JPH10511764A - Atmosphere controlled storage chamber - Google Patents

Abstract

(I) a means for generating air (34) such as a cooled and pressurized air conditioner located in or proximate to the chamber; and (ii) in cooperation with the generating means; One or more air supply ducts (28) for circulating the cooled and pressurized air throughout the chamber (22), wherein each or each of the supply ducts (28) is substantially a chamber (22). ) Having an unrestricted airflow passage extending the length thereof and having an inwardly tapering lateral dimension or width increasing inwardly toward its end remote from the generating means (34). One or more air supply ducts (28); (iii) cooperating with the or each supply duct (28) and extending substantially the length of the or each supply duct (28). Air outlet means (51, 61, (Iv) one or more elongated hollow storage members (23) having one or more closely located heat sources (27), the or each storage member. Function as return ducts (29) for returning hot air to the generating means (34), or each return duct (29) extends substantially the length of the chamber (22). And characterized by having an unrestricted airflow passage having a lateral dimension or width that tapers outwardly and gradually increases over its length toward an end (59) remote from the generating means (34). And (v) cooperating with the or each return duct (29) and extending substantially the length of the or each return duct (29). Air inlet means (52, 54) A controlled atmosphere storage chamber (22).

Description

Description: FIELD OF THE INVENTION The present invention relates to an atmosphere-controlled storage chamber that represents the interior of a building comprising one or more rooms, the interior of a vehicle, the interior of a container, or a movable container. Storage chamber. BACKGROUND ART Conventionally, means for generating cooled pressurized air, such as an air conditioner, one or more supply ducts for circulating cooled pressurized air throughout the chamber in fluid communication with the air conditioner, A plurality of hollow storage shelves with elongated lighting in the form of fluorescent tubes mounted on the underside of each shelf and for returning hot spent air located inside the hollow of each storage shelf to the air conditioner A conventional controlled atmosphere storage chamber consisting of a return duct is described in Australian Patent No. 628067. A humidifying duct was also provided to circulate the humidified air throughout the chamber. The storage chamber of Australian Patent No. 628067 is such that the flow of air in the chamber controls the heat release in the vicinity of each lighting strip in the surrounding envelope which occupies only a small part of the total volume of the chamber, It is characterized in that the supply duct and the return duct are separated. The controlled storage chamber of Australian Patent No. 628067 was made as an experimental prototype and controlled such as (i) heat, (ii) air pressure, (iii) air velocity, and (iv) humidity. It has been found to be unsatisfactory in some respects, as there is no reasonable control to provide adequate monitoring of the variables contributing to the created atmosphere. Without such monitoring, "hot spots" or locally hot pockets will form in the chamber, which are very harmful to perishable items placed on storage shelves, product damage, plant damage. Lack of germination, lack of proper maintenance of cell and bacterial cultures, and introduction of pathogens into the disinfecting atmosphere. Thus, it is believed that the controlled atmosphere storage room of Australian Patent No. 628067 is neither energy efficient nor cost effective, and is particularly well-suited for conducting research in biological applications involving DNA recombination techniques or tissue culture experiments. It did not provide an atmosphere that was accurately monitored for the above variables that were essential to DISCLOSURE OF THE INVENTION Accordingly, it is an object of the present invention to provide a controlled atmosphere storage chamber that alleviates the aforementioned disadvantages of the prior art. Thus, the controlled atmosphere storage chamber of the present invention comprises: (i) means for producing cooled and pressurized air located within or adjacent to the chamber; and (ii) in cooperation with the producing means, One or more air supply ducts for circulating cooled and pressurized air throughout the chamber, the or each supply duct extending substantially the length of the chamber and spaced from the generating means One or more air supply ducts having an unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length toward its defined end; and (iii) the or Air outlet means cooperating with each supply duct and extending substantially the length of the or each supply duct; and (iv) having one or more heat sources located in close proximity One or more elongated hollow storage members, wherein the or each storage member has an interior therein functioning as a return duct for returning heated air to the generating means; Defines an unrestricted airflow passage extending substantially the length of the chamber and having an outwardly tapered lateral dimension or width increasing outwardly toward its end remote from the generating means. And (v) air inlet means cooperating with the or each return duct and extending substantially the length of the or each return duct. including. In connection with the storage chamber described in Australian Patent No. 628067, in practice, a localized area with little or no air circulation, as well as a large, variable and unwanted unstable array of hot spots generated Was also found, which differed in location in one plane and at different levels or heights throughout the chamber. This means that it is very difficult, if not