Automatic food dispensers or vending machines for dispensing pre-packaged food products are well known. Typically, the vending machine includes a cabinet or housing having mounted therein at least one inventory area that includes refrigerated passages or compartments for storing food products to be dispensed. The vending machine can further be provided with a microwave oven and a conveying system operable to remove one of the food products from the inventory area and position the food product within the microwave oven for cooking. The present disclosure relates to an improved vending machine.
According to one aspect, a vending machine adapted for dispensing at least one pre-packaged food product includes a microwave oven. The microwave oven includes a magnetron that emits microwave electromagnetic radiation and a housing that defines a microwave cavity for receiving the food product. The housing defines a first opening to allow passage of the pre-packaged food product between outside of the microwave cavity and inside of the microwave cavity. The microwave oven also includes a first chain door that selectively covers the first opening so as to prevent the microwave electromagnetic radiation from escaping the housing through the first opening.
According to another aspect, a method of dispensing at least one pre-packaged food product includes selecting the pre-packaged food product from an inventory area, moving the selected pre-packaged food product from the inventory area through a first opening of a housing to a microwave cavity of the housing, emitting microwave electromagnetic radiation to heat the pre-packaged food product, and preventing the microwave electromagnetic radiation from leaving the microwave cavity thought the first opening with a first chain door.
According to another aspect, a vending machine adapted for dispensing at least one pre-packaged food product includes a microwave oven. The microwave oven includes a magnetron that emits microwave electromagnetic radiation and a housing that defines a microwave cavity for receiving the food product. The housing defines a bottom opening to allow passage of the pre-packaged food product between outside of the microwave cavity and inside of the microwave cavity. The microwave also includes a platen configured to support the pre-packaged food product and also selectively cover the bottom opening so as to prevent the microwave electromagnetic radiation from escaping the housing through the bottom opening.
According to another aspect, a method of dispensing at least one pre-packaged food product includes selecting the pre-packaged food product from an inventory area, raising the selected pre-packaged food product on a platen through a first opening of a housing to a microwave cavity of the housing, emitting microwave electromagnetic radiation to heat the pre-packaged food product, and preventing the microwave electromagnetic radiation from leaving the microwave cavity thought the first opening with the platen.
It should, of course, be understood that the description and drawings herein are merely illustrative and that various modifications and changes can be made in the structures disclosed without departing from the present disclosure. Further, it will be appreciated that a reference to a general figure is a reference to all of the figures of that number. Stated another way, any general call-out to a figure, for example,
Referring now to the drawings, wherein like numerals refer to like parts throughout the several views,
The vending machine 100 generally includes a cabinet 102 for housing various operational components of the vending machine. The operational components can comprise at least one inventory area 104 that includes refrigerated passages or compartments for storing at least one food product 128 to be dispensed, a microwave oven 110 for heating/cooking the food product, and a conveying system 112 (e.g., a conveyor, a robotic arm, and the like) operable to remove at least one of the food product 128 from the inventory area 104 and position the food product 128 within a cavity 124 of the microwave oven 110 for cooking.
It will be appreciated that the microwave oven 110 could be any number of different types of ovens that emit radiation, including for example, microwave, radio frequency (RF), infrared (IR). convection, resistive element, and combinations thereof. Further, the term refrigerated will be understood to encompass any device that reduces a temperature of the food product. This could include, for example, freezers, refrigerators, and ice boxes.
As is well known, the vending machine 100 includes a front operational panel 114, which can include a display screen, a keypad (and/or touchscreen), a credit/debit card reader, a cash acceptor opening, a change return, and a receipt printer. All of these features are electronically coupled with a central processing unit (CPU) 120 for automated operation of the vending machine 100. The food product is available for selection from the vending machine 100 optionally are viewable through a window on the cabinet 102 and can be selected, for example, by entering a code using the keypad. Alternatively, the available food product 128 can be visualized via a graphical user interface.
The CPU 120 can include a transaction processing module configured to verify receipt of payment for the selected food product, generate a change return signal that causes any remaining money credit to be returned through the change return, generate a dispensing signal for the conveying system to permit the selected food product to be retrieved from the inventory area 104 and delivered to the microwave oven 110, and generate a cooking signal that selectively operates the microwave oven 110 based on the selected food product. The basic operation of the vending machine 100 is well understood, and a detailed explanation thereof is not necessary for an understanding of the present invention.
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The housing 122 can includes a first wall 132 with a first wall inner surface 132a and a first wall outer surface 132b, a second wall 134 with a second wall inner surface 134a and a second wall outer surface 134b, a third wall 136 with a third wall inner surface 136a and a third wall outer surface 136b, and a fourth wall 138 with a fourth wall inner surface 138a and a fourth wall outer surface 138b. Further, the first wall 132 can be spaced from the second wall 134 and the third wall 136 can be spaced from the fourth wall 138. Additionally, a top wall 142 can connect the first wall 132, second wall 134, third wall 136, and fourth wall 138 together on a top portion of the microwave oven 110 and a bottom wall 144 can connect the first wall 132, second wall 134, third wall 136, and fourth wall 138 together on a bottom portion of the microwave oven 110. A horizontal distance between the first wall inner surface 132a and the second wall inner surface 134a defines a cavity depth and a horizontal distance between the third wall inner surface 136a and the fourth wall inner surface 138a defines a cavity width.
