RU2780767C1 - Refrigerating and freezing apparatus - Google Patents

Abstract

FIELD: refrigeration equipment.

SUBSTANCE: invention relates to refrigeration and freezing equipment. Apparatus comprises a casing, wherein at least one storage compartment is formed. A heating cavity is formed in one of the storage compartments. The electromagnetic heating apparatus comprises an electromagnetic wave generation module and a power supply module. The power supply box is located above the top of the casing. Heat dissipation holes are formed in the body of the power supply box. The power supply module is located in the power supply box. A heat dissipation fan is additionally located in the power supply box. A storage apparatus with a cylinder and a door is located in one of the storage compartments, and a heating cavity is formed in the storage apparatus. The electromagnetic heating apparatus additionally comprises an emitting antenna and a signal processing and measurement control circuit, located in the cylinder. The emitting antenna is electrically connected with the signal processing and measurement control circuit, and the electromagnetic wave generation module is electrically connected with the signal processing and measurement control circuit and then electrically connected with the emitting antenna.

EFFECT: electricity supply efficiency is increased, impact of moisture on the power supply unit or dusting thereof are prevented.

9 cl, 5 dwg

Description

The field of technology to which the invention belongs

The present invention relates to the field of refrigeration and freezing, and in particular to a refrigeration and freezing device.

Background of the invention

The quality of food is preserved during freezing. However, frozen foods must be reheated before being processed or eaten. In order to make it easier for users to freeze and heat food, in the prior art, food is usually heated by placing a heating device or a microwave device in a refrigerator and other refrigeration and freezing devices. However, in general, heating food with a heating device requires a long heating time, and the heating time and temperature are not easy to control, so that evaporation of moisture and loss of juice from the food is easily caused, and the quality of the food is lost. Microwave heating of foodstuffs is fast and efficient, so there is very little loss of nutritional ingredients in foodstuffs. However, due to the difference in microwave penetration of water and ice and absorption of water and ice by microwave, and uneven distribution of internal substances in food, the energy absorbed in the melted area is larger, which easily causes uneven heating and local overheating.

In order to solve the above problems, the applicant of this application has previously proposed a heating method using electromagnetic waves with a positive heating effect, but the previous electromagnetic heating device would occupy too large an area for heating, and the heat generated by the electromagnetic heating device itself is not easy to dissipate, thus affecting to the heating effect.

Brief description of the invention

One object of the present invention is to overcome at least one of the drawbacks of the prior art and to provide a refrigeration and freezing apparatus with a relatively large area for heating and a high utilization rate of the area.

Another object of the present invention is to rapidly and efficiently cool the power supply unit (power supply module) to improve the efficiency of power supply and prolong its service life.

Another object of the present invention is to prevent the power supply from being exposed to moisture or dust deposits.

In order to achieve the above objects, the present invention describes a refrigeration and freezing apparatus including

a casing in which at least one storage compartment is formed, and in one of the storage compartments a heating cavity is formed, configured to accommodate an object to be processed; and

an electromagnetic heating device configured to supply electromagnetic waves to the heating cavity to heat an object to be processed in the heating cavity, wherein the electromagnetic heating device comprises an electromagnetic wave generation module configured to generate an electromagnetic wave signal, and a power supply configured to supply a power source to module for generating electromagnetic waves, and

the power supply box is disposed above the top of the case, and heat dissipation holes configured to communicate between the inside of the power supply box and the external environment in which the power supply box is located are formed in the power supply box body; and

the power supply is located in the power supply box, the fan for heat dissipation is additionally located in the power supply box and is configured to drive the air flow to pass between the inside of the power supply box and the external environment where the power supply box is located through the heat dissipation holes to dissipate heat on the power supply.

Optionally, the power supply box includes a bottom shell located on the top surface of the case and an upper box body covering the top of the bottom shell.

The power supply and heat dissipation fan are located on the bottom shell of the bottom.