possible, to provide a chamber with a uniform air distribution throughout the chamber. Also, in connection with the rectangular air supply duct utilized in the storage chamber described in Australian Patent No. 628067, it has been found that such a rectangular air supply duct is mainly due to the aforementioned disadvantages of the prior art. Was. In work leading to the development of the present invention, it was determined that the initial air velocity as air entered the supply duct was greater than the final air velocity at one end of the rectangular duct spaced from the air conditioner. Thus, in accordance with the present invention, such a configuration has been tapered or otherwise tapered to compensate for the reduction in air velocity from the air supply inlet to its outlet. This also means that the return duct must be of opposite taper to the supply duct to achieve the desired purpose of uniform air distribution throughout the chamber. The air supply duct and the air return duct may have a substantially conical shape or a shallow cubic shape that is substantially trapezoidal in a plane. However, the air duct has been modified in accordance with the present invention to provide an unrestricted air passage having a tapered shape, with the taper increasing inward from one end proximate to the generating means with respect to the supply duct to one end remote from the generating means. For the air supply duct extending towards the rear and providing an opposite taper with respect to the return duct, which may be substantially conical or shallow cubic which is substantially rectangular in plane as described in Australian Patent No. 628067. It is important to emphasize. This may be a plurality of lengths or heights that are progressively shortened or reduced along the opposing surfaces of each of the rectangular air ducts to an end spaced from the vicinity of the air generating means in the case of the air supply duct. This is achieved by providing a baffle and, in the case of an air return duct, the length or height of the baffle is gradually reduced from an end close to the air generating means to an end remote from it. At this point, the baffles are properly oriented perpendicular to the longitudinal axis of each air duct. However, this is not essential, and their effective height (ie, their distance from their free ends to the adjacent side walls of the air duct, measured perpendicular to the plane of the side walls) tapers as described above. Alternatively, the baffle may extend at an acute angle with respect to the longitudinal axis to provide for grading. The air generating means used in the present invention may be of any suitable type, and thus corresponds to the air conditioner described in Australian Patent No. 628067, and in one form includes a centralized refrigeration coil. It may be a distributed air conditioning system using an air conditioning system or an evaporative cooling system. The air outlet means of the air supply duct may comprise elongate slots extending substantially over the length of the storage chamber or alternatively one or more rows of outlet apertures. In a similar manner, the air inlet means of the and each air return duct may comprise an elongated slot or alternatively one or more rows of inlet apertures extending substantially the length of the storage chamber. Is also good. The elongated storage member utilized in the controlled storage chamber of the present invention comprises an elongated box of any suitable shape which forms a storage shelf for perishables stored on the top of the elongated box. You may do it. The heat source utilized in the present invention may be of any suitable type, but preferably comprises electric lighting in the form of a row of lighting gloves, more suitably strip lighting in the form of fluorescent tubes. Such strip lighting is mounted below each storage chamber. Humidification means for the storage chamber consisting of a water supply or water source heated by a suitable heating means may also be provided. An air supply duct may be utilized for the supply of humidified air to the chamber. The storage chamber may be provided with at least one thermal sensor or probe suitably located near the storage shelf. More specifically, a plurality of thermal sensors are utilized, and such thermal sensors are located proximate to each shelf in the storage chamber. Also, at least one pneumatic sensor located in the air supply duct or the air return duct may be provided. However, more suitably, a plurality of pneumatic sensors are provided located in the air supply duct and the air return duct. Also, at least one air velocity sensor may be provided located in the air supply duct or air return duct. However, more suitably, there are a plurality of air velocity sensors located in the air supply duct and the air return duct. If necessary, one or more humidity sensors may be provided. The presence of the above-mentioned sensors is preferably used for precise monitoring of variables contributing to the controlled atmosphere achieved in the storage chamber. Suitably, each sensor is electrically connected to one or more microprocessors that connect to a computer at a location remote from the storage chamber. This means that predetermined values of temperature, pressure, speed and humidity are given to the storage chamber and the function of the microprocessor is to maintain the predetermined values. When changes to these values are requested, such changes must be made using a computer. Reference is made below to preferred embodiments of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a movable container including a controlled atmosphere storage chamber according to the present invention as viewed from one end of the container; FIG. 2 is a view opposite to the direction shown in FIG. FIG. 3 is a perspective