FR2689220A1 - Absorption refrigerator using microwaves as heat source - uses sliding control facing magnetron to direct microwaves to either absorption refrigerator or microwave oven. - Google Patents

Abstract

The absorption refrigerator is built as an integral unit with a microwave oven. A single magnetron (2) is mounted at the base of the unit facing a sliding control (22) that has passages formed through it to allow the magnetron output to be directed either to the refrigeration (41) unit or the microwave oven (43), depending on the position of slide. The microwaves are carried by waveguides (29,30) to the appropriate destination. The absorption refrigeration unit can cool a conventional refrigerator and also a freezer compartment (42). USE/ADVANTAGE - Allows single magnetron to be used to provide machine that can produce both hot and cold water for preparation of drinks.

Description

The present invention relates to an absorption cycle refrigeration system (water, ammonia, hydrogen), using the microwaves generated by a magnetron as a boiler heating device, this refrigeration system can also be associated with a cooling device. water heating, while remaining powered by the same magnetron which is oriented microwaves by a drawer system, and which is channeled to the chosen heating mode, through conduits carrying these microwaves
The currently known techniques consit to use the thermoelectric cell with "peltier effect" which has the advantage of providing in one homogeneous and static module a cold side and the other heat.

-However, its use remains limiting because of the low powers obtained
Heat pumps are not used for this function because their heating performance would not reach 1002 for a device of this size. Moreover their design and their implementation would be too expensive and innoportune for this gamne of power.

 Even then, effective techniques used to meet domestic or commercial demand for cooling and / or heating capacity have been the separate use of refrigerating units (with a compression cycle), associated with heat production elements (heat resistors). electric or gas burner).

When the absorption refrigeration cycle has been implemented, it has until now been associated with heating modes using heat recovery (exhaust pipes of heat engines, or vapors), or heating modes. more conventional, (thermoelectric resistors or burner-gas). Supplied in the market of commercial refrigeration and household by the cycle of compression refrigeration, it is however commonly used for installations of air conditionings because of its silent function and for installations not with no electricity (necessary for compressors), such as gas-operated campground refrigerators or solar-powered absorption cycle refrigerators (Patent No. ">
The refrigerant circuit of the invention remains conventional, and comprises its known organs according to the prior art. However, the original form of abhorb2ur (10) can only favor the absorption phase of even the exploitation of residual microwaves which allows the boiling in two stages (boiler-boiler and boiler-separator), not can only favor the absorption refrigeration cycle.

The advantage of this invention lies essentially in the fact that the magnetron (2) supplying the microwaves for the absorption refrigerator (1) may also provide it for another use, such as a microwave oven ( 43>, or a cavity for heating water with microwaves (4)
It appears in this case that a simple arrangement in the microwave supply circuit, by means of an orientation device (22), and pipes of these microwaves, allows the simultaneous operation of the cooling system and heat system in a single unit (Figure 1 & 9)
The design of such an apparatus is made possible by the assembly of metal sheets <FIGS. 1 &9>, having a longitudinal junction plane, and imprinting the refrigerant circuit comprising the ducts, cavities and recesses (FIG. , 6), and imprint of the heat circuit (Figure 9), or by joining by welding, piping and pieces of boiler making these circuits
according to the configuration of these circuits, the apparatus will take on its definitive appearance after the folding of its parts, thus constituting a functional carcass, ensuring the refrigerating production (FIG. 7 & 8), and calorific production (FIG. 10), thus offering a structure (or chassis) adapted to receive a dressing to obtain a finite appearance device (Figure 10).

-The other advantages inherent to the use of the absorption refrigeration cycle are: its silent function, and its longevity due to its static function
-On the other hand, the heat of the microwave for heating water allows to maintain optimal performance because the deposit of limestone on the walls of the heating cavity does not affect the diffusion of microwaves , moreover the heating of the water by the microwaves is immediately effective because they heat the water directly within it and offer no thermal inertia unlike the electric resistances: -The heating of the water by microwaves is flexible, just program the duration of exposure of microwaves corresponding to a volume of water, as a non-exhaustive example: 10 minutes are enough to heat 1 liter of water of 204 & 100, the duration of heating for 25cl at the same T will be 2.5 minutes .We can consider that a differential temperature thermostat records the temperature difference between the outlet and the water inlet (varying with the seasons), so what it controls the optimal duration of microphone power - water heating
FIG. 1 represents the schematic diagram of the apparatus for refrigerating use of the "kettle" type refrigerator and heating type for heating water
FIGS. 2,3 to 4 represent the orientation slide of the microwaves
FIGS. 5 & 8 show the absorption refrigeration apparatus designed for use with the vertical evaporator
FIGS. 6 & 7 show the absorption refrigeration apparatus designed for use with the horizontal evaporator.

