CN114877597B

CN114877597B - Energy-saving intelligent control refrigerator

Info

Publication number: CN114877597B
Application number: CN202210650961.1A
Authority: CN
Inventors: 赵昌磊; 王森; 李言宗; 张瑞祥; 赵光谱; 王统治; 相修华; 张永军; 李庆波; 高阳; 殷善民; 张友琪
Original assignee: Qingdao Hiron Commercial Cold Chain Co Ltd
Current assignee: Qingdao Hiron Commercial Cold Chain Co Ltd
Priority date: 2022-06-10
Filing date: 2022-06-10
Publication date: 2023-03-10
Anticipated expiration: 2042-06-10
Also published as: CN114877597A

Abstract

The invention belongs to the field of intelligent control freezers, and particularly relates to an energy-saving intelligent control freezer. This energy-saving intelligent control refrigerator-freezer includes the cabinet body, freezer and refrigerating system, still includes: the refrigerator comprises a cabinet body, a rotating shaft, a swinging mechanism, a first piston assembly and a second piston assembly, wherein the cabinet body is provided with two air suction mechanisms close to an opening, each air suction mechanism comprises a shell, a plurality of air cavities are arranged in each shell, the air cavities are all communicated with an inner cavity of each shell, each shell is rotatably connected with the corresponding rotating shaft, each swinging mechanism is arranged in the corresponding inner cavity of each shell, the swinging mechanisms are fixedly connected with the corresponding rotating shafts, the air cavities are all provided with the first piston assemblies, and the first piston assemblies can introduce air in a freezing chamber into the inner cavities of the shells in a reciprocating sliding mode in the air cavities under the driving of the swinging assemblies; this energy-saving intelligent control refrigerator-freezer guarantees that the temperature everywhere in the freezer is the same, avoids frequently opening and shutting the refrigerator, causes the refrigerator to form the difference in temperature everywhere to influence freezing effect.

Description

Energy-saving intelligent control refrigerator

Technical Field

The invention belongs to the field of intelligent control refrigerators, and particularly relates to an energy-saving intelligent control refrigerator.

Background

The refrigerator is a refrigerating device which keeps constant low temperature, and is a civil product which keeps food or other articles in a constant low temperature state. The cabinet body is internally provided with a compressor, a cabinet or a box for icing of an ice maker and a storage box with a refrigerating device.

When the freezer is used in summer, the freezer needs to be frequently switched on and off, so that cold air in the freezer is easily lost, temperature difference exists in each part area in the freezer, and the freezing effect is influenced; the existing energy-saving intelligent control freezer accelerates airflow flow by arranging a fan, but the fan drainage area is small, and airflow circulation flow cannot be formed. To avoid the above technical problems, it is necessary to provide an energy-saving intelligent control refrigerator to overcome the above-mentioned drawbacks of the prior art.

Disclosure of Invention

The invention aims to provide an energy-saving intelligent control freezer, aiming at solving the problem that when the freezer is used in summer, cold air in the freezer is easy to lose due to frequent switching on and off of the freezer, so that temperature difference exists in each part area in the freezer, and the freezing effect is influenced.

The invention is realized in this way, the energy-saving intelligent control freezer, including the cabinet body, freezer and refrigerating system, the said refrigerating system is set up in the cabinet body, also include:

the refrigerator comprises a cabinet body, a freezing chamber, a rotating shaft, a swinging mechanism and a refrigerating chamber, wherein the cabinet body is provided with two air suction mechanisms close to an opening, the air inlets of the air suction mechanisms are opposite to the freezing chamber, the air suction mechanisms comprise shells, a plurality of air cavities are arranged in the shells, the air cavities are all communicated with the inner cavities of the shells, the shells are rotatably connected with the rotating shaft, the inner cavities of the shells are internally provided with the swinging mechanism, the swinging mechanism is fixedly connected with the rotating shaft, and the swinging mechanism can continuously swing under the rotating action of the rotating shaft;

the air cavities are internally provided with first piston assemblies, and the first piston assemblies can introduce air in the freezing chamber into the inner cavity of the shell in a reciprocating sliding mode in the air cavities under the driving of the swinging assemblies;

the cabinet body rotates and is connected with air outlet mechanism, air outlet mechanism can last the rotation, just the tip of shell passes through hose and air outlet mechanism intercommunication.