view of the movable container shown in FIG. 1 as viewed; FIG. 3 is a cross-sectional view through the storage chamber of FIG. 1 showing the arrangement of air supply and air return ducts in fluid communication with the air conditioner; FIG. 5 is a plan view of the storage chamber of FIG. 1 showing an arrangement of an air supply duct and an air return duct; FIG. 5 is a perspective view of an air return duct used in the storage chamber of FIG. 1; FIG. 7 is a view of an air return duct in an alternative form to that shown in FIG. 5 or 6; FIG. 8 is a view of an air supply duct in an alternative form to that shown in FIG. 4; FIG. 9 shows a storage channel. FIG. 10 is a block diagram of an electric circuit used for operation of electric components in FIG. 10; FIG. 10 is a cutaway perspective view showing circulation of an air flow through a storage chamber of the present invention; FIG. 11 is an air supply duct shown in FIG. FIG. DETAILED DESCRIPTION In the view of FIG. 1, the container 10 is movable, the legs 11 are adjustable in height, and the retractable crane hook set is withdrawn if necessary so that the container 10 can be lifted by the crane when desired. A roof with a solid 12, an optional extended or retracted step 13, a door 14 with a window 14A, a ramp 15, a key 16, a pair of side walls 17, a front wall 18, and an air vent. 19 inclusive. Also shown is a lug 21 for the attachment of a cable or chain (not shown) when the container 10 is moved by a truck. The container 10 includes a plurality of storage members 23 including a shelf surface 24 used to support an object such as a plant 25, a support column 26 for supporting the storage members 23, a long and thin illumination 27, It includes a controlled atmosphere storage chamber having an air supply duct 28 in the shape of a shallow cubic as described, and an air return duct 29. A heat sensor 30 is provided similarly to the passage 31. A forklift support member 32 is also shown. In FIG. 2, container 10 includes a grid 32A adjacent to an inlet grid 33 of an air conditioner 34 located in rear chamber 9 of container 10. Chamber 9 also houses a microprocessor control module 36, an outlet duct 37 for discharging spent air from air conditioner 34 through air vent 20, and associated electrical components for operation of storage chamber 22. It has a control cabinet 38, a humidifier 39, a power input or switch board 40, a cabinet 41 containing a manual override switch for the lighting strip 27, a microprocessor 44 with a keyboard 44 and a visual display 45. A communication cable 42 for connecting to the computer 43; The switch board 40 may connect the storage chamber 22 to an external power supply. The thermal sensor 30 is electrically connected to a microprocessor, as well as an air pressure sensor, an air speed sensor, and a humidity sensor, as described below. Communication cable 42 may be replaced by a wireless link if desired. 3-4, the flow of air in the air supply duct 28 and the return of air through the air return duct 29 are indicated by arrows. Also shown are a heating element 46, an air supply vent 47 and a return air vent 48, a pressure sensor 49 and an air velocity sensor 50. In FIG. 4, an outlet slot 51 for the air supply duct 28 extending substantially the length of the storage chamber 22 is shown. Also shown is a humidity sensor 51A. In FIGS. 5-6, a diagram of the return duct 29 and the associated air passage 47 is shown. As indicated by the arrows, air flows through inlet slots 52 arranged in a pair of rows 53 as shown. If necessary, a longer length inlet slot 54 is also used. The air exits through the outlet aperture 54A and returns to the air conditioner 48 through the ventilation passage 48 as shown and as indicated by the arrow. The air return duct also includes a booster 55, electrical connectors 56, and wires 57. Increasingly inwardly tapering toward the ventilation passage 48 best shown in FIG. 6 or alternatively increasingly outwardly tapering at the air conditioner 34 or at an end 59 remote from the ventilation passage 48. A baffle 58 labeled is also shown. In FIG. 7, a modified return duct 29A is shown that includes an unrestricted airflow passage 60 that tapers inwardly toward an end 59 remote from the air passage 47 or air conditioner 34. The air flow passage 60 includes a tapered side wall 29B and is supported by a rectangular housing 29C. In FIG. 8, a modified air supply duct 28A having a plurality of baffles 60A, each having an increasing length or height, toward an end 61A remote from the air conditioner 34 is shown. The switch board 40 includes a power input, a power isolation switch, and a fuse, as best shown in FIG. 9, and the control cabinet 38 transmits control signals from a microprocessor in connection with the operation and control of lighting variables. Power supply to the lighting control module 64 to determine, the elongated lighting 27, the air conditioner 34 and the humidifier 39 and other electrically operated components used in connection with the storage chamber 22 shown in FIGS. A contactor 65, which is a microprocessor controlled switch for turning on and controlling the air conditioner, a transformer 66 for supplying DC current to components such as some components of the air conditioner 34, and a fuse 67 for the transformer 66. . The microprocessor control module 36 includes a microprocessor capable of computing, monitoring, controlling, and passing all variables or parameters to maintain predetermined values. The control module also includes a relay that passes control signals computed and interpreted by the microprocessor to the associated electrical components. A manual override switch in cabinet 41 provides manual control of lighting variables if lighting control module 64 fails. The phantom lines in FIG. 9 indicate electrical connections, including multiple electrical