The present invention refers to a construction of a vacuum-breaking valve to be used in refrigeration appliances in general, such as vertical freezers and refrigerators combined with a freezing compartment, in order to increase the internal pressure inside these appliances and facilitate the reopening of the door.
In refrigeration appliances, such as vertical freezers and refrigerators combined with a freezing compartment which have, inside a cabinet G, at least one compartment, which is hermetically closed with good sealing and thermically insulated and inside which the temperature is lower than the temperature of the surrounding external environment, there is observed an undesired effect which tends to make difficult the immediate reopening of the door of said refrigeration appliance after it has been opened and closed.
This phenomenon is due to the decrease in the pressure of the air mass admitted to the inside of the refrigerated compartment upon the opening of the door, which is inherent to the decrease in temperature of said air mass after the closing of the door, producing an unbalance between the internal pressure, which is lower, and the external pressure, which is higher.
As a result, a strong vacuum is produced inside the cabinet, resulting in a force on the door acting to keep it closed, and consequently making difficult the immediate reopening thereof. At present, it is recommended that the user wait a few minutes before reopening the door.
In order to overcome this problem and allow users to reopen the cabinet door immediately after its closing and with less effort, a device known as vacuum-breaking valve is used, whose function is to promote the equalization of the internal and external pressures. This valve is comprised of a generally cylindrical and rectilinear tubular body, which crosses one of the walls of the cabinet G of the refrigeration appliance, in order to promote a fluid communication between the inside and the outside thereof and to allow, in certain occasions (notably when the internal pressure is lower than the external pressure), the external air to enter the cabinet, thus increasing the internal pressure until it becomes close to the external pressure, represented by the atmospheric pressure. The tubular body is open on its inner side and has on its outer side a sealing system consisting of a movable seal, which is activated by gravity and is movable between a sealing position when in rest, seated on a valve seat and promoting the sealing of the air passage, and a spaced position, when it is maintained suspended and spaced from the valve seat, due to the difference between the external and internal pressures of the cabinet, thus enabling the air flow to the inside thereof.
The tubular body of the valve may be formed of a thermically conductive material, having its outer end arranged in order to define a heat collector to collect thermal radiation coming from a heat source available in the refrigeration appliance and which can be defined by the compressor. This construction allows the tubular body of the valve to be kept warm enough to prevent ice formation therein, due to the condensation of the air that enters when the valve is open, without interfering with the cooling inside the cabinet. This construction is described in the patent application BR PI0001249-1, of the same applicant.
While operating adequately, mainly when the tubular body of the valve is built of a material with good thermal conductivity and is kept slightly heated, the constructive arrangement of the seal suggested in the prior art uses the force of gravity to keep the seal, in the form of a sphere, seated on the valve seat, sealing the fluid communication between the inside and the outside of the cabinet.
Due to the fact that the seal is gravitationally and vertically displaced between a closed position, seated on the valve seat, and an open position, elevated in relation to the valve seat by action of the pressure difference between the inlet and outlet ends of the tubular body, it should be built in order to be light enough to be suspended by the “vacuum” formed inside the cabinet, particularly when the user starts the movement of reopening the door immediately after a closing thereof.
The construction of the usual spherical seal with a light spherical body is relatively costly and complex, besides allowing surface irregularities, such as barbs, to be formed on the spherical body of the seal. The low weight of these seals and the presence of surface irregularities thereon makes little efficient the closing of the valve seat only by the gravitational seating of a very light and small sphere against the sealing seat of the valve. On the other hand, the use of a heavier seal would make impracticable its upward displacement by pressure difference.
Therefore, in these known solutions, the construction of the seal is determined by the weight limitations, which weight should also be determined so that the valve only opens when the user starts a door reopening, in order to avoid that the presence of the pressure difference after each closing of the door causes the opening of the valve and the admission of external humid air inside the cabinet, even without an immediate reopening of the door. The adequate operation of the valve thus depends on the weight of the seal and the precision of its finishing, even if the limit weight is insufficient to promote an efficient sealing in the closed valve condition.
An inadequate sealing of the valve seat allows the occurrence of a flow of external humid air to the inside of the cabinet any time the internal pressure thereof is lower than the external pressure, causing undue ice formation inside the refrigerated compartment.
It is the object of the present invention to provide a vacuum-breaking valve for refrigerated compartments of simple construction and reliable operation, which allows the admission of external air to the inside of the cabinet to which it is installed only when the cabinet door is reopened by the user, immediately after a previous closing, assuring a high degree of sealing when in a closed position.
The objective above is achieved with the provision of a vacuum-breaking valve for a refrigerated compartment closed by a door operated by the user, said valve comprising: a tubular body mounted through one of the walls of the cabinet and having inner and outer ends, which are respectively open to the inside and the outside of the cabinet; a valve seat provided on the outer end of the tubular body and defining a fluid communication between the inside and the outside of the cabinet; and a seal mounted to the tubular body and constantly biased towards a closed position, in which it is seated against said valve seat, blocking said fluid communication and movable towards an open position, spaced from the valve seat, establishing said fluid communication.
According to the invention, the seal comprises a slide, which is axially and slidingly mounted through the valve seat and has a closed end portion and an opposite end portion, which are interconnected by a peripheral lateral contour carrying a surrounding sealing ring, which is seated against the valve seat when the slide is displaced to the closed seal position and which is spaced away from the valve seat when the slide is displaced to the open seal position, the slide being provided with at least one air passage connecting the opposite end portion of the slide with a region of the peripheral lateral contour located between said opposite end portion and the surrounding sealing ring, said air passage being upstream the valve seat when the slide is in the closed seal position and interconnecting the upstream and downstream sides of the valve seat when the slide is in the open seal position.
