toner cartridge depicted in FIG.


3


.





FIG. 5

is another side elevation schematic detail view of the imaging device and toner cartridge depicted in FIG.


3


.





FIG. 6

is another side elevation schematic detail view of the imaging device and toner cartridge depicted in

FIG. 3

, wherein an alternative configuration of the sealing member is shown.





FIG. 7

is another side elevation schematic detail view of the imaging device and toner cartridge depicted in

FIG. 3

, wherein another alternative configuration of the sealing member is shown.





FIG. 8

is a side elevation sectional view in which a toner cartridge is depicted in accordance with another embodiment of the present invention.





FIG. 9

is a side elevation sectional detail view of the toner cartridge depicted in

FIG. 8

, wherein the sealing member is shown in a closed position.





FIG. 10

is another side elevation detail view of the toner cartridge depicted in

FIG. 8

, wherein the sealing member is shown in an open position.





FIG. 11

is a side elevation detail view showing an alternative configuration of the sealing member of the toner cartridge depicted in FIG.


8


.





FIG. 12

is a side elevation detail view showing another alternative configuration of the sealing member of the toner cartridge depicted in FIG.


8


.





FIG. 13

is a side elevation sectional view in which a toner cartridge is depicted in accordance with still another embodiment of the present invention.





FIG. 14

is a side elevation sectional detail view of the toner cartridge depicted in

FIG. 13

, wherein the sealing member is shown in a closed position.





FIG. 15

is another side elevation detail view of the toner cartridge depicted in

FIG. 13

, wherein the sealing member is shown in an open position.











DETAILED DESCRIPTION OF THE INVENTION




Various embodiments in accordance with the present invention include sealing apparatus and methods and more specifically, thermally activated sealing apparatus and methods. The sealing apparatus and methods disclosed herein can be beneficially applicable in the field of electrophotographic imaging, although it is understood that other fields of application are contemplated as well. The various embodiments of the invention described herein generally include a thermally activated sealing member that can be caused to selectively and alternately block and unblock an opening by way of thermal activation of the sealing member, wherein heat energy is applied thereto.




With reference to

FIG. 1

, an isometric view is shown in which a sealing apparatus


100


is depicted in accordance with one embodiment of the invention. The apparatus


100


includes a frame


110


, and a thermally activated sealing member


120


. The terms “thermally activated,” and “thermally activatable,” as used herein, mean capable of being activated, or operated, by way of heat energy absorption, as is explained in greater detail below. More specifically, a “thermally activated” device, as well as a “thermally activatable device,” can be selectively operated, or activated, by way of selective supply, or exposure, of a given quantity of heat energy to the device.




As shown, the sealing member


120


can be operatively supported by the frame


110


. However, it is understood that the sealing member


120


need not be supported by the frame


110


. As is further seen, the frame


110


defines an opening therethrough. Thus, the sealing member


120


can be operatively supported by the frame


110


, or alternatively, can be supported by an element other than the frame


110


, whereby the orientation of the sealing member relative to the frame enables the sealing member to function to selectively block and unblock the opening


20


as is described below.




The sealing member


120


includes a flexible member


123


. The flexible member


123


is configured to change shape when heated. More specifically, the flexible member


123


is configured to change shape when heated, wherein the change in shape of the flexible member results in the blocking, or unblocking, of the opening


20


. The flexible member


123


is fabricated from a material, or materials, which change shape in response to a temperature change thereof. It is understood that the phrase “change shape” includes “change in dimension.”




For example, the flexible member


123


can be fabricated from a shape memory alloy (“SMA”). Shape memory alloys are known. One of the most common shape memory alloys is known by the name, “nitinol.” Shape memory alloys are known to change shape when heated. Furthermore, shape memory alloys are known to return to their original shape when cooled. That is, a given element that is fabricated from a shape memory alloy can have a first shape at, for example, ambient temperature. When the given element is heated to, for example, 150° F. above ambient temperature, the given element will have a second shape. If the given element is allowed to cool back to ambient temperature, the given element again attains the first shape.




As another example, the flexible member


123


can include both a hyper-expansive element


121


, as well as a hypo-expansive element


122


. The term “hyper-expansive element” as used herein is defined as any element with which a relatively high coefficient of thermal expansion is associated. Likewise, the term “hypo-expansive element” as used herein is defined as any element with which a relatively low coefficient of thermal expansion is associated.




That is, the coefficient of thermal expansion associated with the hyper-expansive element is high relative to that of the hypo-expansive element, while the coefficient of thermal expansion associated with the hypo-expansive element is low relative to that of the hyper-expansive element. It is understood that the term “coefficient of thermal expansion” refers to the rate of dimensional expansion experienced by a given object per unit temperature increase thereof.




Both the hyper-expansive element


121


and the hypo-expansive element


122


can be in substantially sheet form as shown. That is, the hyper-expansive element


121


and/or the hypo-expansive element


122


can be substantially thin and relatively flat. Furthermore, the hyper-expansive element


121


and the hypo-expansive element


122


can be in substantially sheet form and bonded to one another in a bi-layered manner. By way of example only, the hyper-expansive element


121


and the hypo-expansive element


122


can be in the form of a “bimetallic” element.




Thus, the hyper-expansive element


121


and the hypo-expansive element


122


can be connected, or affixed, to one another by bonding or other such means, so as to give the appearance of a single sheet of material that includes two layers, wherein the hyper-expansive element is one of the layers, and the hypo-expansive element is the other of the layers. The hyper-expansive element


121


and the hypo-expansive element


122


can be oriented in substantially parallel, juxtaposed registration relative to one another as shown.