connections as required. The overall circulation of air in the storage chamber 22 is shown in FIG. 10 with only a portion of the return duct 29 for convenience, and the cross section of the supply duct 28 attached to the roof 19 at 73 is shown in FIG. It is shown. Insulating layers 71 and 72 are also shown. In operation of the storage chamber of the present invention, sensors 30, 49, 50 and 51, together with appropriate computer software, adjust and update air supply variables. The air supply duct is suitably shaped so that the volume of supply air is about 10% of the total return air duct volume. The supply volume is based on the maximum heat load per level of the storage member 23 and is updated and managed by online optimal set point control software that changes both air speed and pressure. Another improvement over the prior art is the placement of all wiring and associated heat producing components other than the fluorescent tubes in the return duct 29. In the prior art, the heat-generating components associated with such wiring were located outside the return duct and adjacent to the elongated lighting below each storage member 23. The addition of sensors 30, 49, 50 and 51 that continuously monitor the return air from all levels of the storage member 23 will substantially remove any heat generated by the lighting device from the source. As a result, only a small amount of the cooling load required to control the desired environment for the actual surface inside the storage chamber is required. Also, the in-line installation of the series of heating elements 46 facilitates obtaining variable settings for the lowest temperature that will be set in the storage chamber, such as the lowest daily temperature. Installation of the heating element also automatically responds to the heat loss that will be experienced in the storage chamber. Thus, for example, if the temperature falls below the required minimum during a night cycle, the heating element is automatically activated to achieve the desired minimum temperature. The storage chamber of the present invention incorporates within its computer software a set of alarm variables programmed to be updated at regular intervals within the device to visually and abnormally deviate from configuration. Report by telephone link. The alarm system also signals sensor and mechanical failures and automatically manages and closes components to prevent damage to expensive products. The storage chamber of the present invention is programmed to continuously and automatically update variables that manage the use of all energy demands cost effectively and efficiently. When a new mechanism setting is required, e.g., a temperature change to a tropical environment is required, the relevant computer software closes the control system parts and achieves the new setting calculated to use the absolute minimum energy. Avoid permanent damage at the same time. The overall operating efficiency of the supply and return ducts of the overall operating system of the control system described above is controlled by an online program that manages all environmental requirements to create and maintain the required equilibrium environment within a finite level. Is updated from all the sensors of. For example, all environmental variables such as lighting level, temperature, heat load, air pressure, air volume, air conditioning and humidity level are controlled by a control system for recomputation and reprocessing purposes to achieve the relevant variable environment. It is precisely balanced and maintained utilizing an online computerized system that optimally manages the real-time data generated within it. Thus, the present invention provides: (i) plant growth at defined temperatures, relative humidity and gaseous levels; (ii) seed disinfection; (iii) mushroom growth; (iv) fruits, flowers, vegetables and nuts and the like. (V) cheese ripening and other controlled fermentation environments; (vi) food processing applications; (vii) porcelain, pottery and earthenware preservation; (viii) fish and other aquatic animal growth (Ix) disinfection room for biological control and microbial growth; (x) climate control environment for animal experiments; (xi) special pathogen-free room for controlled DNA recombination technology experiments and gene technology; xii) a defined pathogen-free operating room; cost-effective to provide a controlled atmosphere storage chamber with equipment that provides optimality of all variables for storage of various products, including: This is a functionally efficient means. From the above description, the term "chamber" is to be construed as including within its scope several rooms or a single room inside a building or one or more rooms inside a vehicle. The present invention, within its scope, is a method of operating a controlled atmosphere storage chamber, comprising: (i) producing cooled and pressurized air; (ii) obtaining an equilibrium distribution within said chamber. Flowing the cooled and pressurized air through the chamber, wherein the cooled and pressurized air gradually increases over its length toward an end remote from the location where the cooled and pressurized air is generated Through an initial supply passage having an inwardly tapered transverse dimension or width; and (iii) cooperating one or more of the cooled and pressurized air from the initial supply passage. Flowing downstream toward a storage member disposed within the controlled atmosphere storage chamber having the above heat source, whereby the cooled and pressurized air flows around the one or more heat sources. And (iv) dissipates the consumed and heated air to produce the cooled and pressurized air having a taper opposite the initial supply flow path. The method includes the steps of passing through the return flow path toward a certain position.

