HEAT EXCHANGER DOOR SYSTEM WITH MOVABLE DOOR |
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申请号 | US12059678 | 申请日 | 2008-03-31 | 公开(公告)号 | US20090242185A1 | 公开(公告)日 | 2009-10-01 |
申请人 | Michael Cyril HASELDINE, JR.; | 发明人 | Michael Cyril HASELDINE, JR.; | ||||
摘要 | A heat exchanger door system includes a heat exchanger and a first rotatable member, proximate to the heat exchanger, that rotates about an axis of rotation. The system includes a first door member rolled around the rotatable member and movable from a rolled position to an unrolled position in which the first door member covers more of the heat exchanger than when the door member is in the rolled position. | ||||||
权利要求 | |||||||
说明书全文 | 1. Field of the Invention This invention relates to a movable member configured to partially or fully isolate a heat exchanger from an environment. In one example, the movable member is disposed within a cooling system such as a freezer, and isolates one or more heat exchangers within the freezer from an interior of the freezer during a defrost operation. 2. Description of the Related Art In cooling systems such as freezers and refrigerators, moisture from the air entering the cooling system through open doors, small passages in the walls or floors, and from the product stored within the cooling system frequently collects on heat exchanger coils and heat exchanger fins in the form of ice. During long operation, ice can accumulate on the coils and fins creating a blockage that impedes the airflow over the heat exchanger and creates a loss in efficiency in operation of the cooling system. Typical heat exchangers increase or decrease temperature by running fluid through manifolds that feed loops of tubes. The tubes frequently have fins attached to them. The purpose of the fins is to increase the effective surface area of the tubes in order to increase the rate of heat exchange. Air flow is typically provided by fans which blow or draw air across the finned tubes. A heat exchanger rating, typically listed in British Thermal Units “BTU,” depends on the number of air cycles which go through the finned tubes per minute. In a freezing application, constriction of the fins or tubes due to ice build up reduces the number of air changes that are allowed to occur. This in turn reduces the heat exchanger's capacity. Accordingly, many heat exchangers in cooling systems must be regularly defrosted in order to maintain sufficient cooling capacity. In order to provide efficient defrosting of individual heat exchangers without requiring defrosting an entire freezer, sequential defrost units have been developed. One objective of a sequential defrost unit is to maintain temperature and freezing/cooling of stored or processed product while providing defrost in one or more heat exchangers at a time. One issue in providing sequential defrost is a difficulty in effectively isolating the one or more heat exchangers in the defrost stage while running other heat exchangers in the cooling system. Some conventional sequential cooling systems are designed with sufficient capacity to allow for at least one heat exchanger to be defrosted while the remaining heat exchangers can accommodate the refrigeration load in the application. In other words, if the required cooling capacity is ninety tons of refrigeration, one would provide a one-hundred-and-twenty ton capacity in four heat exchangers, i.e., thirty tons in each heat exchanger. With the above-noted arrangement, when one heat exchanger is in defrost, the remaining three heat exchangers provide the required ninety ton refrigeration capacity. Conventional sequential cooling systems often attempt to isolate the heat exchanger undergoing defrost with mechanical louvers or shutters. However, the louvers or shutters themselves can become coated or clogged with ice and cease to adequately isolate the heat exchanger during its defrost stage. In some cases, the shutters freeze in the open or closed position. When this clogging occurs, air flow around the heat exchanger undergoing defrost can be disrupted, which can result in an increased amount of time required to defrost the heat exchanger. Furthermore, warm air from the heat exchanger undergoing defrost can leak into the cooling system at large, resulting in an increased heat load on the heat exchangers that are not being defrosted. Accordingly, one aspect of the present invention is to allow the sequential defrost of individual evaporators (otherwise know as heat exchangers) while maintaining desired airflow and design temperature in the cooling system. One example of the invention provides movable doors or screens configured to unroll from a stored position to be placed over each evaporator front and/or back side. In one example, the doors are controlled via a PLC and/or frost detection devices. The controller directs the doors to move, for example, downward, into a closed position or upward into an open position. When these doors are closed, i.e., in an unrolled position, the heat exchanger is at least partially isolated from air movement in the remainder of the freezer created by any fans that are often included with cooling systems, especially large-scale cooling systems. Thus, in this example, airflow over the