As is further shown, the sealing member


120


can include an extension member


125


. The extension member


125


can be connected to, or alternatively supported by, the flexible member


123


. The extension member


125


can be employed to effectively enlarge the reach, or coverage, of the sealing member


120


. That is, for a given size of the flexible member


123


, the inclusion of an extension member


125


can enable the sealing member


120


to controllably cover a larger opening


20


. The extension member


125


can be configured so as to be substantially unaffected by heat. That is, the extension member


125


can be fabricated from a material that does not substantially change shape as a function of the temperature thereof.




The apparatus


100


can also include a heat source


130


. The heat source


130


is configured to produce heat energy that can be absorbed by the flexible member


123


. The heat source


130


can be supported on the apparatus


100


as shown, although it is understood that the heat source need not contact any other element or component of the apparatus. That is, the heat source


130


can be supported in contact with the sealing member


120


. Alternatively, the heat source


130


can be supported in contact with the flexible member


123


. However, it is understood that the heat source


130


can also be supported in a manner wherein contact of the sealing member


120


therewith does not occur.




As further shown in

FIG. 1

, the apparatus


100


can include a power source


140


that is configured to supply power to the heat source


130


. The apparatus


100


can also include a switch


150


that is configured to control the flow of power from the power source


140


to the heat source


130


. For example, the power source


140


can be in the form of an electrical power supply configured to supply electrical power to the heat source


130


, in which the heat source can be an electrically-powered heater or the like. Likewise, the switch


150


can be an electrical switch that is configured to control the flow of electrical current between the power source


140


and the heat source


130


.




The apparatus


100


can also include at least one power conduit


10


such as an electrical power cable or the like that is configured to transmit power from the power source


140


to the heat source


130


. The switch


150


, as shown, can be connected between the power source


140


and the heat source


150


by way of the power conduits


10


. Thus, by way of example only, when the switch


150


is included in the apparatus


100


, the switch can be switched between an “off” position, in which no operational power flows from the power source


140


to the heat source


130


, and an “on” position, in which operational power flows from the power source to the heat source. In this manner, the production of heat energy by the heat source


130


can be controlled by manipulation of the switch


140


.




It is noted that, with reference to

FIG. 1

, the switch


150


is shown in the “off” setting, wherein no power flows from the power source


140


to the heat source


130


. That is, the heat source


130


is depicted as not producing heat energy. Therefore, the heat source


130


is depicted as not providing heat energy to the sealing member


120


. In other words, the flexible member


123


is depicted as being in a non-thermally activated state, wherein no significant amount of heat energy has been absorbed thereby. This point becomes more relevant in later discussion.




Turning now to

FIG. 2

, another isometric view is shown in which the apparatus


100


is depicted in an alternate operational mode. That is, with reference to

FIG. 2

, the switch


150


is shown in the “on” setting, wherein power flows from the power source


140


to the heat source


130


. Therefore, the heat source


130


is depicted as producing heat energy, a significant quantity of which is shown to have been absorbed by the flexible member


123


. Thus, the sealing member


120


is shown to be in an open position, thereby allowing material flow MF through the opening


20


. In other words, still referring to

FIG. 2

, the heat source


130


is shown to be producing heat energy that is absorbed by the flexible member


123


, thereby thermally activating the flexible member.




Thus, in contrast with the operational mode of the apparatus


100


that is shown in FIG.


1


and explained above with respect thereto, the operational mode of the apparatus as illustrated in

FIG. 2

shows that the flexible member


123


can absorb a given quantity of heat energy, whereby the flexible member can become thermally activated. The heat energy that is produced by the heat source


130


, and which is absorbed by the flexible member


123


, can cause the flexible member to change shape.




For example, if the flexible member


123


includes the hypo-expansive element


121


and the hypo-expansive element


122


, then the disparity between the dimensional expansion rates of the hyper-expansive element


121


and the hypo-expansive element


122


, respectively, can cause the flexible member to change shape when heat energy is absorbed thereby, as can be seen with reference to both

FIGS. 1 and 2

. It is understood that a change in shape of the flexible member


123


in response to heat absorption thereby can also occur in an alternative case, wherein the flexible member is fabricated from a shape memory alloy, for example, as is mentioned above.




The shape change of the flexible member


123


as the result of thermal activation thereof, can cause the sealing member


120


to move from a closed position to an open position, or from an open position to a closed position, depending on the specific configuration and orientation of the sealing member. That is, it is understood that the sealing member


120


can be configured in an alternative configuration (not illustrated herein) in accordance with which the thermal activation of the sealing member results in the blocking of the opening


20


by the sealing member, and wherein the opening is not blocked by the sealing member when the sealing member is not thermally activated.




Thus, the specific function of the sealing member


120


in response to thermal activation thereof can be determined by the specific shape of the sealing member when not thermally activated, as well as by the orientation of the sealing member with respect to the opening


20


. As is illustrated in

FIGS. 1 and 2

by way of example only, the sealing member


120


is configured and oriented in a manner whereby thermal activation thereof can cause the sealing member to unblock the opening


20


.




As mentioned above, such unblocking of the opening


20


by the thermal activation of the sealing member


120


can allow material flow MF through the opening. As can be appreciated, the sealing member


120


can be employed to selectively control material flow MF through the opening


20


, wherein, by way of example only, non-thermal activation of the sealing member can cause the opening to be blocked, and wherein thermal activation of the sealing member can cause the opening to be unblocked.




In other words, the sealing member


120


, as is specifically depicted in

FIGS. 1 and 2

by way of example only, is configured to substantially block the opening


20


at relatively low temperatures of the sealing member, and is further configured to unblock the opening at relatively high temperatures of the sealing member. Alternatively, the relative position and/or shape of the flexible member


123


can be reversed so that the flexible member is bent, or curved, at relatively low temperatures, and is substantially straight, or flat at relatively high temperatures.