[Procedure for Amendment] Patent Law Article 184-8 [Date of Submission] June 27, 1996 [Content of Amendment] Lack of proper maintenance of bacterial culture and introduction of pathogenic bacteria into the disinfecting atmosphere. Thus, it is believed that the controlled atmosphere storage room of Australian Patent No. 628067 is neither energy efficient nor cost effective, and is particularly well-suited for conducting research in biological applications involving DNA recombination techniques or tissue culture experiments. It did not provide an atmosphere that was accurately monitored for the above variables that were essential to DISCLOSURE OF THE INVENTION Accordingly, it is an object of the present invention to provide a controlled atmosphere storage chamber that alleviates the aforementioned disadvantages of the prior art. Thus, the controlled atmosphere storage chamber of the present invention comprises: (i) means for producing cooled and pressurized air located within or adjacent to the chamber; and (ii) in cooperation with the producing means, One or more air supply ducts for circulating cooled and pressurized air throughout the chamber, the or each supply duct extending substantially the length of the chamber and spaced from the generating means One or more air supply ducts having an unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length toward its defined end; and (iii) the or Air outlet means cooperating with each supply duct and extending substantially the length of the or each supply duct; and (iv) having one or more heat sources located in close proximity One or more elongated hollow storage members, wherein the or each storage member has an interior therein functioning as a return duct for returning heated air to the generating means; Defines an unrestricted airflow passage extending substantially the length of the chamber and having an inwardly tapered lateral dimension or width increasing inwardly toward its end remote from the generating means. And (v) air inlet means cooperating with the or each return duct and extending substantially the length of the or each return duct. including. In connection with the storage chamber described in Australian Patent No. 628067, in practice, a localized area with little or no air circulation, as well as a large, variable and unwanted unstable array of hot spots generated Was also found, which differed in location in one plane and at different levels or heights throughout the chamber. This means that it is very difficult, if not possible, to provide a chamber with a uniform air distribution throughout the chamber. Also, in connection with the rectangular air supply duct utilized in the storage chamber described in Australian Patent No. 628067, it has been found that such a rectangular air supply duct is mainly due to the aforementioned disadvantages of the prior art. Was. In work leading to the development of the present invention, it was determined that the initial air velocity as air entered the supply duct was greater than the final air velocity at one end of the rectangular duct spaced from the air conditioner. Thus, in accordance with the present invention, such a configuration has been tapered or otherwise tapered to compensate for the reduction in air velocity from the air supply inlet to its outlet. This also means that to achieve the desired purpose of a uniform air distribution throughout the chamber, the return duct must have an opposite taper to the supply duct, and a similar taper It is to be understood that both the duct and the return duct have lateral dimensions that taper inwardly toward the end remote from the generating means. The air supply duct and the air return duct may have a substantially conical shape or a shallow cubic shape that is substantially trapezoidal in a plane. However, the air duct has been modified in accordance with the present invention to provide an unrestricted air passage having a tapered shape, with the taper increasing inward from one end proximate to the generating means with respect to the supply duct to one end remote from the generating means. For the air supply duct, which extends toward the return duct and has a similar taper with respect to the return duct, which can be substantially conical or shallow cubic, which is substantially rectangular in plane as described in Australian Patent No. 628067. It is important to emphasize. This involves providing a plurality of baffles having increasing lengths or heights along each opposing surface of the rectangular air duct to an end spaced from the vicinity of the air generating means in the case of an air supply duct, and providing a plurality of baffles for the air return duct. In some cases, the length or height of the baffle is achieved by gradually increasing from an end proximate to the air generating means to an end spaced away. At this point, the baffles are properly oriented perpendicular to the longitudinal axis of each air duct. However, this is not essential, and their effective height (ie, their distance from their free ends to the adjacent side walls of the air duct, measured perpendicular to the plane of the side walls) increases gradually as described above. To provide this, the baffle may extend at an acute angle to the longitudinal axis. The air generating means used in the present invention may be of any suitable type, and thus corresponds to the air conditioner described in Australian Patent No. 628067, and in one form includes a centralized refrigeration coil. It may be a distributed air conditioning system using an air conditioning system or an evaporative cooling system. The air outlet means of the air supply duct may comprise elongate slots extending substantially over the length of the storage chamber or alternatively one or more rows of outlet apertures. In a similar manner, the air inlet means of the and each air return duct may comprise an elongated slot or alternatively one or more rows of inlet apertures extending substantially the length of the storage chamber. Is also good. The elongated storage member utilized in the controlled storage chamber of the present invention comprises an elongated box of any suitable shape which forms a storage shelf for perishables stored on the top of the elongated box. You may do it. Sensor 49 and air speed sensor 50 are also shown. In FIG. 4, an outlet slot 51 for the air supply duct 28 extending substantially the length of the storage chamber 22 is shown. Also shown is a humidity sensor 51A. In FIGS. 5-6, a diagram of the return duct 29 and the associated air passage 48 is shown. As indicated by the arrows, air flows through inlet slots 52 arranged in a pair of rows 53 as shown. If necessary, a longer length inlet slot 54 is also used. The air exits through the outlet aperture 54A and returns to the air conditioner 48 through the