CN219550591U - Cold air structure and integrated kitchen - Google Patents

Abstract

The utility model relates to a cold air structure and an integrated kitchen, wherein the cold air structure comprises a mounting seat, a mounting hole is formed in the top of the mounting seat, and a containing box is arranged in the mounting hole and used for containing a low-temperature medium; a fan is arranged in the mounting seat, and is communicated with the inside of the accommodating box and supplies air to the accommodating box; an air outlet is formed in the front side surface of the mounting seat, and an air deflector assembly is rotationally connected to the air outlet; an air duct is arranged in the mounting seat, two ends of the air duct are respectively provided with a front air duct opening and a rear air duct opening, the rear air duct opening is communicated with the inside of the accommodating box, and the front air duct opening is communicated with the air outlet. According to the utility model, the accommodating box capable of internally accommodating ice cubes, ice water and other low-temperature mediums is arranged, the fan is arranged to generate air flow, the air flow is cooled by the low-temperature mediums in the accommodating box to form cold air, and the cold air is blown out to the outside after passing through the air duct and the air deflector assembly, so that the cooking environment temperature is reduced, the use experience of a user is improved, and the cold air structure is small in size and simple in structure and can be applied to kitchen equipment such as a range hood, an integrated kitchen range and the like.

Description

Cold air structure and integrated kitchen

Technical Field

The utility model relates to the technical field of kitchen appliances, in particular to a cold air structure and an integrated kitchen range.

Background

The integrated kitchen range is multifunctional and integrated kitchen equipment, and usually integrates a range hood, a gas stove and other functional modules, such as a disinfection cabinet, a storage cabinet and the like. The integrated kitchen has the advantage of good oil smoke suction effect, and also has the advantage of saving kitchen space due to the high integration of the functional modules, so that the integrated kitchen is widely welcomed by families and is particularly suitable for kitchens with smaller space.

The overall ambient temperature rise in the kitchen results in a very poor cooking experience for the person due to the large amount of heat generated during cooking, especially in summer months where the ambient temperature itself is high. It is not practical for most households to install additional refrigeration equipment such as air conditioning in a kitchen where the space itself is small.

Disclosure of Invention

In view of the above, the present utility model provides a cold air structure and an integrated stove, which are used for solving the problem that the cooking experience of a person is poor due to the fact that the overall environmental temperature in a kitchen is increased by heat generated in a cooking process in the related art.

In order to achieve one or a part or all of the above objects or other objects, the present utility model provides a cold air structure, which comprises a mounting seat, wherein a mounting hole is formed in the top of the mounting seat, and a containing box is arranged in the mounting hole and is used for containing a low-temperature medium;

a fan is arranged in the mounting seat, and is communicated with the inside of the accommodating box and supplies air to the accommodating box;

an air outlet is formed in the front side surface of the mounting seat, and a rotatable air deflector assembly is rotatably arranged at the air outlet;

the mounting seat is internally provided with an air duct, two ends of the air duct are respectively provided with a front air duct opening and a rear air duct opening, the rear air duct opening is communicated with the inside of the accommodating box, and the front air duct opening is communicated with the air outlet.

In an alternative embodiment, the accommodating box comprises a lower box body and an upper cover, the lower box body is arranged in the mounting hole, and the upper cover is covered with the lower box body;

the front end face of the lower box body is provided with a plurality of front through holes, the front through holes are communicated with the rear air duct opening, the rear end face of the lower box body is provided with a plurality of rear through holes, and the rear through holes are communicated with the fan.

In an alternative embodiment, the air deflection assembly includes an air deflection and an electric motor;

the motor is fixedly arranged on the mounting seat, and is connected with and controls the air deflector to rotate;

the air guide plate is rotationally connected to the air outlet, at least one ventilation opening is formed in the air guide plate, and when the air guide plate rotates to a preset angle, the ventilation opening is communicated with the rear air channel opening.

In an optional embodiment, the air deflector comprises two baffle bodies arranged in parallel, a plurality of air guide sheets are arranged between the two baffle bodies at intervals, two ends of each air guide sheet are respectively connected with the two baffle bodies, and a gap between two adjacent air guide sheets is the ventilation opening.