Optionally, the top body of the box includes a top wall and a peripheral wall extending downward from the periphery of the top wall; and

the heat dissipation holes include a plurality of air inlet holes formed in the first side wall of the peripheral wall and a plurality of air outlet holes formed in the second side wall of the peripheral wall opposite the first side wall to allow the passage of the driven air flow. fan to dissipate heat, into the power supply box through the air inlets and out through the air outlets, and thus forced convective heat dissipation is carried out on the power supply.

Optionally, the heat dissipation fan is located on the side of the power supply near the air outlets, and the air inlet of the heat dissipation fan faces the power supply.

Optionally, the heat dissipation fan is an axial flow fan.

Optionally, the top body of the box further includes a water retaining rib extending downward from its top wall and positioned adjacent the inside of its peripheral wall to prevent outside water from entering the power supply box.

Optionally, the water retaining fin surrounds the periphery of the power supply, and the ribbed plates of the water retaining fin against the first side wall and the second side wall comprise through holes, respectively, to allow air flow through them.

Optionally, the power supply includes a printed circuit board (PCB) configured to include power supply processing circuits. The printed circuit board contains an input terminal configured to be connected to a power source and an output terminal configured to be connected to an electromagnetic wave generation module. Therefore, the input power voltage input by the input terminal is processed by the power supply processing circuit on the printed circuit board, and then output by the output terminal to the electromagnetic wave generation unit.

Optionally, a storage device with a cylinder and a door is placed in one of the storage compartments, and a heating cavity is formed in the storage device.

The electromagnetic heating device further includes a radiating antenna and a signal processing and measurement control circuit, which are located in the cylinder. The radiating antenna is electrically connected to the signal processing and measurement control circuit, and the electromagnetic wave generation unit is electrically connected to the signal processing and measurement control circuit through a wire located in the foaming layer of the casing, and then electrically connected to the radiating antenna.

Optionally, the electromagnetic wave generation module is located on the outer side of the foaming layer of the casing, and the electromagnetic wave generation module is electrically connected to the signal processing and measurement control circuit through a wire located in the foaming layer of the casing.

The refrigeration and freezing device of the present invention includes an electromagnetic heating device that uses electromagnetic waves to heat and defrost an object to be processed, and so on. The heating efficiency is high, the heating is uniform, and the food quality can be guaranteed. In particular, the power supply unit, configured to supply power to the electromagnetic wave generation module, is located in the power supply box above the casing, that is, the power supply unit is located on the outside of the casing and does not occupy the storage area in the casing and the heating area in the heating cavity. . Both the storage area and the heating area are relatively large, and the utilization rate of the areas is high.

However, due to the fact that the power supply is located at the top on the outside of the case, the heat generated by the power supply will not be dissipated in the case and affect the storage temperature in the storage compartments. More importantly, the heat dissipation holes are located in the body of the power supply box, the heat dissipation fan is additionally located in the power supply box, and the airflow can be driven by the heat dissipation fan to pass through to help dissipate the heat generated by the power supply, into the space of the external environment. Therefore, the power supply is cooled quickly and efficiently, the decrease in service life and efficiency caused by the temperature increase during continuous operation of the power supply is completely eliminated, and, at the same time, the risk of burns caused by unintentional touch of users is completely eliminated.

In addition, the power supply is located in a relatively closed power supply box, which can prevent splashing of water on the power supply or deposit of dust and the like to a certain extent. The water retaining rib is specially formed in the power supply box, and the water retaining fin is located on the inside of the peripheral wall of the upper case of the box, so that the water in the upper case can be prevented from entering the power supply box, causing moisture or dust to be deposited on the power supply and even causing unnecessary potential security hazards.

The above, as well as other objects, advantages and features of the present invention will be better understood by experts in this field in accordance with the following detailed description of specific embodiments of the present invention in conjunction with the accompanying drawings.