The invention will be described below, with reference to the appended drawing, in which:
As mentioned above, the present vacuum-breaking valve is of the type comprising a tubular body 10, which is preferably cylindrical and formed of a thermically conductive material, mounted through one of the walls P of a refrigerated cabinet G, closed by a door (not illustrated) to be operated by the user.
The tubular body 1 has an inner end 11 open to the inside of cabinet G and an outer end 12 open to the outside of the cabinet and preferably arranged in order to define a collector for the heat irradiated by the compressor of the refrigeration system or by any other heat source available to the refrigeration appliance.
Inside the outer end 12 of the tubular body 10 a valve seat 15 is incorporated, defining a generally circular opening in order to establish fluid communication between the inside and the outside of cabinet G through the tubular body 10.
In the illustrated embodiment, the valve seat 15 is defined by an annular flange internally incorporated in an elongated portion 13 of the outer end 12 of the tubular body 10, which elongated portion 13 coaxially projects from the outer face of the wall P of cabinet G and may present a contour that is geometrically equal to, similar to or different from the rest of the tubular body 10 and may be constructed as a separate piece.
The vacuum-breaking valve further comprises a seal in the form of a slide 20, which is axially and slidingly mounted through a valve seat 15 so that it may be displaced between a closed position, in which it blocks the valve seat 15 and the fluid communication between the inside and the outside of cabinet G, and an open position, allowing the establishment of said fluid communication through the valve seat 15.
In the illustrative configuration shown in the drawings, the slide 20 takes the form of a an elongated prismatic body having a cross-section similar to and slightly smaller than the cross-section of the valve seat 15, preferably cylindrical, said slide having a closed end portion 21 and an opposite end portion 22, which are interconnected by a peripheral lateral contour 23. In the illustrated construction, the slide 20 is tubular, with the opposite end portion 22 opened and with the peripheral lateral contour 23 provided with at least one window 24, which defines, with the hollow interior and the open opposite end portion 22, an air passage, whose function will be described below.
The slide 20 carries, externally, on its closed end portion 21, a surrounding sealing ring 25 located downstream the valve seat 15 and seated against the latter when the slide 20 is displaced to the closed seal position, blocking the fluid communication between the inside and the outside of cabinet G. The sealing ring 25 is preferably built of an elastomer, in order to facilitate the achievement of a high level of tightness at the interfaces thereof with the slide 20 to which it is mounted and with the valve seat 15 when seated thereon.
The positioning of the valve seat 15 and sealing ring 25 on the respective parts that carry them is made in order that, when the slide 20 is in the closed seal position, with the sealing ring 25 seated against the valve seat 15, the opposite end portion 22 of the slide 20 remains markedly projected outwardly from the tubular body 10.
In order that the slide 20 be constantly biased towards the closed seal position (FIG. 1), a spring 30 is provided around the slide 20 and upstream the sealing ring 25 and has an end seated against a stop 22a incorporated to the opposite end portion 22 of the slide 20 and the other end seated against the outer end 12 of the tubular body 10.
The spring 30 is dimensioned to be compressed, allowing the displacement of the slide 20 towards the tubular body 10, spacing the sealing ring 25 from the valve seat 15 and opening the valve when a reopening of the cabinet door is started immediately after a previous closing.
The spring 30 is dimensioned to yield only upon the sudden increase of the level of “vacuum” or of the sub-pressure present in cabinet G soon after the closing of the door, when the user starts an immediate reopening. If the door is not reopened, the sub-pressure level present soon after a closing of the door is not sufficient to provide, on the slide 20, enough axial force to compress the spring 30.
While only one embodiment of the vacuum-breaking valve has been illustrated, it should be understood that modifications could be made within the same constructive concept disclosed herein. For example, the slide 20 is not necessarily tubular, since each air passage may be formed by a respective longitudinal groove provided on the lateral peripheral contour 23 of the slide 20, upstream the sealing ring 25. The spring 30 may also take different forms, as long as it assures the closing of the valve during the usual operation of cabinet G, allowing its opening only when a reopening of the door is started immediately after being closed.
When the slide 20 is displaced towards the open seal position, each window 24 occupies a position at least partially located downstream the valve seat 15 (FIG. 2), establishing a fluid communication between the inside and the outside of cabinet G through the tubular body 10,valve seat 15 and each air passage 24, 22 provided on the slide 20.
The constructive arrangement described above allows the door to be easily reopened by the user, without the need of additional effort or special handles for increased manual grip, besides allowing an efficient sealing of the valve when in the closed position.
Number | Date | Country | Kind |
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0006442 | Dec 2000 | BR | national |
This application claims priority under 35 U.S.C. §371 based on International Application No. PCT/BR01/00025, filed Mar. 15, 2001, which was published on Jun. 20, 2002, as International Publication No. WO 02/48626, claiming priority to Brazilian Patent Applications Ser. No. PI0006442-4, filed Dec. 11 2001, of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/BR01/00025 | 3/15/2001 | WO | 00 | 9/11/2002 |
Publishing Document | Publishing Date | Country | Kind |
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WO02/48626 | 6/20/2002 | WO | A |
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5836170 | Perkins et al. | Nov 1998 | A |
6176776 | Finkelstein et al. | Jan 2001 | B1 |
6672094 | Carden et al. | Jan 2004 | B1 |
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Number | Date | Country |
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030 046 | Jun 1981 | EP |
547 385 | Nov 1968 | FR |
552 | Aug 1956 | GB |
Number | Date | Country | |
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20030054752 A1 | Mar 2003 | US |