In an alternative embodiment, a blocking groove is formed in the upper edge of the front air duct opening, and when the air deflector rotates to a preset position, one of the two baffle bodies is abutted to the blocking groove.

In an alternative embodiment, a first fixing plate and a second fixing plate are fixedly arranged in the mounting seat;

the two ends of the air deflector are respectively provided with a first rotating shaft and a second rotating shaft;

the motor is fixedly connected to the first fixed plate, and the motor is connected with and controls the first rotating shaft to rotate;

the second rotating shaft is rotatably connected to the second fixing plate.

In an alternative embodiment, the first fixed plate is provided with a first micro switch, and the second fixed plate is provided with a second micro switch;

a first poking piece is arranged on the first rotating shaft, and rotates synchronously with the first rotating shaft, and the first poking piece is used for triggering a first micro switch;

the second rotating shaft is provided with a second poking piece, the second poking piece and the second rotating shaft synchronously rotate, and the second poking piece is used for triggering a second micro switch.

In an optional embodiment, a first clamping spring is clamped on the first rotating shaft, and the first clamping spring and the first fixing plate are respectively positioned at two ends of the first plectrum and used for propping against the first plectrum to carry out axial limiting;

the second rotating shaft is provided with a second clamping spring, and the second clamping spring and the second fixing plate are respectively positioned at two ends of the second plectrum and used for propping against the second plectrum to carry out axial limiting.

In an alternative embodiment, the fan is a through-flow fan, a plurality of air inlet holes are formed in the outer surface of the mounting seat, and the air inlet holes are communicated with the fan.

The utility model also provides an integrated kitchen, which comprises a main body, a machine head arranged on the main body, and a cold air structure, wherein the cold air structure is arranged at the top of the machine head.

The implementation of the embodiment of the utility model has the following beneficial effects:

according to the utility model, the accommodating box capable of accommodating ice cubes, ice water and other low-temperature mediums is arranged, the fan is arranged to generate air flow, the air flow is cooled by the low-temperature mediums in the accommodating box to form cold air, and the cold air is blown out to the outside after passing through the air duct and the air deflector assembly, so that the cooking environment temperature is reduced, and the use experience of a user is improved. In addition, the cold air structure has small volume and simple structure, can be installed and applied to kitchen equipment such as a range hood, an integrated kitchen range and the like, and has wide application range.

The problem of the heat that the cooking process produced in the correlation technique makes the whole environment temperature rise in the kitchen lead to the people's culinary art experience poor is solved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the related art, the drawings that are required to be used in the embodiments or the related technical descriptions will be briefly described, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the drawings without inventive effort for those skilled in the art.

Wherein:

FIG. 1 is a perspective view of an integrated cooktop according to an alternative embodiment of the present utility model;

FIG. 2 is an exploded view of an alternative embodiment of an integrated cooktop according to this utility model;

FIG. 3 is a perspective view of a cold air structure according to an alternative embodiment of the present utility model;

FIG. 4 is a cross-sectional view of an alternative embodiment of the present utility model showing a cool air structure in an open and closed state;

FIG. 5 is an exploded view of the housing box in an alternative embodiment of the present utility model;

fig. 6 is an exploded view of an air deflection assembly in an alternative embodiment of the present utility model.

The reference numerals are explained as follows: 1-a mounting base; 11-mounting holes; 12-an air inlet hole; 13-an air outlet; 2-a fan; 3-a housing box; 31-lower box body; 311-front through hole; 312-rear through holes; 32-an upper cover; 4-an air duct; 41-front air duct opening; 411-catch groove; 42-a rear air duct port; 5-an air deflector assembly; 51-air deflectors; 511-vents; 512-baffle body; 513-wind guiding sheets; 514-a first spindle; 515-a second axis of rotation; 52-an electric motor; 61-a first microswitch; 62-a second microswitch; 71-a first plectrum; 72-a second plectrum; 81-a first clamp spring; 82-a second clamp spring; 91-a first fixing plate; 92-a second fixing plate; 01-a main body; 02-a handpiece; 021-fume inlet.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 to 4, a cold air structure according to an embodiment of the utility model includes a mounting base 1, a mounting hole 11 is formed at the top of the mounting base 1, a containing box 3 is disposed in the mounting hole 11, and the containing box 3 is used for containing a low-temperature medium. The low-temperature medium can be ice cubes, ice water or the like, and is used for cooling the wind flow passing through the accommodating box 3.