As is discussed above, the change in shape of the flexible member


123


, which can be caused by thermal activation thereof, can be employed to selectively block and unblock an opening such as the opening


20


. That is, as shown, the switch


150


can be selectively switched between an “on” position and an “off” position, wherein power is supplied and not supplied, respectively, to the heat source


140


.




Thus, when power is not supplied to the heat source


130


, the flexible member


123


is not thermally activated. When the flexible member


123


is not thermally activated, the sealing member


120


can, as is depicted by way of example only in

FIG. 1

, act to seal, or at least substantially block, the opening


20


, thus preventing material flow MF therethrough. However, as is mentioned above, in an alternative configuration and/or orientation which is not depicted but which is explained above, the sealing member


120


, when the flexible member


123


is not thermally activated, can be in an open position whereby the opening


20


is not blocked.




When power is supplied to the heat source


130


, the heat source can produce heat energy that can be absorbed by the sealing member


120


, and more specifically, by the flexible member


123


. The flexible member


123


, upon absorbing a given quantity of heat energy, can become thermally activated, resulting in a change of shape thereof. The thermal activation of the flexible member


123


can result in the opening


20


becoming unblocked as is depicted in FIG.


2


. An alternative configuration and/or orientation of the sealing member


120


can result in the opening


20


becoming blocked when the flexible member


123


becomes thermally activated, as explained above.




Furthermore, it is understood that the switch


150


which controls the flow of power to the heat source


130


can be replaced with a coupling such as is described below in greater detail and which is shown in another figure as noted below. That is, rather than employing a switch, such as the switch


150


to control the flow of power to the heat source


130


, a coupling (not shown) can be employed, wherein the power to the heat source can be selectively connected and/or disconnected in order to control the flow of power to the heat source.




As is explained above with reference to

FIGS. 1 and 2

, it is also understood that in accordance with one possible configuration of the sealing member


120


, the extension


125


can be omitted, wherein the flexible member


123


is configured to selectively cover, or block, substantially the entire opening


20


. In accordance with an alternative configuration of the sealing member


120


, the sealing member can include both a flexible member


123


and an extension member


125


that is operatively connected to the flexible member, wherein the flexible member and the extension member together act to cover, or block, substantially the entire opening


20


as is specifically depicted by way of example only in

FIGS. 1 and 2

.




In any case, the sealing member


120


can be configured to selectively move, by way of thermal activation, between a closed position and an open position, wherein when in the closed position, the sealing member substantially covers, or blocks, the opening


20


so as to substantially prevent material flow MF through the opening


20


, and wherein when in the open position, the sealing member uncovers, or unblocks, at least a portion of the opening so as to allow material flow MF therethrough.




It is noted that, as illustrated in

FIGS. 1 and 2

, the sealing member


120


has a blade form. That is, the term “blade form” means a substantially flat, planar form that is affixed to a supportive member substantially at only one edge, whereby the sealing member can bend so as to substantially unblock the opening


20


. As explained further below, a sealing member in accordance with at least one alternative embodiment of the invention can have an alternative form and/or configuration.




Turning now to

FIG. 3

, a side elevation schematic view is shown in which a toner cartridge


200


and an electrophotographic imaging device


300


are depicted in accordance with another embodiment of the invention. That is,

FIG. 3

presents one example of a specific application in which the thermally activated sealing member


120


can be employed. For example, the thermally activated sealing member


120


, which is discussed above, can be included in a toner cartridge


200


that is configured to contain a quantity of toner (not shown).




The toner cartridge


200


can be configured to dispense the toner onto an optical photoconductor


14


that can be operatively supported within the electrophotographic imaging device


300


, or “laser printer.” Electrophotographic imaging devices, and their operation, are well known in the art and need not be discussed in detail herein. In general, the electrophotographic imaging device


300


together with the toner cartridge


200


, can function to produce an image from the toner and to affix the image onto the media, or image carrier, M.




The electrophotographic imaging device


300


can include a number of components that are typically included in conventional electrophotographic imaging devices. For example, in addition to the optical photoconductor


14


, the imaging device


300


can include a laser


18


, or other suitable light source, as well as a charging device


17


, and a cleaning device


16


. The imaging device


300


can also include such components as a transfer roller


15


, as well as various other rollers


11


and


13


that can be employed to move the toner to the optical photoconductor


14


.




By way of example only, the rollers


11


and


13


can be developing rollers that can be employed to “develop” the image on the optical photoconductor


14


. The imaging device


300


can also include a paddle device


9


that is configured to facilitate movement of the toner onto the rollers


11


and


13


. The imaging device


300


also can include a housing


7


. The housing


7


can define a cavity


8


in which the other components are operatively supported, as shown.




Likewise, the toner cartridge


200


can include a body


2


that defines a toner reservoir


19


in which the toner can be stored. The toner cartridge


200


can also include various other components configured to facilitate movement and control of the toner. For example, a stirring device


3


can be included in the toner cartridge


200


, wherein the stirring device is operatively supported within the reservoir


19


. Additionally, a roller


4


can also be included in the toner cartridge


200


, wherein the roller is also operatively supported within the reservoir


19


.




As is depicted, the toner cartridge


200


can be configured to be removably supported by the imaging apparatus


300


, wherein, when the toner cartridge is supported on the imaging apparatus, toner can be drawn from the toner cartridge and transferred into the cavity


8


in facilitation of the production of images in the manner briefly discussed above.




That is, the toner cartridge


200


can be configured to be removable from, and replaceable onto, the imaging apparatus


300


. In this manner, once the toner is depleted from the toner cartridge


200


, it can be removed from the imaging device


300


, and a like toner cartridge that contains a supply of toner can be replaced onto the imaging device. Such a removable and/or replaceable nature of toner cartridges is generally known and practiced in the art.




