CN221055060U - Integrated kitchen range - Google Patents

Abstract

The utility model relates to an integrated kitchen range, and relates to the technical field of kitchen appliances. The integrated kitchen comprises a shell, an air blowing mechanism and a cooling mechanism, wherein a first air supply opening is formed in the shell, the air blowing mechanism is arranged in the shell, an air outlet of the air blowing mechanism faces to the first air supply opening, and the cooling mechanism is arranged in the shell and is positioned between the first air supply opening and the air outlet. The air outlet of the air blowing mechanism faces the first air supply outlet on the shell, the temperature of the air flow generated by the air blowing mechanism is reduced after the air flow passes through the cooling mechanism, and the low-temperature air flow is blown to a preset area through the first air supply outlet on the shell, so that the air temperature of the preset area near the integrated kitchen is effectively reduced, and a relatively comfortable cooking environment is provided.

Description

Integrated kitchen range

Technical Field

The utility model relates to the technical field of kitchen appliances, in particular to an integrated kitchen range.

Background

The heat generated by various heat sources can raise the temperature of the kitchen during cooking activities, especially in summer when the temperature is high, which can be intolerable during cooking. Because of the oil smoke environment of the kitchen, the device is not suitable for installing conventional cooling equipment such as an air conditioner, the cooling effect by an electric fan is not obvious, and the risk of blowing out the flame of the kitchen range exists.

The existing kitchen appliances, such as range hoods or integrated stoves, have only the function of fume extraction, do not have the function of cooling, and cannot provide a comfortable cooking environment.

Disclosure of utility model

The utility model provides an integrated kitchen range, which can blow low-temperature air flow in a preset direction, reduce the air temperature in a preset area and create a comfortable cooking environment.

The utility model provides an integrated cooker, comprising:

The shell is provided with a first air supply outlet;

The air blower mechanism is arranged in the shell, and an air outlet of the air blower mechanism faces the first air supply outlet; and

The cooling mechanism is arranged in the shell and is positioned between the first air supply outlet and the air outlet.

In one embodiment, the integrated kitchen further comprises an air curtain generator arranged in the shell, a second air supply opening is further formed in the shell, an air flow inlet and an air flow outlet are formed in the air curtain generator, the air flow inlet is connected with the air outlet, and the air flow outlet faces the second air supply opening.

In one embodiment, the air flow outlet and the air outlet are respectively arranged at two sides of the cooling mechanism, the area of the air flow inlet is smaller than that of the air outlet, and the air flow blown out from the air outlet comprises a first part flowing into the air curtain generator and a second part flowing through the cooling mechanism.

In one embodiment, the air curtain generator comprises an air inlet pipe and a generator body, wherein one end of the air inlet pipe is provided with the air flow inlet, the other end of the air inlet pipe is connected with the generator body, the air flow outlet is arranged on the generator body, and the generator body and the air blowing mechanism are respectively arranged on two sides of the cooling mechanism.

In one embodiment, the generator body includes a boss disposed at the airflow outlet.

In one embodiment, the second air supply opening and the air flow outlet are both elongated and horizontally arranged.

In one embodiment, the integrated cooker further comprises a refrigeration mechanism, a heat dissipation mechanism and a refrigerant pipeline, wherein the refrigeration mechanism, the heat dissipation mechanism and the refrigerant pipeline are arranged in the shell, and the cooling mechanism and the heat dissipation mechanism are connected with the refrigeration mechanism through the refrigerant pipeline.

In one embodiment, the integrated kitchen further comprises a heat exchange mechanism arranged in the shell, the heat dissipation mechanism is arranged in the heat exchange mechanism, and a liquid inlet for a heat exchange medium to pass in is formed in the heat exchange mechanism.

In one embodiment, the heat exchange medium is water.

In one embodiment, the integrated kitchen further comprises a smoke ventilator arranged in the shell, a smoke inlet and a smoke outlet are formed in the shell, and the refrigerant pipeline passes through a smoke inlet of the smoke ventilator.

In one embodiment, the integrated cooker further comprises a steam box arranged in the shell, and the outer wall of the steam box is provided with the refrigerant pipeline.

Compared with the prior art, the utility model has the advantages that the air outlet of the air blowing mechanism faces the first air outlet on the shell, the temperature of the air flow generated by the air blowing mechanism is reduced after passing through the cooling mechanism, and the low-temperature air flow is blown to a preset area through the first air outlet on the shell, so that the air temperature of the preset area near the integrated kitchen is effectively reduced, and a relatively comfortable cooking environment is provided.

Drawings

The utility model will be described in more detail hereinafter on the basis of embodiments and with reference to the accompanying drawings.