Further technical scheme, swing mechanism includes the bent axle, links axle, ring cover and flabellum, bent axle and pivot fixed connection, the one end and the bent axle of even axle are rotated and are connected, the other end of even axle and the interior terminal surface universal connection of shell, ring cover and even axle fixed connection, fixedly connected with connecting rod in the ring cover, the flabellum rotates with the connecting rod to be connected, just be connected with the elastic torsion spring between flabellum and the connecting rod, ring cover intercommunication has the sleeve, sliding connection has second piston assembly in the sleeve, under the drive of ring cover, second piston assembly can mix the air current in the shell through the mode of reciprocating sliding in the sleeve.

According to a further technical scheme, the second piston assembly comprises a spring, a second piston, a second one-way air inlet valve and a second one-way air outlet valve; the second piston is connected with the sleeve in a sliding mode, the second piston is connected with the inner wall of the ring sleeve through a spring, the second one-way air inlet valve is connected with the sleeve, the air inlet of the second one-way air inlet valve is arranged in the sleeve, the second one-way air outlet valve is connected with the second piston, the air outlet of the second one-way air outlet valve is opposite to the ring sleeve, and the ring sleeve is provided with a plurality of air holes.

According to a further technical scheme, the first piston assembly comprises a first piston, a first one-way air inlet valve, a first one-way air outlet valve and a push-pull rod, the first piston is connected with the inner wall of the air hole in a sliding mode, the first one-way air inlet valve is arranged at the air inlet of the air hole, the first one-way air outlet valve is fixedly connected with the first piston, the air outlet of the first one-way air outlet valve faces the inner cavity of the shell, and two ends of the push-pull rod are respectively connected with the first piston and the ring sleeve in a universal mode.

According to a further technical scheme, the air outlet mechanism comprises a vertical pipe, a spiral guide pipe and a driving assembly, the vertical pipe is rotatably connected with the cabinet body, and two ends of the vertical pipe are communicated with the hose through a rotating connector;

the spiral duct is communicated with the vertical pipe through a pipeline, the spiral duct is spirally arranged around the vertical pipe, the spiral duct and the vertical pipe are provided with a plurality of air gap holes, and the driving assembly is used for driving the vertical pipe to rotate in a reciprocating mode.

According to a further technical scheme, the driving assembly comprises a motor and a gear transmission pair, the motor is fixedly connected with the cabinet body, and an output shaft of the motor is in transmission connection with the vertical pipe through the gear transmission pair.

In a further technical scheme, a belt transmission pair is connected between the vertical pipe and the rotating shaft in a transmission manner.

Compared with the prior art, the invention has the following beneficial effects:

when the energy-saving intelligent control freezer is used, under the driving of the swinging assembly, the first piston assembly can lead air in the outer side of the freezer into the inner cavity of the shell in a reciprocating sliding mode in the air cavity; mix the gas in the cavity through swing mechanism afterwards, gas after mixing lets in air outlet mechanism department through the hose, and air outlet mechanism carries out the inboard of discharging gas dispersion to the freezer when lasting the pivoted to make the air current circulation flow of freezer, guarantee simultaneously that the temperature is the same everywhere in the freezer, avoid frequent switching refrigerator, cause the refrigerator to form the difference in temperature everywhere, thereby influence freezing effect.

Drawings

FIG. 1 is a schematic view of the structure of the present invention;

FIG. 2 is an enlarged schematic view of the area A in FIG. 1;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 2;

fig. 4 is a schematic view of the connection of the sleeve and the swing mechanism.