heat exchanger or heat exchangers undergoing defrost is reduced, and the heat exchangers will defrost more efficiently. Another aspect of the present invention is the containment of any heat produced in the defrosting heat exchanger during the defrost process. This containment creates a hot zone around the defrosting heat exchanger, which allows for a faster defrost time than some conventional defrosters. Additionally, the containment of the heat around the defrosting heat exchanger reduces the effect the defrosting heat exchanger on the area of the cooling system used to store items such as food. One aspect of the invention uses two doors on each heat exchanger, one on the front side of the heat exchanger and one on the back side of the heat exchanger. In one example, the doors are nylon fabric doors. The doors can be moved to roll or unroll by one or more motors. In an example using one motor, there may be a linkage to actuate the door on one side, typically the back side, of the heat exchanger. Preferably, any doors, shafts, and tracks are compatible with the temperatures normally present in the cooling system. In one example, the doors can be quite wide. In certain embodiments, when the doors are wide, the door preferably includes a reinforcement or “wind rib” in the center of the door to help prevent the door from collapsing due to air movement within the cooling system. One beneficial aspect of certain examples of the invention is the reduction in defrost time due to the concentration of heat used to defrost the heat exchangers. Another aspect of the invention is that the door or doors are can be placed in a rolled up (open position) or unrolled (closed position) within a hood, and thus, isolated from the freezer environment. Some aspects of the invention include a door with a weighted bar at the bottom. The weighted bar typically enhances the sealing effect of the door by pressing any sealing material against a sealing surface. When in the down position, the doors may be subject to moisture buildup (condensation) on the side of the door facing the heat exchanger being defrosted. Accordingly, another aspect of the invention provides a scraper or squeegee to scrape off condensation from the door when the door moves into or out of a closed position. In one embodiment, the scraper is made from ultra-high molecular weight polyethylene (UHMW). In one embodiment, the door comprises nylon based fabric. In a further example, the door has a coating of polyvinylchloride (PVC) laminate. In yet a further example, the doors include a water repellant such as a siliconized overcoat. Another aspect of the invention includes a nozzle providing a loop of hot gas. The hot gas is typically bled from a main hot gas line used to defrost the heat exchanger. The loop heats the hood area to release moisture that could potentially freeze the door in an up position and risk tearing the door when the door is engaged to move. The door may be enclosed in a hood when in an open or rolled-up position. In one example, the hood is stainless steel or insulated metal and encompasses most of the door when the door is in a rolled-up position. In one example, the only area exposed when the doors are in a rolled-up state is the bottom which remains outside of the hood area. The top of the hood can be pitched to drain moisture which may be created during the pre-defrost of the door, and the hood can be heated to reduce the build-up of ice on the rolled up door during normal non-defrost operation of the cooling system. One aspect of the invention provides a door system for partially isolating a heat exchanger. In one example, the door system is provided as a kit for retrofitting existing heat exchanger equipment. Typically, the door system includes a first rotatable member configured to be attached proximate to the heat exchanger. The first rotatable member is configured to rotate about an axis of rotation. The system also includes a first door member rolled around the rotatable member and movable from a rolled position to an unrolled position in which the first door member extends farther away from the rotatable member than when the door member is in the rolled position. The system also typically includes a track configured to guide the first door member as the first door member moves from the rolled position to the unrolled position. Benefits of certain examples of the present invention include providing shorter defrost cycle times because the heat exchanger is more effectively isolated during the defrost cycle than are heat exchangers in conventional cooling systems. This isolation typically results in saving electrical usage. As the movable door typically takes of little space within the cooling system, another benefit of the present invention is improved accessibility for cleaning and maintenance. The movable door can advantageously be retro-fit to existing systems, or installed in newly manufactured systems. One example of the present invention can provide a heat exchanger door system including a heat exchanger. The system further includes a first rotatable member, proximate to the heat exchanger. The rotatable member is configured about an axis of rotation. A first door member is rolled around the rotatable member