Brief description of the drawings

In the following part, some specific embodiments of the present invention will be described in detail with reference to the accompanying drawings by way of example and not limitation. The same reference numbers in the accompanying drawings designate the same or similar elements or parts. Those skilled in the art will appreciate that these accompanying drawings are not necessarily drawn to scale. On the accompanying drawings

1 is a schematic structural diagram of a refrigeration and freezing apparatus according to an embodiment of the present invention;

2 is a schematic sectional view of a refrigeration and freezing apparatus according to an embodiment of the present invention;

3 and 4 are schematic sectional views of a structure in a power supply box in different directions in accordance with an embodiment of the present invention;

Fig. 5 is a schematic structural diagram of the lower shell of the lower part of the power supply box according to an embodiment of the present invention.

Detailed description of the invention

The present invention describes a refrigeration and freezing device, which may be a refrigerator, freezer, or other storage devices with refrigeration and/or freezing functions. Fig. 1 is a schematic structural diagram of a refrigeration and freezing apparatus according to an embodiment of the present invention, and Fig. 2 is a schematic sectional view of a refrigeration and freezing apparatus according to an embodiment of the present invention.

As shown in FIGS. 1-2, the refrigerator and freezer 1 of the present invention includes a case 10. At least one storage compartment 11 is formed in the case 10. In addition, the refrigerator and freezer 1 may also include a door for opening and/or closing the storage compartments 11. A heating cavity configured to accommodate an object to be processed is formed in one of the storage compartments 11 . The heating cavity can heat and defrost an object to be processed, etc. In particular, a plurality of storage compartments 11 may be formed in the case 10, which may include, for example, a refrigerator compartment, a freezer compartment, and a variable temperature compartment. The temperatures in the aforementioned compartments are different from each other and hence the functions are different. The heating cavity may be formed in any of a refrigerator compartment, a freezer compartment, and a variable temperature compartment.

In addition, the refrigeration and freezing device 1 further includes an electromagnetic heating device configured to supply electromagnetic waves to the heating cavity to heat an object to be processed in the heating cavity. The electromagnetic waves generated by the electromagnetic heating device may be electromagnetic waves with a suitable wavelength, such as radio frequency waves, microwaves, and the like. The method of using electromagnetic waves to heat the object to be processed ensures high heating efficiency and uniform heating, and can guarantee food quality. The electromagnetic heating device generally includes an electromagnetic wave generation module 21 configured to generate an electromagnetic wave signal and a power supply 24 configured to supply a power source to the electromagnetic wave generation module 21 . Since both the electromagnetic wave generation unit 21 and the power supply unit 24 have a relatively large power and generate more heat, therefore, the electromagnetic wave generation unit 21 and the power supply unit 24 can be located on the outer side of the foaming layer of the casing 10, so that the storage medium in case 10 is prevented from being influenced, and at the same time, heat dissipation is ensured. The electromagnetic wave generating unit 21 may be located, for example, outside the upper part of the casing 10, outside the rear part of the casing, or inside the compressor room 19 and the like.

In particular, the power supply box 40 is located above the top of the case 10. Heat dissipation holes configured to allow communication between the inside of the power supply box 40 and the external environment in which the power supply box 40 is located are formed in the body of the power supply box 40. . The power supply box 24 is located in the power supply box 40, and the heat dissipating fan 31 is further located in the power supply box 40 and configured to drive the air flow to pass between the inside of the power supply box 40 and the external environment in which the power supply box 40 power supply is located, through the above-mentioned heat dissipation holes for heat dissipation on the power supply 24.

The power supply 24, configured to supply power to the electromagnetic wave generating unit 21, is located in the power supply box 40 above the case 10. That is, the power supply 24 is located on the outside of the case 10 and does not occupy a storage area in the case 10 and heating in the heating cavity. Both the storage area and the heating area are relatively large, and the utilization rate of the areas is high.