In the drawings: the refrigerator comprises a cabinet body 1, a freezing chamber 2, a refrigerating system 3, an air suction mechanism 4, a shell 5, a swing mechanism 6, a crankshaft 61, a connecting shaft 62, a ring sleeve 63, fan blades 64, a connecting rod 65, a first piston assembly 7, a first piston 71, a first one-way air inlet valve 72, a first one-way air outlet valve 73, a push-pull rod 74, an air outlet mechanism 8, a vertical pipe 81, a spiral guide pipe 82, a driving assembly 83, a motor 84, a gear transmission pair 85, a second piston assembly 9, a spring 91, a second piston 92, a second one-way air inlet valve 93, a second one-way air outlet valve 94, an air cavity 10, a rotating shaft 11, a sleeve 12 and a belt transmission pair 13.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

As shown in fig. 1 and fig. 2, the energy-saving intelligent control freezer provided by the present invention includes a cabinet 1, a freezing chamber 2, and a refrigeration system 3, where the refrigeration system 3 is disposed in the cabinet 1, and further includes:

the refrigerator comprises a cabinet body 1, and is characterized in that two air suction mechanisms 4 are arranged at the position close to an opening of the cabinet body 1, the air inlets of the air suction mechanisms 4 are opposite to a freezing chamber 2, each air suction mechanism 4 comprises a shell 5, a plurality of air cavities 10 are arranged in the shell 5, the air cavities 10 are communicated with the inner cavity of the shell 5, the shell 5 is rotatably connected with a rotating shaft 11, a swing mechanism 6 is arranged in the inner cavity of the shell 5, the swing mechanism 6 is fixedly connected with the rotating shaft 11, and the swing mechanism 6 can continuously swing under the rotating action of the rotating shaft 11;

the air cavities 10 are internally provided with first piston assemblies 7, and the first piston assemblies 7 can introduce air in the freezing chamber 2 into the inner cavity of the shell 5 in a reciprocating sliding mode in the air cavities 10 under the driving of the swinging assemblies 6;

the cabinet body 1 rotates and is connected with air outlet mechanism 8, air outlet mechanism 8 can continuously rotate, just the tip of shell 5 passes through the hose and communicates with air outlet mechanism 8.

When in use, under the driving of the swing assembly 6, the first piston assembly 7 can lead the air in the outer side of the freezing chamber 2 into the inner cavity of the shell 5 in a reciprocating sliding mode in the air cavity 10; mix through the gas of swing mechanism 6 in to the cavity afterwards, gas after the mixture lets in air outlet mechanism 8 department through the hose, air outlet mechanism 8 carries out the inboard of discharging freezing chamber 2 with gaseous dispersion when lasting the pivoted to make the air current circulation of freezing chamber 2 flow, guarantee simultaneously that freezing chamber 2 is the same with temperature everywhere, avoid frequent switching refrigerator, cause the refrigerator to form the difference in temperature everywhere, thereby influence the refrigeration effect.

In the embodiment of the present invention, as shown in fig. 2 and fig. 4, as a preferred embodiment of the present invention, the swing mechanism 6 includes a crankshaft 61, a connecting shaft 62, a ring 63, and blades 64;

the crankshaft 61 is fixedly connected with the rotating shaft 11, one end of the connecting shaft 62 is rotatably connected with the crankshaft 61, the other end of the connecting shaft 62 is universally connected with the inner end surface of the shell 5, the ring sleeve 63 is fixedly connected with the connecting shaft 62, the connecting rod 65 is fixedly connected in the ring sleeve 13, the fan blades 64 are rotatably connected with the connecting rod 65, an elastic torsion spring is connected between the fan blades 64 and the connecting rod 65, the ring sleeve 63 is communicated with the sleeve 12, the second piston assembly 9 is slidably connected in the sleeve 12, and under the driving of the ring sleeve 63, the second piston assembly 9 can mix air flow in the shell 5 in a reciprocating sliding mode in the sleeve 12;

the shaft 11 drives the crankshaft 61 to rotate synchronously, the crankshaft 61 drives the ring 63 to swing circumferentially through the connecting shaft 62, and the ring 63 drives the blades 64 to mix the air flow.