FIG. 9 shows the apparatus in its mixed configuration (refrigerator and microwave oven), assembled in a flat sheet (with longitudinal section at the orientation of the microwave drawer)
FIG. 10 represents the apparatus of FIG. 9 whose folds have been effected, it reflects in this figure a fairly complete image of one of the applications of the invention
FIG. 11 represents a detailed view of the absorber, composed of two triangular absorber elements
FIG. 1 shows a longitudinal section of the refrigerating apparatus (1), the magnetron (2V, the microwave orientation drawer (3), and the use of microwaves for the production of hot water (4)
-The power supply of the apparatus is provided by the magnetron (2) which is fed through an electrical circuit known according to the prior art
The waves generated by the magnetron are oriented by the orientation slide (22), the function of which is illustrated by FIGS.
-When the drawer (22) directs the microwaves to the window (4) of the heat production they are then channeled through the microwave pipe (30), and serve the selected heating mode (oven to microwaves, or hot water tank) .When the drawer (22) directs the microwaves to the refrigerating production apparatus (1), they are then channeled by the tube (29) which convey them to the boiler- elevator (5) passing through a sealed glass (or ceramic or plastic) window (35)
The ammonia solution is brought to the boiler by the conduit (14), or it is heated by the microwaves (because of the agitation of the molecules of water at the frequency of the microwaves), then it is conveyed to the rising tube (by capillarity and due to the rise in temperature) to the boiler-separator (7), or residual microwaves still heating the rich solution, reduce the solubility of ammonia in water
the gaseous amoniac is then released under a pressure close to its saturation vapor pressure at the temperature of the boiler
The gaseous ammonia is favored by the kettle form of the separator-boiler (7), towards the rectifier (16) where the ammonia vapors separate mechanically driven water droplets, then the ammonia vapors are conveyed to the condenser (8), which inclined, channels the condensate to the capillary (19), which joins the collector (17) of hydrogen (poor gases), to obtain by thermal conduction between these two ducts, a sub-cooling of the condensed ammonia
-A capillary (20) asure the equalization of pressures between the condenser and the absorber, to facilitate the circulation of the gases
-The relaxation of ammonia condensates occurs in (21) where the gases mix (amoniaque and hydrogen), forming the rich gas which evaporates then in the evaporator (9>
At the outlet of the evaporator (9), the rich gas is absorbed in (18) by the poor solution (15) which, coming from the boiler is injected into the rich gas duct (9), to then be admitted to the absorber (10>
-In the absorber (10) the poor solution absorbs ammonia from the rich gas (because of the important power of dissolution of the amoniaque in water), and tends to reject the hydrogen of the rich gas towards the collector ( 17), or the hydrogen is evacuated (taking with it a little amoniaque)
This operation is favored by the triangular shape of the absorber elements (10), and by the bumps (13) which cause both mixing and uniform diffusion of the solution in the absorber.
At the outlet of the absorber, the enriched solution is stored in the reservoir (11), then to be conveyed to the conduit (14), through the exchanger (12), to the rich solution feed ( 15), the boiler-lifter (5>
FIG. 2 shows a longitudinal section of the microwave orientation slide (22), hermetically sealed by a metal membrane (3), in order to confine the slide in a hermetically sealed chamber to prevent any leakage.
-The principle of this system uses the reflective properties of metal for microwaves, notably iron
The rectangular section drawer is guided in its longitudinal translation by the envelope (3), which serves as a guide
At each end of the drawer springs calibrated (24) ensure its central position at rest.

Conical recesses (23) have been made in the movable body of the slide, parallel to an axis AC 'for the conduit 25, and has an axis AC for the conduit 23
-These two orientation ducts are of opposite direction, and have their widest bases located respectively in the B 'axis, and in the B axis, towards the magnetron
FIG. 3 a longitudinal displacement of the mobile body to the left by a distance equivalent to the AB-axis (48>, which allows the orientation of the microwaves towards the pipe (30>
This movement is caused by the magnetic attraction of an electromagnet (27), whose excitation is controlled by the demand for microwaves in the pipe (30). The magnetic field attracts towards the electromagnet (27). ) the mobile body of the orientation slide (22) of micro waves, (composed of metal)
FIG. 3 shows a variant of FIG. 3, where the recesses (23 & 25) made in the movable body of the drawer are cylindrical, and no longer conical (to make the manufacture of the drawer easier), in this case the diameter of the ducts increases at each junction
FIG. 5 shows the assembly (made by any known means) of two plates imprinted with the refrigerant circuit (45>, and having a longitudinal junction plane
This set is different from FIG. 1 by the addition of an additional lateral flank (34), the purpose of which is to complete mechanically the apparatus in its configuration (obtained after folding), carcass and production unit. refrigerated
- Recesses (32> were made to remove the innoportune thermal conductions, and allow the folding of some parts
FIG. 6 highlights while having (omitted the lateral flank removed here arbitrarily), the same characteristics as FIG. 5, a modification (33), differentiating in this respect the refrigerant circuit (44), of the circuit (45)
-This modification allows the feeding of the evaporator from above by practicing a circuit drawing an "gooseneck" reversed, which facilitates the horizontal arrangement of the evaporator during folding
FIG. 7 represents the apparatus (44) of FIG. 6, the bends of which have been made (after having cut off the holding tabs).