Meanwhile, since the power supply 24 is disposed at the top outside of the case 10, the heat generated by the power supply will not be dissipated in the case 10 and affect the storage temperature in the storage compartments. More importantly, the heat dissipation holes are located in the body of the power supply box 40, the heat dissipation fan 31 is further located in the power supply box 40. The heat dissipation fan 31 can drive the airflow to pass through more quickly and help dissipate the heat generated by the power supply to the outside environment more quickly. Accordingly, the power supply 24 is cooled quickly and efficiently, the decrease in service life and efficiency caused by the temperature rise during continuous operation of the power supply 24 is completely eliminated, and the risk of burns caused by inadvertent touching of users is completely eliminated.

3 and 4 are schematic sectional views of a structure in a power supply box in different directions in accordance with an embodiment of the present invention. The cut lines in figures 3 and 4 are perpendicular to each other. As shown in FIGS. 1-4, the power supply box 40 includes a bottom bottom shell 41 located on the top surface of the case 10, and an upper box body 42 covering the top of the bottom bottom shell 41. Both the power supply 24 and the heat dissipating fan 31 are disposed on the bottom shell 41 of the bottom. That is, the power supply 24 and the heat dissipating fan 31 are supported on the bottom shell 41 of the bottom. The top case 42 of the box covers the power supply 24, the heat dissipation fan 31, and the bottom shell 41 of the lower part from top to bottom.

In some embodiments, the box top body 42 includes a top wall 421 and a peripheral wall 422 extending downward from the periphery of the top wall 421. The top wall 421 may protrude upwardly from the top surface 10a of the casing 10, that is, the top wall 421 is higher than the top surface 10a. case 10, which not only does not take up space, but can also dissipate heat well. The heat dissipation holes mentioned above include a plurality of air inlet holes 43 formed in the first side wall of the peripheral wall 422, and a plurality of air outlet holes 44 formed in the second side wall of the peripheral wall 422 opposite the first side wall, for allowing the airflow driven by the heat dissipation fan 31 to pass into the power box 40 through the air inlets 43 and out through the air outlets 44, and thus forced convective heat dissipation is performed on the power box 24. That is, the air inlet holes 43 and the air outlet holes 44 can be located on two opposite side walls of the upper case 42 of the box to provide airflow forming a convection effect, so that the speed of the airflow is increased and the efficiency of dissipating heat from the power supply 24 additionally increased.

In some embodiments, a heat dissipating fan 31 may be located on the side of the power supply 24 near the air outlets 44. The air inlet of the heat dissipating fan 31 faces the power box 24 to promote faster airflow into the power box 40 from the air inlets 43 and out faster from the air outlets 44, thereby increasing the airflow rate. .

Further, the heat dissipating fan 31 may be an axial flow fan. In some other embodiments, the heat dissipation fan 31 may alternatively be other types of fan such as a centrifugal fan, crossflow fan, and the like, as long as the heat dissipation fan air passage in the power supply box 40 positioned correctly and its air outlet faces the power supply 24.

In addition, one, two, three or more heat dissipating fans 31 are provided.

In some embodiments, the box top body 42 further includes a water retention rib 45 extending downward from its top wall and adjacent on the inside of its peripheral wall to prevent outside water from entering the power supply box 40. By positioning the power supply box 40 itself, the power supply 24 can be protected to a certain extent from splashing water or adhering dust and the like. The water retaining rib 45 is specially formed in the power supply box 40, and the water retaining rib 45 is disposed on the inside of the peripheral wall of the upper case 42 of the box, so that water in the upper part of the case 10 can be prevented from passing into the housing area 14, causing moisture or dust deposition on the power supply 24, and even causing unnecessary potential safety hazards. Specifically, the water retaining rib 45 may extend downward to abut against the bottom wall of the bottom shell 41 of the lower part to provide better water tightness.

In some embodiments, the implementation of the rib 45 to retain water surrounds the periphery of the block 24 of the power supply. That is, the water retaining rib 45 has four ribbed plates connected in series to prevent water from entering the power supply 24 from either side. Through holes 451 are formed in the ribbed plates of the water retaining fin 45 against the first side wall and the second side wall of the peripheral wall 422, respectively, to allow air flow through them, so that it is ensured that the location of the water retaining fin 45 does not affect the normal passage. air flow.