Moving now to

FIG. 4

, a side elevation schematic detail view is shown in which particular portions of the toner cartridge


200


and the imaging device


300


are depicted with greater clarity. That is,

FIG. 4

is intended to be a “close-up” view of the sealing member


120


and associated elements of the toner cartridge


200


and imaging apparatus


300


that are depicted in FIG.


3


. As is seen in

FIG. 4

, the toner cartridge


200


can include the thermally activated sealing member


120


that is described above in detail with respect to the apparatus


100


.




It is noted that, as depicted in

FIG. 4

, the toner cartridge


200


is not supported by the imaging device


300


. That is, the toner cartridge


200


is shown to be separated from the imaging device


300


. However, as is indicated by the directional arrows in

FIG. 4

, the toner cartridge


200


can be moved toward the imaging apparatus


300


so as to be supported thereby as explained further below. It is further noted that the sealing member


120


, as shown in

FIG. 2

, can have a blade form as described above with respect to the apparatus


100


.




As is seen, the body


2


defines an opening


42


therethrough. The sealing member


120


can be supported on the body


2


proximate the opening


42


in the manner depicted, wherein the sealing member can substantially block the opening when not thermally activated. That is, the sealing member


120


can be configured to control toner flow TF through the opening


42


. More specifically, as depicted in

FIG. 4

, the sealing member


120


is not thermally activated, and is blocking the toner flow TF through the opening


42


. In other words, as shown in

FIG. 4

, the sealing member


120


is in a closed position.




As is also seen, the housing


7


of the imaging device


300


defines a toner port


47


therethrough. The opening


42


and the port


47


can be located relative to the body


2


and housing


7


, respectively, such that when the toner cartridge


200


is operatively supported by the imaging device


300


, the opening and the port are substantially aligned in juxtaposed registration with one another for passage of toner therethrough from the toner cartridge to the imaging device. In this manner, the flow of toner from the toner reservoir


19


into the cavity


8


is facilitated.




As is further seen in

FIG. 4

, the imaging device


300


can include a heat source


130


. The heat source


130


is described in greater detail above with respect to the apparatus


100


. It is understood that the heat source


130


can have any of a number of possible shapes and/or configurations and/or orientations not specifically illustrated herein. It is further understood that the heat source


130


need not be specifically configured to produce heat energy. That is, the heat source


130


can be a device that produces heat energy as a by-product, or as a secondary function.




The heat source


130


can supported by the housing


7


proximate the port


47


, as shown. More specifically, the heat source


130


can be located in a position relative to the port


47


such that, when the toner cartridge


200


is operatively supported by the imaging device


300


, the heat source operatively contacts the sealing member


120


in facilitation of the transfer of heat energy thereto. However, as is discussed below, the heat source


130


need not come into direct contact with the sealing member


120


.




The operation of the sealing member


120


is readily seen with reference to

FIG. 5

which is another side elevation schematic detail view, or “close-up” in which the toner cartridge


200


and the imaging device


300


are depicted. As is further seen, the toner cartridge


200


is depicted as being operatively supported on the imaging device


300


. When the toner cartridge


200


is thus supported by the imaging device


300


, the heat source


130


can come into contact, or at least into operative proximity, with the sealing member


120


.




The heat source


130


can come into direct contact with the sealing member


120


as a result of placement of the toner cartridge


200


into an operatively supported position on the imaging device


300


, as shown. However, it is understood that the heat source


130


need not come into direct contact with the sealing member


120


when the toner cartridge


200


is operatively supported by the imaging device


300


.




Instead, when the toner cartridge


200


is operatively supported by the imaging device


300


, the heat source


130


can at least come into sufficient proximity with the sealing member


120


, whereby an operative quantity of heat energy is transferable from the heat source to the sealing member. In other words, the heat source


130


need only be close enough to the sealing member


120


to transfer a given quantity of heat thereto, wherein the given quantity of heat is sufficient to enable thermal activation, and thus operation, of the sealing member.




In any case, heat energy supplied by the heat source


130


can be absorbed by the sealing member


120


, whereby the sealing member is thermally activated. Such thermal activation of the sealing member


120


can result in a shape change thereof as is explained above. The change in shape of the sealing member


120


as the result of the thermal activation thereof can cause the sealing member to unblock the opening


42


. When the sealing member


120


unblocks the opening


42


, the toner flow TF is free to proceed from the reservoir


19


, and through the opening, and then through the port


47


, and into the cavity


8


, as depicted. Thus, as depicted in

FIG. 5

, the sealing member


120


is shown in an open position as the result of thermal activation thereof.




As can be appreciated from a study of

FIGS. 4 and 5

, the sealing member


120


can be employed in conjunction with the toner cartridge


200


and the imaging device


300


to control the flow of toner from the toner reservoir


19


. More specifically, by way of example only, the sealing member


120


can thus be employed in the manner of an automatic toner dam which remains closed to block flow of toner from the reservoir


19


when the toner cartridge


200


is not installed in the imaging device


300


, and when the sealing member is not thermally activated. However, the sealing member


120


can be caused to open automatically to allow toner flow TF from the reservoir


19


and into the cavity


8


when the toner cartridge


200


is installed on the imaging device


300


and when the sealing member becomes thermally activated.




Moreover, it is seen that the sealing member


120


can be configured to automatically close when the toner cartridge


200


is removed from the imaging device


300


, or when the toner cartridge remains supported on the imaging device when the supply of electrical power thereto is terminated. That is, for example, when the imaging device


300


is unplugged from an electrical power source, such as from a wall socket (not shown), the heat source


130


will cease the production of heat energy, and the sealing member


120


will therefore cease to be thermally activated, resulting in a change of shape so as to move to the closed position, thus blocking the flow of toner from the reservoir


19


and through the opening


42


.