ventilation passage 48 as shown and as indicated by the arrow. The air return duct also includes a booster 55, electrical connectors 56, and wires 57. Increasingly inwardly tapering toward the ventilation passage 48 best shown in FIG. 6 or alternatively increasingly outwardly tapering at the air conditioner 34 or at an end 59 remote from the ventilation passage 48. A baffle 58 labeled is also shown. In FIG. 7, a modified return duct 29A is shown that includes an unrestricted airflow passage 60 that tapers incrementally inward toward the end 59 away from the air passage 48 or air conditioner 34. The air flow passage 60 includes a tapered side wall 29B and is supported by a rectangular housing 29C. 8, a modified air supply having a plurality of baffles 60A each having an increasing length or height toward an end 61A remote from the air conditioner 34, as shown in FIGS. 2-3. Duct 28A is shown. An outlet slot 61, which is one or more apertures 62 if desired, is also shown. The switch board 40 includes a power input, a power isolation switch, and a fuse, as best shown in FIG. 9, and the control cabinet 38 transmits control signals from a microprocessor in connection with the operation and control of lighting variables. Power supply to the lighting control module 64 to determine, the elongated lighting 27, the air conditioner 34, the humidifier 39 and other electrically operated components used in connection with the storage chamber 22 shown in FIGS. The air conditioned has an initial width or width that tapers inwardly, increasing in length over its length toward an end remote from the location where the cooled and pressurized air is generated. (Iii) the controlled atmosphere storage chamber having one or more heat sources cooperating with the cooled and pressurized air from the initial supply flow path; Flowing downstream toward a storage member disposed therein, whereby the cooled and pressurized air flows around the one or more heat sources, whereby the air is consumed to dissipate heat. (Iv) allowing the consumed and heated air to flow through a return flow path toward the position where the cooled and pressurized air is generated, having a taper similar to that of the initial supply flow path; It also includes methods that include steps. Claims 1. (I) means for generating cooled and pressurized air located in or adjacent to the chamber; (ii) cooperating with the generating means to circulate the cooled and pressurized air throughout the chamber. One or more air supply ducts, the or each supply duct extending substantially the length of the chamber and increasing inwardly over the length toward the end remote from the generating means; One or more air supply ducts having an unrestricted air flow passage having a tapered lateral dimension or width toward; and (iii) cooperating with and substantially with the or each supply duct. Air outlet means extending the length of each supply duct; and (iv) one or more elongated hollow storage members having one or more heat sources disposed proximately, Also The interior of each storage member serves as a return duct for returning hot air to the generating means, the or each return duct extending substantially the length of the chamber and spaced from the generating means. One or more storage members, characterized by having an unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length toward the end; and A) an air inlet means cooperating with the or each return duct and extending substantially the length of the or each return duct. 2. The or each supply duct has a plurality of baffles on opposite sides of increasing length or height from an end proximate to the generating means to an end spaced from the generating means, and toward the spaced end. 2. The controlled atmosphere storage chamber of claim 1, wherein the controlled atmosphere storage chamber provides a tapered, unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length. 3. The or each supply duct has a plurality of baffles on opposite sides of increasing length or height from an end proximate to the generating means to an end spaced from the generating means, and toward the spaced end. 2. The controlled atmosphere storage chamber of claim 1, wherein the controlled atmosphere storage chamber provides a tapered, unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length. 4. The controlled atmosphere storage chamber of claim 1, wherein the air outlet means comprises an elongated slot. 5. The controlled atmosphere storage chamber of claim 1 wherein the air outlet means comprises a plurality of spaced apertures over its length. 6. The controlled atmosphere storage chamber of claim 1, wherein the air inlet means comprises one or more elongated slots. 7. 2. The controlled atmosphere storage chamber of claim 1 wherein the air inlet means comprises a plurality of spaced apertures optionally arranged in one or more rows over the length thereof. 8. The controlled atmosphere storage chamber of claim 1, wherein said one or more heat sources comprises one or more lighting strips. 9. 11. The controlled atmosphere storage chamber of claim 10, wherein the or each hollow storage member has the lighting strip mounted on an underside thereof. 10. A controlled atmosphere storage chamber according to claim 1, wherein the or each hollow storage member has a top support surface comprising a shelf for supporting perishables. 11. 12. The controlled atmosphere storage chamber of claim 11, including one or more heat sources proximate to the lighting strip. 12. The controlled atmosphere storage chamber according to claim 1, further comprising one or more pneumatic sensors located in the supply duct and / or the return duct. 13. The controlled atmosphere storage chamber according to claim 1, further comprising one or more air velocity sensors located in the supply duct and / or the return duct. 14． 2. The controlled atmosphere storage chamber of claim 1, further comprising humidifying means located within or adjacent to the chamber. 15. 12. The controlled atmosphere storage chamber of claim 11, including one or more humidity sensors located in the return duct. 16. 12. The controlled atmosphere storage chamber of claim 11, wherein each return duct has therein all heat generating components and wiring associated with each lighting strip. 