Fig. 5 is a schematic structural diagram of the lower shell of the lower part of the power supply box according to an embodiment of the present invention. As shown in FIG. 5, the power supply 24 may include a circuit board 241 configured to include a power supply processing circuit. The printed circuit board 241 includes an input terminal 242 configured to be connected to a power source and an output terminal 243 configured to be connected to the electromagnetic wave generation unit 21 . Therefore, the supply voltage inputted by the input terminal 242 is processed by the power supply processing circuit on the printed circuit board 241, and then outputted by the output terminal 243 to the electromagnetic wave generation unit 21. Specifically, the input terminal 242 and the output terminal 243 may be located at two opposite ends of the circuit board 241, respectively.

In some embodiments, a storage device 60 with a cylinder 61 and a door 62 is located in one of the storage compartments 11 . In the storage device 60, a heating cavity is formed. During processing by heating, the door 62 closes the cylinder 61 so that a closed heating cavity is formed and electromagnetic waves are prevented from leaking out.

In addition, the electromagnetic heating device further includes a radiant antenna 22 and a signal processing and measurement control circuit 23, which are located in the cylinder 61. The radiant antenna 22 is electrically connected to the signal processing and measurement control circuit 23. The electromagnetic wave generation unit 21 is electrically connected to the signal processing and measurement control circuit, and then electrically connected to the radiating antenna 22.

In addition, the electromagnetic wave generation module 21 may be disposed on the outer side of the foam layer of the case 10. The electromagnetic wave generation module 21 may be electrically connected to the signal processing and measurement control circuit 23 via a wire 50 disposed in the foam layer of the case 10. Specifically, the module 21 generation of electromagnetic waves can be located in the compressor compartment 19. The module 21 generation of electromagnetic waves and the power supply 24 are connected through an electrical wire located in the foaming layer of the casing 10.

Specifically, the signal processing and measurement control circuit 23 includes a first RF port 231 and a first signal transmission interface 232 that are led out from the rear wall of the storage device 60 . The electromagnetic wave generation module 21 includes a second RF port and a second signal transmission interface. The first RF port 231 is connected to the second RF port via an RF cable located in the foam layer of the housing 10, and the first signal transmission interface 232 is connected to the second signal transmission interface via a signal transmission cable located in the foam layer of the housing 10.

Cylinder 61 may include a loading and stowage opening for loading and stowage of objects. Door 62 may include an electrically conductive end plate. When the door 62 is closed, the end plate closes the opening for loading and accommodating the cylinder 61, thus closing the heating cavity in the cylinder 61. The end plate may be a metal end plate made of a conductive metal material, or may be a conductive end plate made of other conductive materials. Door 62 further includes at least one conductive connector electrically connected to the end plate. The conductive connector is configured to electrically connect to the cylinder 61 at least when the door 62 is in the closed position, covering the opening for loading and accommodating the cylinder 61 so that the cylinder 61 and the door 62 form a continuously conductive shield when the door 62 is in the closed position. position. Therefore, it can be ensured that a stable electrical connection is formed between the cylinder 61 and the door 62, so that a continuously conductive shield is formed during heating, electromagnetic waves are prevented from being emitted through the gap, electromagnetic radiation is effectively shielded, and electromagnetic radiation damage to the human body is prevented. The cylinder 61 may be a metal cylinder or a non-metal cylinder containing electromagnetic shielding elements such as a conductive coating, a conductive metal mesh, and the like.

Those skilled in the art will understand that, unless otherwise indicated, terms such as "top", "bottom", "inner", "outer", "side", "front", "rear", etc. used to describe the orientation or position in the embodiments of the present invention are based on the practical use of the refrigeration and freezing device 1. These terms are used only to provide a description and understanding of the technical solution of the present invention, and not to indicate or imply that the said device or elements must have a specific orientation. Therefore, such terms cannot be construed as limiting the present invention.