The inside fan 2 that is provided with of mount pad 1, fan 2 and the inside intercommunication of holding box 3 and supply air to holding box 3, air outlet 13 has been seted up to mount pad 1 leading flank, and air outlet 13 department is provided with rotatable aviation baffle subassembly 5. The air deflector assembly 5 is used for guiding air flow and controlling the air outlet direction at the air outlet 13.

An air duct 4 is arranged in the mounting seat 1, two ends of the air duct 4 are respectively provided with a front air duct opening 41 and a rear air duct opening 42, the rear air duct opening 42 is communicated with the inside of the accommodating box 3, and the front air duct opening 41 is communicated with the air outlet 13.

When the kitchen ventilator is used, a user can place low-temperature media such as ice cubes in the accommodating box 3, the fan 2 works to generate air flow, the air flow enters the accommodating box 3 and is cooled by the low-temperature media to form cold air, the cold air sequentially passes through the air duct 4 and the air deflector assembly 5 and is blown out to the outside, so that the cooking environment temperature of a kitchen can be effectively reduced, and the user experience is improved. The problems that the cooking experience of people is poor and the air conditioner is unrealistic to install in a kitchen due to the fact that the overall environmental temperature in the kitchen is increased due to heat generated in the cooking process in the related technology are solved.

Meanwhile, the blowing direction of cold air can be controlled by controlling the rotation angle of the air deflector assembly 5 so as to meet the cooking environments with different heights and the demands of users.

In addition, the cold air structure of the utility model has small volume and simple structure, can be applied to kitchen equipment such as a range hood or an integrated kitchen range, and has wide application range.

Optionally, the accommodating box 3 is detachably arranged in the mounting seat 1, so that a user can conveniently take out and place a low-temperature medium or clean the low-temperature medium.

In an alternative embodiment, as shown in fig. 5, the accommodating case 3 includes a lower case 31 and an upper cover 32, the lower case 31 is disposed in the mounting hole 11, and the upper cover 32 is covered with the lower case 31. The front end face of the lower box body 31 is provided with a plurality of front through holes 311, the front through holes 311 are communicated with the rear air duct opening 42, the rear end face of the lower box body 31 is provided with a plurality of rear through holes 312, and the rear through holes 312 are communicated with the fan 2. In this way, the wind flow generated by the fan 2 can smoothly enter the accommodating box 3 through the rear through hole 312 and then is blown to the air deflector assembly 5 through the front through hole 311.

Referring to fig. 2 and 6 in combination, in an alternative embodiment, the air deflection assembly 5 includes an air deflection 51 and an electric motor 52. The motor 52 is fixedly arranged on the mounting seat 1, and the motor 52 is connected with and controls the air deflector 51 to rotate. The air deflector 51 is rotatably connected to the air outlet 13, and at least one ventilation opening 511 is provided on the air deflector 51, and when the air deflector 51 rotates to a preset angle, the ventilation opening 511 is communicated with the rear air duct opening 42.

As shown in the top of fig. 4, when the cold air blowing operation is performed, the motor 52 controls the air deflector 51 to rotate in the forward and reverse directions to different angles, that is, controls the air vent 511 to rotate to different angles, so as to guide the air flow. As shown at the bottom in fig. 4, at the end of the operation, the air deflector 51 rotates until covering the air outlet 13 for dust blocking.

For example, the air deflector 51 includes two parallel baffle bodies 512, a plurality of air guiding sheets 513 are arranged between the two baffle bodies 512 at intervals, two ends of each air guiding sheet 513 are respectively connected with the two baffle bodies 512, and a gap between two adjacent air guiding sheets 513 is a ventilation opening 511. The air guiding sheets 513 and the two baffle plates 512 are matched to intensively guide the air generated by the fan 2 to the air outlet 13, so that the air outlet is more concentrated.