Alternatively, when the toner cartridge


200


is removed from the imaging device


300


, the sealing member


120


is removed from proximity or contact with the heat source


130


, wherein the sealing member ceases to be thermally activated. This, in turn, results in the movement of the sealing member


120


from an open position to a closed position, thus blocking the toner flow TF through the opening


42


. In this manner, toner leakage can be substantially prevented when the toner cartridge


200


is removed from the imaging device


300


and during movement and/or transport of the imaging device with toner cartridge installed thereon.




Turning now to

FIG. 6

, a side elevation schematic detail view is shown in which the imaging device


300


, along with an alternative configuration of the toner cartridge


200


are depicted. That is, the toner cartridge


200


and the imaging device


300


that are depicted in

FIG. 6

can be substantially identical to the toner cartridge and imaging device that are depicted in

FIGS. 4 and 5

, with the exception of a coating


125


that can be applied to the sealing member


120


.




More specifically, the coating


125


can substantially surround the sealing member


120


as shown. The coating


125


can be an elastomeric coating that is substantially flexible and relatively durable. The coating


125


can serve as a thermal insulator with respect to the sealing member


120


. As a thermal insulator, the coating


125


can retard the loss of heat energy from the sealing member, for example, and can also prevent the transfer of heat energy to the toner and/or to objects such as the body


2


of the toner cartridge


200


.




Moving now to

FIG. 7

, another side elevation schematic detail view is shown in which a further alternative configuration of the toner cartridge


200


, as well as an alternative configuration of the imaging device


300


are shown. For example, in the alternative configuration thus shown, the heat source


130


can be operatively supported by the toner cartridge


200


. Furthermore, the heat source


130


can have a substantially sheet, or strip, form as is depicted. In such a case, the heat source


130


in sheet or strip form can be bonded to at least a portion of the sealing member


120


.




Moreover, in such a case wherein the heat source


130


has a sheet or strip form, the heat source can be oriented in parallel, juxtaposed aligned registration with the sealing member


120


in facilitation of heat transfer thereto from the heat source. As is further seen, when the heat source


130


is operatively supported by the toner cartridge


200


, the toner cartridge can include an electrical contact


127


that is operatively supported by the toner cartridge. The electrical contact


127


can be electrically linked with the heat source


130


, whereby operational electrical power can be supplied to the heat source by way of the electrical contact.




Similarly, the imaging device


300


can include an electrical receptacle


327


operatively supported by the imaging device. As is seen, the electrical receptacle


327


can be configured to electrically link with the electrical contact


127


when the toner cartridge


200


is placed into an operatively supported position on the imaging device


300


, whereby electrical energy can be supplied to the heat source


130


from the imaging device by way of the electrical receptacle and the electrical contact. In this manner, the sealing member


120


can open only when provided with electrical power from the imaging device


300


, which can occur only when the toner cartridge


200


is placed in an operatively supported position on the imaging device which, in turn, can result in the electrical connection of the electrical receptacle


327


to the electrical contact


127


.




Thus, the electrical receptacle


327


and the electrical contact


127


can be positioned relative to the imaging device


300


and to the toner cartridge


200


, respectively, so as to be in substantially connectively aligned registration with one another when the toner cartridge is placed in an operatively supported position on the imaging device. That is, the electrical contact


127


and the electrical receptacle


327


can be positioned so that when the toner cartridge


200


is installed on the imaging device


300


, then the electrical contact and the electrical receptacle can automatically link for electrical power transmission therebetween.




Although not specifically depicted in the interest of clarity, the sealing member


120


that is shown in

FIG. 7

can also include the coating


125


shown in FIG.


6


and described above. The coating


125


can be applied so as to substantially surround both the heat source


130


and the sealing member


120


in the form depicted in FIG.


7


. This can prevent direct contact of the heat source


130


with the toner contained in the toner reservoir


19


of the toner cartridge


200


.




Turning to

FIG. 8

, a side elevation sectional view is shown in which a toner cartridge


400


is depicted in accordance with another embodiment of the invention. The toner cartridge


400


includes a body


31


that defines a toner reservoir


32


. The toner reservoir


32


is configured to contain a quantity of toner (not shown). A stirring device


34


can also be included in the toner cartridge


400


, wherein the stirring device is operatively disposed within the reservoir


32


. The body


31


can also define an antechamber


33


. A waste hopper


46


can also be defined by the body


31


as is shown.




The toner cartridge


400


can be configured to operatively support the optical photoconductor


14


as well as one or more of the rollers


13


and


15


, which are each described above with respect to the apparatus


100


and


300


. The optical photoconductor


14


can be located within the antechamber


33


, as can the rollers


13


and


15


. The toner cartridge


400


can also include the cleaning device


16


which can be employed to remove waster toner and other debris from the optical photoconductor


14


. Such waste toner and debris removed from the optical photoconductor


14


can be collected in the waste hopper


46


.




The toner cartridge


400


can also include a sealing member


420


that is explained in greater detail below. The sealing member


420


can be operatively supported by the toner cartridge


200


, and more specifically, can be operatively supported by the body


31


. As is further seen from a study of

FIG. 8

, the body


31


defines an opening


35


through which toner can be moved from the reservoir


32


to the optical photoconductor


14


. In other words, toner can pass through the opening


35


on its way from the reservoir


32


to the antechamber


33


. As is further seen, the sealing member


420


can be operatively disposed at, or proximate to, the opening


35


to thereby facilitate toner flow control through the opening in the general manner of the sealing member


120


as is explained above with respect to the toner cartridge


200


.




Still referring to

FIG. 8

, the toner cartridge


400


is configured to be operatively supported on an imaging device (not shown) wherein the reservoir


32


can contain a toner (not shown) that can be processed by the imaging device so as to produce an image from the toner, wherein the image can be affixed to a sheet of media (not shown) or the like. It is understood that the specific configuration of the toner cartridge


400


, as well as that of the toner cartridge


200


discussed above, are set forth herein as illustrative examples only.