However, those skilled in the art should understand that while many embodiments of the present invention have been shown and described in detail herein without departing from the spirit and scope of the present invention, many other changes or modifications that are consistent with the principles of the present invention are still can be directly determined or derived from the content disclosed in the present invention. Therefore, the scope of the present invention should be understood and recognized as covering all these other changes or modifications.

Claims (9)

1. A refrigeration and freezing device, comprising: a casing in which at least one storage compartment is formed, and in one of the storage compartments a heating cavity is formed, configured to accommodate an object to be processed; and an electromagnetic heating device configured to supply electromagnetic waves to the heating cavity to heat an object to be processed in the heating cavity, wherein the electromagnetic heating device comprises an electromagnetic wave generation module configured to generate an electromagnetic wave signal, and a power supply module configured to supply power source to the electromagnetic wave generation module, wherein the power supply box is located above the upper part of the casing, and heat dissipation holes configured to provide communication between the inside of the power supply box and the external environment in which the power supply box is located are formed in the box body power supply; the power supply module is located in the power supply box, the heat dissipation fan is further located in the power supply box and is configured to drive the air flow to pass between the inside of the power supply box and the external environment in which the power supply box is located through the holes for heat dissipation to dissipate heat on the power supply module; a storage device with a cylinder and a door is located in one of the storage compartments, and a heating cavity is formed in the storage device; and the electromagnetic heating device further comprises a radiating antenna and a signal processing and measurement control circuit, which are located in the cylinder, wherein the radiating antenna is electrically connected to the signal processing and measurement control circuit, and the electromagnetic wave generation module is electrically connected to the signal processing and measurement control circuit, and then electrically connected to the radiating antenna. 2. Refrigerator and freezer according to claim 1, in which the power supply box contains the lower shell of the lower part, located on the upper surface of the casing, and the upper body of the box covering the upper part of the lower shell of the lower part; and the power supply module and heat dissipation fan are located on the bottom shell of the bottom. 3. Refrigeration and freezing device according to claim 2, in which the upper body of the box includes a top wall and a peripheral wall extending downward from the periphery of the upper wall; and the heat dissipation holes include a plurality of air inlet holes formed in the first side wall of the peripheral wall and a plurality of air outlet holes formed in the second side wall of the peripheral wall opposite the first side wall to allow the air flow driven by the fan to pass through. for heat dissipation, into the power supply box through the air inlets and out through the air outlets, and thus forced convective heat dissipation is carried out on the power supply. 4. The refrigerator and freezer according to claim 3, wherein the heat dissipation fan is located on the side of the power supply module near the air outlets, and the air inlet of the heat dissipation fan faces the power supply module. 5. The refrigeration and freezing apparatus according to claim 4, wherein the heat dissipating fan is an axial flow fan. 6. The refrigeration and freezing apparatus of claim 3, wherein the upper body of the box further comprises a water retaining rib extending downward from its upper wall and adjacent on the inside of its peripheral wall to prevent outside water from entering the power supply box. 7. The refrigeration and freezing apparatus according to claim 6, wherein the water retaining fin surrounds the periphery of the power supply module, and the ribbed plates of the water retaining fin opposite the first side wall and the second side wall comprise through holes, respectively, to allow air flow through them. 8. The refrigerator and freezer according to claim 1, wherein the power supply includes a printed circuit board (PCB) configured to include power supply processing circuits, the printed circuit board includes an input terminal configured to connect to a power source, and an output terminal connected to the electromagnetic wave generation unit, and therefore the input supply voltage at the input terminal is processed by the power supply processing circuit on the circuit board, and then output through the output terminal to the electromagnetic wave generation unit. 9. The refrigeration and freezing apparatus according to claim 1, wherein the electromagnetic wave generation module is located on the outer side of the foaming layer of the casing, and the electromagnetic wave generation module is electrically connected to the signal processing and measurement control circuit through a wire located in the foaming layer of the casing.

Images