Alternatively, as shown in fig. 2 and 4, the upper edge of the front air duct opening 41 is provided with a blocking slot 411, and when the air deflector 51 rotates to a preset position, one of the two baffle bodies 512 abuts against the blocking slot 411. The baffle body 512 is abutted with the baffle slot 411 and can be used for circumferentially limiting the air deflector 51, so that the cold air structure is more stable and reliable. In addition, when the air deflector 51 rotates to an angle where the baffle plate 512 abuts against the baffle slot 411, air flow is prevented from leaking out from the gap between the baffle plate 512 and the baffle plate 512, and the cooling effect is improved.

As shown at the top in fig. 4, in an alternative embodiment, a first fixing plate 91 and a second fixing plate 92 are fixedly provided in the mount 1. The two ends of the air deflector 51 are respectively provided with a first rotating shaft 514 and a second rotating shaft 515. The motor 52 is fixedly coupled to the first fixing plate 91, and the motor 52 is coupled to and controls the rotation of the first shaft 514. The second rotation shaft 515 is rotatably coupled to the second fixing plate 92.

The first fixing plate 91 is used for fixing the motor 52 on the mounting seat 1, and simultaneously provides support for one end of the air deflector 51, and the second fixing plate 92 is used for providing support for the other end of the air deflector 51.

Optionally, the first fixing plate 91 is provided with a first micro switch 61, and the second fixing plate 92 is provided with a second micro switch 62. The first rotating shaft 514 is provided with a first pulling piece 71, the first pulling piece 71 rotates synchronously with the first rotating shaft 514, and the first pulling piece 71 is used for triggering the first micro switch 61. The second rotating shaft 515 is provided with a second pulling piece 72, the second pulling piece 72 rotates synchronously with the second rotating shaft 515, and the second pulling piece 72 is used for triggering the second micro switch 62.

The first micro switch 61 is matched with the first shifting piece 71, and the second micro switch 62 is matched with the second shifting piece 72, so that two rotation angles of the air deflector 51 can be monitored respectively. For example, when the air deflector 51 is closed in place, the first paddle 71 triggers the first micro switch 61 so that the motor 52 stops rotating, and when the air deflector 51 is opened in place, the second paddle 72 triggers the second micro switch 62 so that the motor 52 stops rotating.

Optionally, the first rotating shaft 514 is clamped with a first clamping spring 81, and the first clamping spring 81 and the first fixing plate 91 are respectively located at two ends of the first plectrum 71 and used for propping against the first plectrum 71 to perform axial limiting; the second rotating shaft 515 is provided with a second clamping spring 82, and the second clamping spring 82 and the second fixing plate 92 are respectively positioned at two ends of the second shifting piece 72 and used for propping against the second shifting piece 72 to carry out axial limiting.

Optionally, the fan 2 is a cross-flow fan, the outer surface of the mounting seat 1 is provided with a plurality of air inlet holes 12, and the air inlet holes 12 are communicated with the fan 2. The cross flow fan radially outputs air, namely, the air can be discharged to the accommodating box 3 at the front side.

Referring to fig. 1 and 2 in combination, an integrated stove according to an embodiment of the present utility model includes a main body 01, a machine head 02 disposed on the main body 01, and any one of the above cold air structures disposed on top of the machine head 02.

The main body 01 is internally provided with a smoke exhausting negative pressure device, the front side of the machine head 02 is provided with a smoke inlet 021, and smoke generated in cooking is pumped to the smoke exhausting negative pressure device after entering from the smoke inlet 021 and then discharged to the outside.

The cold air structure at the top of the machine head 02 can be used for discharging cold air on one hand and can be used as a smoke collecting plate on the other hand to resist rising smoke, so that the smoke is conveniently pumped into the smoke inlet 021.

The present utility model is not limited to the above-mentioned embodiments, but is not limited to the above-mentioned embodiments, and any person skilled in the art can make some changes or modifications to the above-mentioned embodiments without departing from the scope of the present utility model.