17． A controlled atmosphere storage chamber according to claim 1, wherein one or more heating elements are provided in or near the inlet end of the or each supply duct. 18. A method of operating a storage chamber in a controlled atmosphere, comprising: (i) producing cooled and pressurized air; (ii) the cooled and pressurized air to obtain a balanced distribution within the chamber. Through the chamber, wherein the cooled and pressurized air tapers inwardly progressively over its length toward an end remote from the location where the cooled and pressurized air is generated. (Iii) passing the cooled and pressurized air from the initial supply flow path to the controlled supply having one or more heat sources cooperating therewith. Flowing downstream toward a storage member located in the storage chamber of the atmosphere, whereby the cooled and pressurized air flows around the one or more heat sources, whereby the air is (Iv) return the consumed and heated air to a location where the cooled and pressurized air is generated in a tapered manner similar to the initial supply flow path; A method that involves each step. [Procedure for Amendment] Article 184-8 of the Patent Act [Date of Submission] July 26, 1996 [Content of Amendment] Claims 1. (I) means for generating cooled and pressurized air located in or adjacent to the chamber; (ii) cooperating with the generating means to circulate the cooled and pressurized air throughout the chamber. One or more air supply ducts, the or each supply duct extending substantially the length of the chamber and increasing inwardly over the length toward the end remote from the generating means; One or more air supply ducts having an unrestricted air flow passage having a tapered lateral dimension or width toward; and (iii) cooperating with and substantially with the or each supply duct. Air outlet means extending the length of each supply duct; and (iv) one or more elongated hollow storage members having one or more heat sources disposed proximately, Also The interior of each storage member serves as a return duct for returning hot air to the generating means, the or each return duct extending substantially the length of the chamber and spaced from the generating means. One or more storage members, characterized by having an unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length toward the end; and A) an air inlet means cooperating with the or each return duct and extending substantially the length of the or each return duct. 2. The or each supply duct has a plurality of baffles on opposite sides of increasing length or height from an end proximate to the generating means to an end spaced from the generating means, and toward the spaced end. 2. The controlled atmosphere storage chamber of claim 1, wherein the controlled atmosphere storage chamber provides a tapered, unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length. 3. The or each supply duct has a plurality of baffles on opposite sides of increasing length or height from an end proximate to the generating means to an end spaced from the generating means, and toward the spaced end. 2. The controlled atmosphere storage chamber of claim 1, wherein the controlled atmosphere storage chamber provides a tapered, unrestricted airflow passage having a lateral dimension or width that tapers inwardly over its length. 4. The controlled atmosphere storage chamber of claim 1, wherein the air outlet means comprises an elongated slot. 5. The controlled atmosphere storage chamber of claim 1 wherein the air outlet means comprises a plurality of spaced apertures over its length. 6. The controlled atmosphere storage chamber of claim 1, wherein the air inlet means comprises one or more elongated slots. 7. 2. The controlled atmosphere storage chamber of claim 1 wherein the air inlet means comprises a plurality of spaced apertures optionally arranged in one or more rows over the length thereof. 8. The controlled atmosphere storage chamber of claim 1, wherein said one or more heat sources comprises one or more lighting strips. 9. The controlled atmosphere storage chamber of claim 1, wherein the or each hollow storage member has the lighting strip mounted on an underside thereof. 10. A controlled atmosphere storage chamber according to claim 1, wherein the or each hollow storage member has a top support surface comprising a shelf for supporting perishables. 11. 2. The controlled atmosphere storage chamber of claim 1 including one or more heat sources proximate to the lighting strip. 12. The controlled atmosphere storage chamber according to claim 1, further comprising one or more pneumatic sensors located in the supply duct and / or the return duct. 13. The controlled atmosphere storage chamber according to claim 1, further comprising one or more air velocity sensors located in the supply duct and / or the return duct. 14． 2. The controlled atmosphere storage chamber of claim 1, further comprising humidifying means located within or adjacent to the chamber. 15. 12. The controlled atmosphere storage chamber of claim 11, including one or more humidity sensors located in the return duct. 16. The controlled atmosphere storage chamber of claim 1 wherein each return duct has therein all heat generating components and wiring associated with each lighting strip. 17． A controlled atmosphere storage chamber according to claim 1, wherein one or more heating elements are provided in or near the inlet end of the or each supply duct. 18. A method of operating a storage chamber in a controlled atmosphere, comprising: (i) producing cooled and pressurized air; (ii) the cooled and pressurized air to obtain a balanced distribution within the chamber. Through the chamber, wherein the cooled and pressurized air tapers inwardly progressively over its length toward an end remote from the location where the cooled and pressurized air is generated. (Iii) passing the cooled and pressurized air from the initial supply flow path to the controlled supply having one or more heat sources cooperating therewith. Flowing downstream toward a storage member located in the storage chamber of the atmosphere, whereby the cooled and pressurized air flows around the one or more heat sources, whereby the air is (Iv) return the consumed and heated air to a location where the cooled and pressurized air is generated in a tapered manner similar to the initial supply flow path; A method that involves each step.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification symbol FI B65D 90/48 B65D 90/48 Z B65G 1/00 521 B65G 1/00 521Z F24F 3/044 F24F 3/044 (81) Designated country EP (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, MC, NL, PT, SE), OA (BF, BJ, CF, CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AM, AT, BB, BG, BR, BY, CA, CH, CN, CZ, DE, DK, EE, ES, FI, GB, GE, HU, JP, KE, KG, KP, KR, KZ, LK, LR, LT, LU, LV, MD, MG, MN, MW, NL, NO, NZ, P , PT, RO, RU, SD, SE, SI, SK, TJ, TT, UA, UZ, VN 2) An end extending over the length and spaced from the generating means (34) One or more storage members (23) characterized by having an unrestricted airflow passage having a lateral dimension or width tapering outwardly over its length toward (59). And (v) air inlet means (52, 54) cooperating with the or each return duct (29) and extending substantially the length of the or each return duct (29). Storage chamber (22) in a conditioned atmosphere.