In the embodiment of the present invention, as shown in fig. 3, as a preferred embodiment of the present invention, the second piston assembly 9 includes a spring 91, a second piston 92, a second one-way intake valve 93, and a second one-way exhaust valve 94; the second piston 92 is connected with the sleeve 12 in a sliding manner, the second piston 92 is connected with the inner wall of the ring sleeve 63 through a spring 91, the second one-way air inlet valve 93 is connected with the sleeve 12, an air inlet of the second one-way air inlet valve 93 is arranged in the sleeve 12, the second one-way air outlet valve 94 is connected with the second piston 92, an air outlet of the second one-way air outlet valve 94 is opposite to the ring sleeve 63, and the ring sleeve 63 is provided with a plurality of air holes; when the ring 63 is oscillated circumferentially, the second piston 92 is slid in the sleeve 12 reciprocally by the inertial force and the elastic force of the spring 91, and at this time, the air flow in the housing 5 is sucked into the sleeve 12 from the second one-way air inlet valve 93 and then discharged into the ring 63 from the second one-way air outlet valve 94, and the ring 63 is oscillated circumferentially while mixing the air in the cavity of the housing 5.

In the embodiment of the present invention, as shown in fig. 2, as a preferred embodiment of the present invention, the first piston assembly 7 includes a first piston 71, a first one-way intake valve 72, a first one-way exhaust valve 73, and a push-pull rod 74;

the first piston 71 is connected with the inner wall of the air cavity 10 in a sliding manner, the air inlets of the air cavity 10 are respectively provided with a first one-way air inlet valve 72, the first one-way air outlet valve 73 is fixedly connected with the first piston 71, the air outlet of the first one-way air outlet valve 73 is opposite to the inner cavity of the shell 5, and two ends of the push-pull rod 74 are respectively connected with the first piston 71 and the ring sleeve 63 in a universal manner;

when the ring sleeve 63 is swung circumferentially, the ring sleeve 63 drives the first piston 71 to slide in the air chamber 10 in a reciprocating manner by the push-pull rod 74, and air in the outer side of the freezing chamber 2 is introduced into the air chamber 10 through the first one-way air inlet valve 72 and then introduced into the cavity of the casing 5 through the first one-way air outlet valve 73.

In the embodiment of the present invention, as shown in fig. 1, as a preferred embodiment of the present invention, the air outlet mechanism 8 includes a vertical pipe 81, a spiral duct 82 and a driving assembly 83, the vertical pipe 81 is rotatably connected with the cabinet 1, and two ends of the vertical pipe 81 are communicated with the hose through a rotating connector;

the spiral duct 82 is communicated with the vertical pipe 81 through a pipeline, the spiral duct 82 is spirally arranged around the vertical pipe 81, the spiral duct 82 and the vertical pipe 81 are both provided with a plurality of air gap holes, and the driving assembly 83 is used for driving the vertical pipe 81 to rotate in a reciprocating manner;

the driving assembly 83 continuously rotates the vertical tube 81 and the spiral duct 82, and the vertical tube 81 and the spiral duct 82 rotate while discharging the gas to the inside of the freezing chamber 2.

In the embodiment of the present invention, as shown in fig. 1, as a preferred embodiment of the present invention, the driving assembly 83 includes a motor 84 and a gear transmission pair 85, the motor 84 is fixedly connected with the cabinet 1, and an output shaft of the motor 84 is in transmission connection with the vertical pipe 81 through the gear transmission pair 85; the motor 84 drives the vertical tube 81 to rotate through the gear transmission pair 85.

In the embodiment of the present invention, as shown in fig. 1, as a preferred embodiment of the present invention, a belt transmission pair 13 is drivingly connected between the vertical tube 81 and the rotating shaft 11.

When the refrigerator is used, the crankshaft 61 is driven by the rotating shaft 11 to synchronously rotate, the crankshaft 61 drives the ring sleeve 63 to circularly swing through the connecting shaft 62, when the ring sleeve 63 circularly swings, the ring sleeve 63 drives the first piston 71 to reciprocate in the air cavity 10 through the push-pull rod 74, air in the outer side of the freezing chamber 2 is introduced into the air cavity 10 through the first one-way air inlet valve 72 and then is introduced into the cavity of the shell 5 through the first one-way air outlet valve 73, the ring sleeve 63 drives the fan blades 64 to mix the air flow, the second piston 92 reciprocates in the sleeve 12 under the action of inertia force and elastic force of the spring 91, the air flow in the shell 5 is sucked into the sleeve 12 through the second one-way air inlet valve 93 and then is discharged into the ring sleeve 63 through the second one-way air outlet valve 94, the air flow is mixed in the cavity of the shell 5 to further mix the air flow while the ring 63 circularly swings, the mixed air flow is introduced into the vertical pipe 81, the vertical pipe 81 and the spiral guide pipe 82 rotates to simultaneously circulate the air flow in the freezing chamber 2, the freezing chamber 2 to ensure that the same temperature is opened and closed, and the temperature difference of the refrigerator is avoided, and the refrigerator is frequently caused by the temperature difference.