The top wall 142 can include a top wall inner surface 142a and a top wall outer surface 142b and the bottom wall can include a bottom wall inner surface 144a and a bottom wall outer surface 144b. A vertical distance between the top wall inner surface 142a and the bottom wall inner surface 144a defines a vertical cavity height. The inner surfaces 132a, 134a, 134a, 138a, 142a, 144a of the first wall 132, second wall 134, third wall 136, and fourth wall 138, top wall 142, and bottom wall 144, respectively, face toward the microwave cavity 124, whereas the outer surfaces 132b, 134b, 134b, 138b, 142b, 144b of the first wall 132, second wall 134, third wall 136, and fourth wall 138, top wall 142, and bottom wall 144, respectively, face away from the microwave cavity 124, which is in a direction opposite of the respective inner surface. The first wall 132, second wall 134, third wall 136, fourth wall 138, top wall 142, and bottom wall 144 are constructed such that the microwave electromagnetic radiation emitted by the magnetron 126 does not pass through the respective walls 132, 134, 136, 138, 142, 144.
The housing 122 can define a first opening 146 to allow passage of the food product 128 between outside of the microwave cavity 124 and inside of the microwave cavity 124. As shown in
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Further each of the pieces of chain 156 includes an attached end 158 and a free end 162 disposed at opposite ends with a plurality of links 164 extending therebetween. The plurality of links 164 may be in the form of spheres, cylinders, strips, cubes, ellipsoids, triangles, or the like, and they may be solid, jacketed, layered or fluid-containing, or any combinations of the foregoing, in order to achieve the proper density and geometry necessary for the desired radiation shielding. The attached end 158 can be fixedly attached to the housing 122, whereas the free end 162 can remain unattached to the housing 122 or other components. As shown, each of the pieces of chain 156 extends in primarily a vertical orientation.
The first chain door 154 is optimized to shield microwave and RF frequency radiation. The first chain door 154 can have a cross-sectional density that is the equivalent of 0.25 mm or more of lead in radiation shielding capacity. It will be appreciated that the basic radiation shielding elements used in the construction of the present disclosure may be made of various materials or combination of materials, and with varying geometries, all of which combinations and variations will be within the purview of one skilled in the art, having the benefits of the teaching of the present disclosure. The first chain door 154 can be a radiation-shielding element which may be elongated to form a strand-like member that can be flexibly connected to a number of other similar elements to form a pliant or flexible string. For example, the first chain door 154 could be a spherical-bead chain.
The first chain door 154 can include an interior chain curtain 166 and an exterior chain curtain 168. The interior chain curtain 166 and the exterior chain curtain 168 of the first chain door 154 can be equal in size to one another and spaced from one another so as to provide two chain layers through which the pre-packaged the food product 128 passes to go between the outside of the microwave cavity 124 and the inside of the microwave cavity 124. This dual layer arrangement can provide for improved radiation protection and allow for smaller links 164 to be used.
With reference to
The second chain door 172 can include an interior chain curtain 184 and an exterior chain curtain 186. The interior chain curtain 184 and the exterior chain curtain 186 of the second chain door 172 can be equal in size to one another and spaced from one another so as to provide two chain layers through which the pre-packaged the food product 128 passes to go between the outside of the microwave cavity 124 and the inside of the microwave cavity 124. The interior chain curtain 166 and exterior chain curtain 168 of the first chain door 154 can be of a same width and height of the interior chain curtain 184 and exterior chain curtain 186 of the second chain door 172.
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The conveying system 112 illustrated in
A method of dispensing at least one pre-packaged food product 128 can include selecting the pre-packaged food product 128 from an inventory area 104, moving the selected pre-packaged food product 128 from the inventory area 104 through a first opening 146 of a housing to a microwave cavity 124 of the housing, emitting microwave electromagnetic radiation to heat the pre-packaged food product 128, and preventing the microwave electromagnetic radiation from leaving the microwave cavity 124 thought the first opening 146 with a first chain door 154. Further, the first opening 146 can be covered with the first chain door 154 when the microwave electromagnetic radiation is being emitted.
Another method of dispensing at least one pre-packaged food product 128 can include selecting the pre-packaged food product 128 from an inventory area 104, raising the selected pre-packaged food product 128 on a platen 196 through a bottom opening 152 of a housing to a microwave cavity 124 of the housing, emitting microwave electromagnetic radiation to heat the pre-packaged food product 128, and preventing the microwave electromagnetic radiation from leaving the microwave cavity 124 thought the bottom opening 152 with the platen 196. When the selected pre-packaged food product 128 is being raised on the platen 196, the food product 128 is moved in a vertical direction toward a top wall 142 of the housing 122 such that the selected pre-packaged food product 128 is between the platen 196 and the top wall 142.
It will be appreciated that the above-disclosed and other features and functions, or alternatives or varieties thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2019/015328 | 1/28/2019 | WO | 00 |
Number | Date | Country | |
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62625581 | Feb 2018 | US |