Claims (10)

1. A cold air structure, its characterized in that: the low-temperature medium storage device comprises a mounting seat (1), wherein a mounting hole (11) is formed in the top of the mounting seat (1), a storage box (3) is arranged in the mounting hole (11), and the storage box (3) is used for storing low-temperature mediums;

a fan (2) is arranged in the mounting seat (1), and the fan (2) is communicated with the inside of the accommodating box (3) and supplies air to the accommodating box (3);

an air outlet (13) is formed in the front side surface of the mounting seat (1), and a rotatable air deflector assembly (5) is arranged at the air outlet (13);

the air duct type air conditioner is characterized in that an air duct (4) is arranged in the mounting seat (1), two ends of the air duct (4) are respectively provided with a front air duct opening (41) and a rear air duct opening (42), the rear air duct opening (42) is communicated with the inside of the accommodating box (3), and the front air duct opening (41) is communicated with the air outlet (13).

2. The cool air structure as claimed in claim 1, wherein: the accommodating box (3) comprises a lower box body (31) and an upper cover (32), the lower box body (31) is arranged in the mounting hole (11), and the upper cover (32) is covered with the lower box body (31);

the front end face of the lower box body (31) is provided with a plurality of front through holes (311), the front through holes (311) are communicated with the rear air duct opening (42), the rear end face of the lower box body (31) is provided with a plurality of rear through holes (312), and the rear through holes (312) are communicated with the fan (2).

3. The cool air structure as claimed in claim 1, wherein: the air deflector assembly (5) comprises an air deflector (51) and a motor (52);

the motor (52) is fixedly arranged on the mounting seat (1), and the motor (52) is connected with and controls the air deflector (51) to rotate;

the air deflector (51) is rotationally connected to the air outlet (13), at least one ventilation opening (511) is formed in the air deflector (51), and when the air deflector (51) rotates to a preset angle, the ventilation opening (511) is communicated with the rear air duct opening (42).

4. A cold air structure as claimed in claim 3, wherein: the air deflector (51) comprises two baffle bodies (512) which are arranged in parallel, a plurality of air guide sheets (513) are arranged between the two baffle bodies (512) at intervals, two ends of each air guide sheet (513) are respectively connected with two baffle bodies (512), and gaps between two adjacent air guide sheets (513) are ventilation openings (511).

5. The cool air structure as claimed in claim 4, wherein: the upper edge of the front air duct opening (41) is provided with a baffle slot (411), and when the air deflector (51) rotates to a preset position, one of the two baffle plates (512) is abutted to the baffle slot (411).

6. A cold air structure as claimed in claim 3, wherein: a first fixing plate (91) and a second fixing plate (92) are fixedly arranged in the mounting seat (1);

the two ends of the air deflector (51) are respectively provided with a first rotating shaft (514) and a second rotating shaft (515);

the motor (52) is fixedly connected to the first fixing plate (91), and the motor (52) is connected with and controls the first rotating shaft (514) to rotate;

the second rotating shaft (515) is rotatably connected to the second fixing plate (92).

7. The cool air structure as claimed in claim 6, wherein: the first fixed plate (91) is provided with a first micro switch (61), and the second fixed plate (92) is provided with a second micro switch (62);

the first rotating shaft (514) is provided with a first poking piece (71), the first poking piece (71) and the first rotating shaft (514) synchronously rotate, and the first poking piece (71) is used for triggering a first micro switch (61);

the second rotating shaft (515) is provided with a second poking piece (72), the second poking piece (72) and the second rotating shaft (515) synchronously rotate, and the second poking piece (72) is used for triggering the second micro switch (62).

8. The cool air structure as claimed in claim 7, wherein: a first clamp spring (81) is clamped on the first rotating shaft (514), and the first clamp spring (81) and the first fixing plate (91) are respectively positioned at two ends of the first poking piece (71) and used for propping against the first poking piece (71) to perform axial limiting;

and a second clamping spring (82) is clamped on the second rotating shaft (515), and the second clamping spring (82) and the second fixing plate (92) are respectively positioned at two ends of the second poking piece (72) and used for propping against the second poking piece (72) to carry out axial limiting.

9. The cool air structure as claimed in claim 7, wherein: the fan (2) is a cross-flow fan, a plurality of air inlet holes (12) are formed in the outer surface of the mounting seat (1), and the air inlet holes (12) are communicated with the fan (2).

10. An integrated kitchen, characterized in that: comprising a main body (01) and a handpiece (02) arranged on the main body (01), and further comprising a cold air structure according to any one of claims 1 to 9, said cold air structure being arranged on top of the handpiece (02).