-It highlights the horizontal position of the evaporator, as well as the detachment of the condenser
FIG. 8 represents the apparatus (45) of FIG. 5 which has been made folds (in the same manner as for FIG. 7)
-It highlights the vertical and unhooked position of the evaporator towards the inside of the refrigerator
FIG 9 shows the assembly by any known means of two plates stamped with a refrigerant circuit (46), having a longitudinal plane of joction. This assembly is equipped with a lateral flank (36), and a superiuere part (35), provided as a carcass of a microwave oven
- Recesses (32 to 37) were made to allow the folding of the different parts of the apparatus
Legs have been created by cutting recesses (38) to maintain the horizontal planes during folding
A new pipe (30) conveys the microwaves to the diffusion recess (40) thereof in the microwave oven (4.3).

the longitudinal section (at the bottom of the apparatus) reveals a rectangular recess (39) imprinted in the plates and intended to receive the mobile microwave orientation drawer (22) serving the latter to the times of translation guide and microwaveable envelope
This set (39 & 22) is the orientation mechanism of the microwaves, either to the boiler-lift (5> or passing through the duct (30), to the microwave oven (43)
FIG. 10 represents the apparatus of FIG. 9, which has been folded, and shows the apparatus in its mixed version, comprising the refrigerator (41), the freezer (42), and the microwave oven; wave (43), using its carcass as a functional element of refrigeration and / or heat production
FIG. 11 represents the absorber (10), whose role is to allow the poor solution (15), to mix (18> with the rich gases (9), and to absorb (10) the amoniaque (10) while rejecting hydrogen (17>
-The absorber consists of at least one "triangular absorber element", and as many triangular elements (50 & 51) as necessary superimposed and interconnected, it receives the mixture of rich gases (9) , and poor solution (15, mixed at 18) at its point of admission (53) where the solution conveyed by gravity meets the bump (13) which causes the mixing of the solution, already favoring the absorption of the ammonia and the degassing of the hydrogen, as well as a uniform diffusion of the solution on the horizontal part, (forming the base of the inverted triangle of the element) the solution there slows down its stroke and constrains to a higher density in this place promotes contact between ammonia and the water that absorbs it
-When the solution reaches the ends of the absorber triangle it is precipitated by the inclined slopes of its sides which leads to the central output of the element (49), forming the vertex of the inverted triangle
-This outlet where the floods of solution meet, increased speed by the slopes, is again a region of strong mixing of the solution, a duct evacuation of poor gases (17, hydrogen), allows the optimal degassing caused by stirring the solution coming into contact with the hump (1S) of the second absorber element (51), then following the same path as in the first element, it leaves the absorber to flow into the reservoir ( 11), where the poor gas collector (17) again allows the degassing of hydrogen
Unlike the conventional absorbers which ensure the intimate mixing by gentle slope flow along a coil, and the single point degassing taken from the tank, the absorber composed of triangular absorption elements allows degassing. in several points, so it degasses better; it promotes the intimate mixing of the ammonium solution by successive phases of strong agitation (bump 13), and slowing down applied by the flat step, which forces the solution to increase pressure with the gas, so the absorber absorbs better
The present invention makes it possible to design an appliance comprising a refrigerator, freezer, and microwave oven of the type of electrical appliance described in FIGS. 9 and 10.
-This product responds perfectly to new eating habits that are increasingly using frozen products (refrigeratorfreezer), and their rapid heating (microwave oven)
-Furthermore the small footprint of this device facilitates its insertion in small spaces (caravans, or small kitchens), and its function is silent since there are moving mechanical parts
-When the cost of manufacturing such a device, it would be a little higher than that of a traditional microwave oven, but much less than the cost of a refrigerator and a microwave made separately, because it only uses one magnetron
-The second interesting application is the manufacture of a module for producing hot water and / or cold water, which by equipping the source of microwave "heat" of a water heater producing water hot water and the microwave "refrigerating" source of an absorption refrigerator equipped with a cold-water ice-water tank, makes it possible to meet a food demand (drinks), it is sufficient to add to this module a system of concentrated syrup dosages of the "post-mix" type, and a treatment system (activated carbon filter), and carbonation (carbonator) of the water to obtain a gaseous refrigerated drinks station (orangeade) , lemon, or cola>, or non-carbonated (orange juice), and hot drinks (coffee, chocolate).