That is, a toner cartridge in accordance with various embodiments of the present invention is not intended to be limited to specific configurations as depicted in the accompanying figures and as described herein. More specifically, it is understood that a toner cartridge in accordance with any of the embodiments of the invention which are either contemplated or specifically illustrated herein need not include all of the components specifically mentioned, and need not have the exact, or similar, configurations of the components and/or elements as specifically mentioned.




Moving now to

FIG. 9

, a side elevation schematic detail view is shown in which the sealing member


420


is depicted along with a portion of the body


31


of the toner cartridge


400


. That is,

FIG. 9

is intended to be a “close-up” of the opening


35


and the sealing member


420


, as well as related elements, which are depicted in FIG.


8


. As is seen, the sealing member


420


can be operatively disposed at, or proximate to, the opening


35


through which toner can move from the toner reservoir


32


to the optical photoconductor


14


(shown in FIG.


8


).




The sealing member


420


can also be operatively supported by the body


31


as is shown. As is further shown in

FIG. 9

, the sealing member


420


can be in the shape of a cylindrical, overlapping roll. That is, in its non-thermally activated state, the sealing member


420


can be formed into a substantially cylindrical roll that overlaps itself slightly as shown.




As is seen, one distinction that can be made between the sealing member


420


and the sealing member


120


(shown in

FIGS. 1 and 2

) is that the former is rolled into a substantially cylindrical overlapping form, while the latter has a substantially planar blade form. However, it is understood that the specific shapes of the sealing members


120


and


420


as depicted and described herein are intended to provide illustrative examples only, and are not intended to limit the shape of a sealing member.




As is further seen, the sealing member


420


can be sized so as to be capable of substantially blocking toner flow TF out of the reservoir


32


by way of the opening


35


. That is, depending on the specific configuration of the sealing member


420


, the sealing member


420


can be in contact with the body


31


when activated, or when non-activated, depending upon the specific configuration of the sealing member, so as to substantially block toner flow TF from the reservoir


32


to the antechamber


33


.




The toner cartridge


400


can also include a heat source


130


. The heat source


130


is described above with respect to the toner cartridge


200


and the imaging device


300


. Still referring to

FIG. 9

, the heat source


130


can be operatively supported by the body


31


, and can also be supported so as to be in contact with, or at least in operative proximity to, the sealing member


420


.




With reference now to

FIG. 10

, another side elevation schematic detail view, or close-up, is shown in which the sealing member


420


along with a portion of the body


31


is depicted. As is seen, the view shown in

FIG. 10

is substantially identical to that shown in FIG.


9


. However, as depicted in

FIG. 10

, sealing member


420


is depicted in the open position. For example, the heat source


130


can produce a given amount of heat energy which can be absorbed by the sealing member


420


, which can thus cause thermal activation thereof, resulting in the movement of the sealing member from a closed position to an open position.




More specifically, heat energy produced by the heat source


130


can be absorbed by the sealing member


420


, which can cause the sealing member to change shape. By way of example, only, such a change in shape of the sealing member


420


can be the curling thereof into a tighter roll. That is, as depicted in

FIG. 9

, the sealing member


420


cap have a substantially cylindrical form having an initial diameter. However, as depicted in

FIG. 10

, the sealing member


420


can change shape, thus attaining a diameter that is less than the initial diameter.




As is seen, this change of shape of the sealing member


420


, which can be caused by the absorption of heat energy thereby from the heat source


130


, can allow toner flow TF to occur between the reservoir


32


and the antechamber


33


. That is, the thermal activation of the sealing member


420


can cause the sealing member to change shape, thus unblocking the opening


35


and allowing toner flow TF therethrough. In this manner, the sealing member


420


can be employed to control the toner flow TF out of the reservoir


32


.




As can be appreciated, the amount of heat energy produced by the heat source


130


can be controlled in the manner discussed above with respect to the apparatus


100


, wherein a switch (not shown) or the like can be employed to control the amount of electrical energy (or other form of energy) that is provided to the heat source. The power to the heat source


130


can alternatively be controlled in the manner described above with respect to apparatus


200


and


300


and shown in FIG.


7


.




The control of the amount of heat produced by the heat source


130


in turn can enable control of the activation of the sealing member


420


. That is, when heat energy is produced by the heat source


130


the sealing member


420


can become thermally activated by absorption of the heat energy, thus allowing toner flow TF. On the other hand, when the heat source


130


does not produce a significant quantity of heat energy, the sealing member


420


can cease to become thermally activated, or can become thermally de-activated, thus blocking the toner flow TF.




Turning now to

FIG. 11

, a side elevation detail view is shown in which an alternative location of the heat source


130


is depicted. That is, more specifically, the heat source


130


can be located so as to be substantially surrounded by the sealing member


420


. As is seen, the heat source


130


can be both surrounded by the sealing member


420


and in contact therewith. However, it is understood that, as explained above, the heat source


130


need not be in direct contact with the sealing member


420


. The heat source


130


can, however, be close enough to the sealing member


420


so that heat energy can be transferred thereto from the heat source for thermal activation of the sealing member.




Also, as is depicted in

FIG. 11

, the sealing member


420


can include the hyper-expansive element


121


and the hypo-expansive element


122


which are explained above with respect to the sealing member


120


. That is, the sealing member


420


can include the hyper-expansive element


121


and the hypo-expansive element


122


that are in a roll form as shown. However, it is understood that the sealing member


420


need not include the hyper-expansive element


121


, or the hypo-expansive element


122


. Rather, at a minimum, the sealing member


420


is required only to be configured to change shape in response to the absorption of heat energy.