The above description is intended to be illustrative of the preferred embodiment of the present invention and should not be taken as limiting the invention, but rather, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Furthermore, it should be understood that although the present specification describes embodiments, not every embodiment includes only a single embodiment, and such description is for clarity purposes only, and it is to be understood that all embodiments may be combined as appropriate by one of ordinary skill in the art to form other embodiments as will be apparent to those of skill in the art from the description herein.

Claims

1. Energy-saving intelligent control refrigerator-freezer, including the cabinet body, freezer and refrigerating system, refrigerating system sets up in the cabinet body, its characterized in that still includes:

2. The energy-saving intelligent control refrigerator according to claim 1, wherein the oscillating mechanism comprises a crankshaft, a connecting shaft, a ring sleeve and fan blades, the crankshaft is fixedly connected with the rotating shaft, one end of the connecting shaft is rotatably connected with the crankshaft, the other end of the connecting shaft is universally connected with an inner end face of the housing, the ring sleeve is fixedly connected with the connecting shaft, a connecting rod is fixedly connected in the ring sleeve, the fan blades are rotatably connected with the connecting rod, an elastic torsion spring is connected between the fan blades and the connecting rod, the ring sleeve is communicated with a sleeve, a second piston assembly is slidably connected in the sleeve, and the second piston assembly can mix air flow in the housing in a reciprocating sliding manner in the sleeve under the driving of the ring sleeve.

3. The energy efficient, intelligent controlled ice bin of claim 2, wherein said second piston assembly comprises a spring, a second piston, a second one-way inlet valve, and a second one-way outlet valve; the second piston is connected with the sleeve in a sliding mode, the second piston is connected with the inner wall of the ring sleeve through a spring, the second one-way air inlet valve is connected with the sleeve, the air inlet of the second one-way air inlet valve is arranged in the sleeve, the second one-way air outlet valve is connected with the second piston, the air outlet of the second one-way air outlet valve is opposite to the ring sleeve, and the ring sleeve is provided with a plurality of air holes.

4. The energy-saving intelligent control refrigerator according to claim 2, wherein the first piston assembly comprises a first piston, a first one-way air inlet valve, a first one-way air outlet valve, and a push-pull rod, the first piston is slidably connected to the inner wall of the air chamber, the air inlets of the air chamber are each provided with a first one-way air inlet valve, the first one-way air outlet valve is fixedly connected to the first piston, the air outlet of the first one-way air outlet valve faces the inner cavity of the housing, and two ends of the push-pull rod are respectively connected to the first piston and the ring sleeve in a universal manner.

5. The energy-saving intelligent control refrigerator according to claim 1, wherein the air outlet mechanism comprises a vertical pipe, a spiral duct and a driving assembly, the vertical pipe is rotatably connected with the cabinet, and two ends of the vertical pipe are communicated with the hose through a rotary connector;

the spiral guide pipe is communicated with the vertical pipe through a pipeline, the spiral guide pipe is spirally arranged around the vertical pipe, the spiral guide pipe and the vertical pipe are provided with a plurality of air gap holes, and the driving assembly is used for driving the vertical pipe to rotate in a reciprocating mode.

6. The energy-saving intelligent control ice chest according to claim 5, wherein said drive assembly comprises a motor and a gear transmission pair, said motor is fixedly connected with the chest body, and an output shaft of said motor is in transmission connection with the standpipe through the gear transmission pair.

7. The energy-saving intelligent control ice chest according to claim 5, wherein a belt transmission pair is connected between said vertical tube and said spindle.