and can move from a rolled position to an unrolled position in which the first door member covers more of the heat exchanger than when the door member is in the rolled position. In one example, the rotatable member is coupled to a motor and, optionally, a gearbox. In a preferred example, the first door member is at least partially contained in a track and slides within the track during a roll-up or roll-down process. In some examples, the there are two rotatable members, each including a door member. In one variation of this example, the two rotatable members are disposed in parallel with each other. One aspect of the invention provides a door system for partially isolating a heat exchanger. The door system typically includes a first rotatable member, configured to be attached proximate to the heat exchanger, which rotates about an axis of rotation. The door system further typically includes means for covering the heat exchanger, the means for covering being rolled around the rotatable member and movable from a rolled position to an unrolled position in which the means for covering extends farther away from the rotatable member than when the means for covering is in the rolled position. The door system also further typically includes a track configured to guide the means for covering as the means for covering moves from the rolled position to the unrolled position. These and other advantages of the invention will become more apparent and more readily appreciated from the following detailed description of the exemplary embodiments of the invention taken in conjunction with the accompanying drawings where: With reference to Typically cooling systems will include a plurality of heat exchangers 30. During normal operation, it is useful to defrost the heat exchangers 30 individually while allowing the remaining heat exchangers 30 to remain on cooling duty. When a defrost of one of the heat exchangers 30 is performed, the door member 10 is typically unrolled to isolate the heat exchanger 30 from the rest of the cooling system. This isolation helps the heat exchanger 30 undergoing defrost to heat up faster than it would be able to if it were not isolated. Furthermore, the isolation of the heat exchanger 30 undergoing defrost helps keep the remainder of the cooling system cool by reducing leakage of heat from the defrosting heat exchanger 30 into the rest of the system. The gearbox 42 is typically disposed near one end of the rotatable member 11 and can perform at least one of two functions. First, the gearbox 42 can reduce the rotational speed of the motor 40 to a level suitable for movement of the door member 10 from a rolled position to an unrolled position. The reduction of the rotational speed of the motor 40 also results in a corresponding increase in torque applied to the rotatable member 11. Additionally, the gearbox 42 can be used to change the direction of the output provided by the motor 40. In other words, the motor 40 may provide an output that rotates around a vertical axis of rotation, and the gearbox 42 can couple this vertical axis of rotation to a rotatable member 11 having a horizontal axis of rotation. One benefit of this arrangement is that the motor 40 can be positioned and oriented relatively compactly with respect to the door member 10 and rotatable member 11. At least a portion, and preferably the majority of the door member is housed in the optional hood 60 when the door member is in a rolled up state. The hood 60 typically comprises sheet metal such as stainless steel, but other materials such as cold-resistant polymers or aluminum may be used. Additionally, the hood 60 preferably includes a layer of insulation 61 (shown in The door member 10 itself is typically comprised of woven nylon fabric. However, other types of flexible, rollable material may be used. In one example, the door member 10 is coated with a coating of polyvinylchloride (PVC) laminate. In another example, the doors include a water repellant material such as a siliconized overcoat. The door member 10 optionally includes a rib 20 that helps reduce possible flapping of the door member 10 due to air movement within the cooling system 1. The rib 20 preferably includes a semi-rigid or rigid material such as stainless steel in order to enhance the rigidity of the door member 10. Preferably, the rib 20 extends in a direction parallel to the axis of rotation X in order to allow the rib 20 to be rolled up with the door member 10. As further depicted in As further shown in As further shown in In some circumstances, it is preferable to build the rotatable member 11 and door member 10 etc. with the heat exchanger as an integral system. In other cases, the door system 1 is installed as a retrofit. In other words, existing refrigeration systems are upgraded to include the door system 1. In this case, the door system 1 can replace an existing door system or can supplement an existing door system. Alternatively, the door system 1 can be installed in refrigeration systems that have no previous door system for isolating heat exchangers. Although only certain embodiments of this invention have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiment without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention. |