Alternatively, the sealing member


420


can include a flexible member (not shown) that does not include either the hyper-expansive element


121


or the hypo-expansive element


122


. That is, the sealing member


420


can include a flexible member, such as the flexible member


123


described above with respect to

FIGS. 1 and 2

, which can be fabricated from a material that changes shape in response to a change in temperature. For example, rather than including the hyper-expansive element


121


and the hypo-expansive element


122


, the sealing member


420


can include a flexible member (not shown) that is fabricated from a shape memory alloy, for example.




Moving to

FIG. 12

, another side elevation detail view is shown in which a further alternative configuration of the sealing member


420


is depicted. As is shown, the toner cartridge


400


can include a sheath


425


that substantially surrounds the sealing member


420


. The sheath


425


can be fabricated from an elastomeric material that is both resiliently flexible and durable. The sheath


425


can serve to thermally insulate the sealing member


420


so as to prevent heat loss therefrom to the surrounding environment. The sheath


425


can also serve to prevent debris and material such as toner and the like from coming into contact with the sealing member


420


.




With reference now to

FIG. 13

, a side elevation sectional view is shown in which a toner cartridge


500


is depicted in accordance with yet another embodiment of the invention. It is seen that the toner cartridge


500


can be substantially similar to the toner cartridge


400


which is described above with reference to

FIGS. 8

,


9


, and


10


. However, the toner cartridge


500


depicted in

FIG. 13

differs from the toner cartridge


400


in that the sealing member


120


is depicted as having a blade form, whereas the sealing member


420


of the toner cartridge


400


is depicted as having a substantially roll form. The sealing member


120


is explained in detail above with respect to

FIGS. 1 and 2

.




Thus, as is seen by a study of

FIG. 13

, the sealing member


120


can have a substantially blade form, and can be employed to control toner flow from one internal chamber of a toner cartridge


500


to another internal chamber thereof. For example, turning now to

FIG. 14

, a side elevation schematic detail view is shown in which the sealing member


120


is depicted along with a portion of the body


31


of the toner cartridge


500


. That is,

FIG. 14

is a “close-up” of the opening


35


and the sealing member


120


, as well as related elements, of the toner cartridge


500


which is depicted in FIG.


13


.




As is seen with reference to

FIG. 14

, toner flow TF from one chamber, such as the toner reservoir


32


, to another chamber, such as the antechamber


33


, can be selectively controlled by way of the sealing member


120


which can have a substantially blade form. The sealing member


120


can be operatively supported by the body


31


proximate the opening


35


defined therethrough. A heat source


130


can also be operatively supported by the body


31


. The heat source


130


can be proximate the sealing member


120


, and more specifically, the heat source


130


can be in contact with the sealing member.




As is depicted in

FIG. 14

, the sealing member


120


is shown in a closed position, wherein the opening


35


is substantially blocked by the sealing member, and wherein toner flow TF through the opening is substantially prevented. With reference now to

FIG. 15

, another detail side elevation schematic detail view is shown in which the sealing member


120


along with a portion of the body


31


is depicted. As is seen, the view shown in

FIG. 15

is substantially identical to that shown in FIG.


14


. However, as depicted in

FIG. 15

, the heat source


130


has produced a given amount of heat energy which has been absorbed by the sealing member


120


, thus causing thermal activation thereof.




In other words, as is seen with reference to

FIGS. 14 and 15

, the heat source


130


can produce heat energy which can be absorbed by the sealing member


120


. Upon absorbing a given quantity of heat energy, the sealing member


120


can become thermally activated, whereby the sealing member changes shape and moves from a closed position to an open position. When in the open position, the sealing member


120


substantially unblocks the opening


35


, thereby enabling toner flow TF through the opening. That is, thermal activation of the sealing member


120


can enable toner flow TF from one chamber (such as the toner reservoir


32


) to another chamber (such as the antechamber


33


) of the toner cartridge


500


.




In accordance with a further embodiment of the invention, a method of controlling material flow through an opening includes providing a sealing member such as the sealing member


120


or the sealing member


420


which are discussed above. In accordance with the method, the sealing member is operatively disposed proximate the opening. When the sealing member is not thermally activated, the sealing member substantially blocks the opening, thus substantially preventing material flow therethrough. The method further includes providing heat energy to the sealing member, thereby thermally activating the sealing member, thereby causing the sealing member to unblock the opening.




While the above invention has been described in language more or less specific as to structural and methodical features, it is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.