Claims (1)

[Claims]   1. (I) cooling and pressurized air located in or near the chamber; Generating means;   (Ii) cooperating with the generating means to transfer the cooled and pressurized air to the entire chamber; One or more air supply ducts circulating through the or each supply The duct extends substantially the length of the chamber and has an end spaced from the generating means. Tapered horizontal dimension that gradually increases inward over its length toward the part One or more air supplies with unrestricted air flow passages of any width or width Duct and;   (Iii) cooperating with the or each supply duct and substantially the or each supply; Air outlet means extending the length of the duct;   (Iv) one or more with one or more heat sources located in close proximity The elongated hollow storage member above, wherein the interior of each or each storage member is heated. Function as return ducts for returning the returned air to the generating means, or each return The duct extends substantially the length of the chamber and has an end spaced from the generating means. Tapered lateral dimension increasing outward over its length towards the part One or more characterized by having an unrestricted air flow passage having a width or width. More storage components;   (V) cooperating with the or each return duct and substantially the or each return duct; Air inlet means extending the length of   A controlled atmosphere storage chamber containing.   2. The or each supply duct is separated from the generating means from the end close to the generating means. A plurality of baffles on both sides of decreasing length or height to spaced apart ends; Tapered inward, gradually increasing over its length towards the intervening end Claims: Providing a tapered, unrestricted airflow passage having a reduced lateral dimension or width Item 2. A controlled atmosphere storage chamber according to Item 1.   3. The or each supply duct is directed towards the end of the duct remote from the generating means The width or width of the taper inwardly increasing over its length The controlled atmosphere storage chamber of claim 1 having:   4. The or each return duct shall be separated from the generating means from the end close to the generating means. A plurality of baffles on opposite sides of increasing length or height to spaced ends; Tapered outwards gradually over its length towards the spaced end Claims: Providing a tapered, unrestricted airflow passage having a reduced lateral dimension or width Item 2. A controlled atmosphere storage chamber according to Item 1.   5. The or each return duct is directed towards the end of the duct, spaced from the generating means Lateral dimensions or widths tapering outwards gradually over its length The controlled atmosphere storage chamber of claim 1 having:   6. 2. The controlled atmosphere of claim 1 wherein said air outlet means comprises an elongated slot. Qi storage chamber.   7. The air outlet means comprises a plurality of spaced apertures over its length. A storage chamber with a controlled atmosphere as described.   8. 2. The air inlet means of claim 1, comprising one or more elongated slots. A storage chamber with a controlled atmosphere.   9. The air inlet means is optionally arranged in one or more rows and spans its length. The controlled atmosphere storage chamber of claim 1 comprising a plurality of spaced apertures. -   10. The one or more heat sources include one or more lighting strips The controlled atmosphere storage chamber of claim 1.   11. The or each hollow storage member is mounted on the underside thereof with the lighting 11. The controlled atmosphere storage chamber of claim 10 having strips.   12. The or each hollow storage member supports perishable objects. 3. The controlled atmosphere storage chamber of claim 1 having a top support surface comprising a shelf. bar.   13. 12. The method of claim 11, including one or more heat sources proximate the lighting strip. A storage chamber with a controlled atmosphere.   14． One or more air located in the supply duct and / or return duct The controlled atmosphere storage chamber of claim 1, further comprising a pressure sensor.   15. One or more air located in the supply duct and / or return duct The controlled atmosphere storage chamber of claim 1, further comprising a speed sensor.   16. 2. The method of claim 1, further comprising humidifying means disposed in or near the chamber. Controlled atmosphere storage chamber.   17． 2. The method of claim 1, further comprising one or more humidity sensors disposed in the return duct. A storage chamber with a controlled atmosphere as described.   18. Each return duct contains in it all the heat associated with each lighting strip. The controlled atmosphere storage chamber of claim 11 having a production component and wiring. .   19. One or more within or near the inlet end of the or each supply duct A controlled atmosphere storage chamber according to claim 1, wherein the upper heating element is provided.   20. The method of operating the storage chamber in a controlled atmosphere, comprising:   (I) producing cooled and pressurized air;   (Ii) cooling and pressurizing to obtain an equilibrium distribution in the chamber; Flowed air into the chamber, and the cooled and pressurized air is cooled and pressurized. Over its length toward the end remote from the location where the Through an initial supply passage having an increasingly inwardly tapered transverse dimension or width. R;   (Iii) cooperating the cooled and pressurized air from the initial supply flow path The controlled atmosphere having one or more heat sources Flow downstream toward a storage member located in the air storage chamber; The cooled and pressurized air flows around one or more heat sources. Whereby the air is consumed and has heat;   (Iv) tapering the consumed and heated air with a taper opposite to the initial supply flow path; Through the return flow path towards the position where the cooled and pressurized air is generated Do   A method that includes each step.