-This device meets the growing needs of the automatic distribution market
-By combining these two suggested examples we can propose a concept of fast food device radically different from those used until then, this device could allow the conservation and the restitution (hot and / or cold) of solid and liquid food products , (cooked dishes, and drinks).

-Thus this concept allows to consider through the invention the manufacture of a device (commercial or household), which powered by a single (but powerful> source of microwave, will be: refrigerator, freezer, microwave oven- waves, fountain of hot and / or cold drinks,
-This concept will find its utility in corporate restaurants, fast-food service stations, campsites, swimming pools, hospital halls,

Claims (4)

RRTEYDICATIONS  1> Absorption cycle refrigeration system, characterized by the use of microwaves as a heating mode  2> Device according to claim 1, characterized in that it comprises water as constituent element of its refrigerant solution, either as a solvent or as a refrigerant  3) Device according to claim 2, characterized by the arrangement of conduits, cavities, and recesses forming the absorption refrigeration circuit and the circuit channeling the microwaves (Figure o>, such  a cavity (5), a conduit (6), and a cavity (7), forming the  part boiler-boiler, and boiler-separator, then  a tubular condenser (8), then  a duct forming the evaporator (9>, then  a duct forming the poor gas collector (17), then  a duct forming the triangular elements of the absorber (10),  then,  a cavity forming the rich solution reservoir (11), then  a cavity forming the hermetic enclosure (39), of the drawer  microwave orientation (22), then  a conduit (30) conveying. the microwaves and then  recesses (37,32,38), ensuring thermal insulation between  certain organs of the apparatus, and facilitating its folding.  the outlet (49, 54) -The first absorber element (50) is connected to the conduit (18) supplying the refrigerant solution (en53> to the absorber, and the last absorber element (51) is connected to the reservoir (11) by the flow (54) of the rich solution -This device can consist of as many elements of absorber of identical triangular structure (50,51), superimposed andreliés between them that nécéssaire ..  from the flat part of the absorber element (base) to  their downward sloping sides (vertices) convey the solution  as well as the degassing of the inert gas towards the collector (17), likewise  (49,54), allowing the flow of the absorber element to flow out  - their vertices directed downwards are arranged of drilling  the admission of the flow into the absorber element, likewise  piercing (49,53> on the upper edge, allowing  their medias with an internal boss (13) on the lower edge, and  -their flat bases facing upwards, are imprinted  5) Device according to claim 3, characterized by the arrangement of conduits forming the elements (50 and 51) of the triangular absorber (10), (Figure 11) so that  4) Device according to claim 3, characterized in that some of the ducts, obvious, and cavities and preferably all these ducts, recesses, and cavities are made of one or more pieces or half-pieces having a longitudinal joint plane, and in that that we assemble these pieces or half-pieces by any known means  8) Device according to claims 6 and 7, characterized in that it comprises a system for orienting the microwaves (Figures 2,3> 4) from the magnetron (2), and directing them to the pipe tubes (29). and 30 '.  7) Device according to claim 2, characterized in that it is associated with a heating system of the type "microwave oven", using the same magnetron as the absorption refrigeration system  6) Device according to claim 2 characterized in that it is associated with a microwave water heating system, using the same magnetron as the absorption refrigeration system -This movable microwave orientation drawer (22), composed of metal (iron) is of rectangular section and drilled with conical or cylindrical ducts (23 and 25), along their respective axes AC and A-C ', d opposite inclinations and having their bases respectively in the axis B and B ', and are spaced from the arrival of the microwaves (in A) by a distance respectively equivalent to the between axis AB (48) and AB' .  10) Device according to any one of claims 1,2,3,6,7,8, since actérisé in that a window, composed of glasses, ceramics, or plastics passes microwaves to the inside the heating cavities such as the boiler 5 and the water heating cavity 4, and are assembled to these cavities in a sealed manner.  9) Device according to any one of claims 3,6,7,8, characterized in that it allows to channel the microwaves through a tubular metal conduit (29 and 30), rectilinear, bringing the microwaves of the magnet- one has a chosen place  -The drawer is held in central position at rest by two previously calibrated springs (24) placed at each end -This movable drawer (22) is hermetically wrapped in a sheet of metal (3, Figure 9), composed by the cavity (39 ), avoiding any leakage of microwaves -the drawer is attracted in longitudinal translation (over a distance equivalent to the axis 47 and 48), by a magnetic field generated by the solenoids (26 and 27), placed on each end and respectively slaved to the microwave demand in the tubes 29 and 30