Claims
  • 1. A toner cartridge for containing a quantity of toner to be dispensed onto an optical photoconductor, the cartridge comprising a thermally activatable sealing member that is configured to control toner flow by selectively moving between a closed position and an open position in response to the absorption of heat energy.
  • 2. The toner cartridge of claim 1, wherein the sealing member comprises:a flexible member that is configured to absorb a quantity of heat energy, thereby causing the flexible member to change shape; and, an extension member operatively supported by the flexible member.
  • 3. The toner cartridge of claim 2, wherein the sealing member comprises:a hyper-expansive element; and, a hypo-expansive element connected thereto.
  • 4. The toner cartridge of claim 3, wherein the hyper-expansive element and the hypo-expansive element are each substantially in sheet form and are oriented in parallel, juxtaposed relation to one another.
  • 5. The toner cartridge of claim 4, wherein the hyper-expansive element and the hypo-expansive element are bonded to one another in a bi-layered manner.
  • 6. The toner cartridge of claim 5, and further comprising a body which defines a toner reservoir and an opening through which the toner passes when dispensed onto the optical photoconductor, and wherein the sealing member is supported on the body and operatively disposed at the opening in facilitation of toner flow control therethrough.
  • 7. The toner cartridge of claim 6, and wherein:an antechamber is defined by the body; the opening connects the toner reservoir to the antechamber; and, the sealing member is operatively disposed at the opening in facilitation of toner flow control between the reservoir and the antechamber.
  • 8. The toner cartridge of claim 7, and wherein the optical photoconductor is operatively supported by the toner cartridge and within the antechamber.
  • 9. An apparatus to selectively block and unblock an opening, the apparatus comprising:a frame defining the opening; and, a thermally activatable sealing member that is configured to: have a first shape corresponding to a first temperature of the sealing member; and, have a second shape corresponding to a second temperature of the sealing member, wherein: at the first temperature, the sealing member substantially blocks the opening; and; at the second temperature, the sealing member substantially unblocks the opening.
  • 10. The apparatus of claim 9, and wherein the sealing member comprises:a hyper-expansive element substantially in sheet form; and, a hypo-expansive element substantially in sheet form and bonded to the hyper-expansive element in a bi-layered manner, wherein the hyper-expansive element and the hypo-expansive element are oriented in substantially juxtaposed registration relative to one another.
  • 11. The apparatus of claim 9, and wherein the sealing member comprises a flexible member that is fabricated from a material comprising a shape memory alloy.
  • 12. The apparatus of claim 9, and wherein the sealing member comprises:a flexible member that is configured to change shape in response to the absorption thereby of heat energy; and, an extension element connected to the flexible member.
  • 13. The apparatus of claim 9, and further comprising a heat source operatively supported by the apparatus and configured to selectively supply heat energy to the sealing member, thereby causing the sealing member to operate.
  • 14. The apparatus of claim 13, and wherein the heat source is in contact with the sealing member.
  • 15. The apparatus of claim 14, and wherein the heat source is substantially in strip form.
  • 16. The apparatus of claim 13, and further comprising a power source configured to selectively supply power to the heat source.
  • 17. The apparatus of claim 16, and further comprising a switch configured to control the flow of power from the power supply to the heat source.
  • 18. The apparatus of claim 9, and wherein the sealing member has a blade form.
  • 19. The apparatus of claim 18, and further comprising an elastomeric coating that substantially surrounds the sealing member.
  • 20. The apparatus of claim 9, and wherein the sealing member is in the shape of a cylindrical, overlapping roll form.
  • 21. The apparatus of claim 20, and further comprising an elastomeric sheath that substantially surrounds the sealing member.
  • 22. The apparatus of claim 20, and further comprising a heat source configured to supply heat energy to be absorbed by the sealing member, thereby causing the sealing member to operate, wherein the heat source is substantially surrounded by the sealing member.
  • 23. A toner cartridge for containing a quantity of toner to be dispensed onto an optical photoconductor, the cartridge comprising:a body which defines a substantially enclosed toner reservoir, wherein an opening is defined through the body, through which the toner passes when dispensed onto the optical photoconductor; a thermally activatable sealing member supported by the body, wherein the sealing member is configured to substantially block the opening at a relatively low temperature of the sealing member, and that is further configured to unblock the opening at a relatively high temperature of the sealing member, the sealing member comprising: a hyper-expansive element substantially in sheet form; and, a hypo-expansive element substantially in sheet form and bonded to the hyper-expansive element in a bi-layered manner, wherein the hyper-expansive element and the hypo-expansive element are oriented in substantially juxtaposed registration relative to one another.
  • 24. The toner cartridge of claim 23, and further comprising a heat source supported on the cartridge, wherein the heat source is configured to supply heat energy to the hyper-expansive element.
  • 25. The toner cartridge of claim 24, and wherein the heat source has a substantially sheet form and is bonded to the hyper-expansive element, the toner cartridge further comprising an electrical contact supported on the cartridge and electrically linked with the heat source, whereby external operational electrical power can be supplied to the heat source by way of the electrical contact.
  • 26. The imaging device of claim 23, comprising an electrical contact supported by the body and electrically linked to the heat source, wherein operational electrical energy can be supplied to the heat source from the imaging device by way of the electrical contact.
  • 27. A toner cartridge comprising:a body; and, a thermally activatable sealing member supported by the body, wherein: the toner cartridge is configured to be operatively supported by an imaging device; and, the sealing member is configured to operate by selectively moving between a closed position and an open position in response to the absorption thereby of energy supplied by the imaging device.
  • 28. The imaging device of claim 27, and further comprising a heat source supported by the body and configured to supply energy in the form of heat to the sealing member, and wherein the energy supplied by the imaging device is in the form of electrical power.
  • 29. The imaging device of claim 28, wherein:the body defines a toner reservoir and an antechamber; and, the sealing member is configured to selectively control toner from the toner reservoir to the antechamber.
  • 30. A method of controlling material flow through an opening, comprising:providing a thermally activatable sealing member proximate the opening, wherein when not thermally activated the sealing member substantially blocks the opening, thus substantially preventing material flow therethrough; and providing heat to the sealing member, whereby the sealing member is thermally activated, thus causing the sealing member to substantially unblock the opening.
  • 31. A sealing apparatus, comprising:a frame defining an opening; a thermally activated sealing member configured to operate in response to absorption thereby of heat energy, wherein the sealing member operates by moving between a closed position in which the opening is substantially blocked by the sealing member, and an open position in which the opening is substantially unblocked by the sealing member; and, a means for providing heat energy to the sealing member.
US Referenced Citations (10)
Number Name Date Kind
3596800 Iketani Aug 1971 A
3984942 Schroth Oct 1976 A
4354452 Patterson Oct 1982 A
4432609 Dueker et al. Feb 1984 A
4905344 McCabe Mar 1990 A
4937628 Cipolla et al. Jun 1990 A
5133487 Russi Jul 1992 A
5799712 Kelly et al. Sep 1998 A
5839027 Sahay et al. Nov 1998 A
6546216 Mizoguchi et al. Apr 2003 B2