FIG. 1 is a front view of an integrated cooktop in an embodiment of the utility model;

FIG. 2 is a perspective view of an integrated cooktop in an embodiment of the utility model;

FIG. 3 is a cross-sectional view taken along A-A of FIG. 1;

FIG. 4 is a cross-sectional view of an integrated cooktop in an embodiment of the utility model;

fig. 5 is an enlarged view at B in fig. 4;

FIG. 6 is a diagram showing the connection between the blower mechanism and the air curtain generator in an embodiment of the present utility model.

Reference numerals:

1. A housing; 2. a blowing mechanism; 31. a cooling mechanism; 32. a refrigeration mechanism; 33. a heat dissipation mechanism; 34. a refrigerant pipe; 35. a heat exchange mechanism; 4. an air curtain generator; 41. an air inlet pipe; 42. a generator body; 421. a boss; 5. an oil smoke fan; 6. a steam box; 7. an oven; 100. a first air supply port; 200. an air outlet; 300. a second air supply port; 400. an air flow outlet; 500. a smoke inlet; 600. and a smoke outlet.

Detailed Description

The utility model will be further described with reference to the accompanying drawings.

Example 1

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located. The single arrow in fig. 3 indicates the direction of flow of the gas stream.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

Example two

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

Example III

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300. The direction of the air flow blown out from the second air outlet 300 is indicated by the dotted arrow in fig. 4.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Example IV

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

Example five

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

As shown in fig. 5, the generator body 42 includes a boss 421 provided at the airflow outlet 400. The boss 421 can function to converge the air flow outlet 400 so that the flow rate of the air flow is increased.

Further, the second air outlet 300 and the air outlet 400 are both elongated and horizontally disposed. The air flow generated by the air curtain generator 4 is directed obliquely downwards, and in order to effectively block the flue gas generated above the kitchen range, the air flow generated by the air curtain generator 4 also needs to have a sufficient width, so that the second air supply opening 300 and the air outflow opening 400 are both in a strip shape and horizontally arranged, and the air flow blown out from the second air supply opening 300 can form an air curtain with a large width to block the flue gas.

Example six

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

Further, the second air outlet 300 and the air outlet 400 are both elongated and horizontally disposed. The air flow generated by the air curtain generator 4 is directed obliquely downwards, and in order to effectively block the flue gas generated above the kitchen range, the air flow generated by the air curtain generator 4 also needs to have a sufficient width, so that the second air supply opening 300 and the air outflow opening 400 are both in a strip shape and horizontally arranged, and the air flow blown out from the second air supply opening 300 can form an air curtain with a large width to block the flue gas.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes a refrigeration mechanism 32, a heat dissipation mechanism 33 and a refrigerant pipe 34 that are disposed in the housing 1, and the refrigeration mechanism 31 and the heat dissipation mechanism 33 are connected to the refrigeration mechanism 32 through the refrigerant pipe 34. The refrigerating mechanism 32 is a compressor, the cooling mechanism 31 and the heat dissipation mechanism 33 are respectively used as an evaporator and a condenser, and the refrigerant pipeline 34 is used for circulating the refrigerant, so that the refrigerating principle is the same as that of the air conditioner. The cooling mechanism 32 is a compressor, has sufficient cooling capacity, can maintain the cooling mechanism 31 at a low temperature, and can provide a low temperature of the air flow blown out from the first air supply port 100 even if the temperature of the surrounding environment is high, thereby achieving a good cooling effect.

Example seven

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. The dotted arrows in fig. 4 to 6 indicate the direction of the air flow generated by the air curtain generator 4, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

Further, the second air outlet 300 and the air outlet 400 are both elongated and horizontally disposed. The air flow generated by the air curtain generator 4 is directed obliquely downwards, and in order to effectively block the flue gas generated above the kitchen range, the air flow generated by the air curtain generator 4 also needs to have a sufficient width, so that the second air supply opening 300 and the air outflow opening 400 are both in a strip shape and horizontally arranged, and the air flow blown out from the second air supply opening 300 can form an air curtain with a large width to block the flue gas.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes a refrigeration mechanism 32, a heat dissipation mechanism 33 and a refrigerant pipe 34 that are disposed in the housing 1, and the refrigeration mechanism 31 and the heat dissipation mechanism 33 are connected to the refrigeration mechanism 32 through the refrigerant pipe 34. The refrigerating mechanism 32 is a compressor, the cooling mechanism 31 and the heat dissipation mechanism 33 are respectively used as an evaporator and a condenser, and the refrigerant pipeline 34 is used for circulating the refrigerant, so that the refrigerating principle is the same as that of the air conditioner. The cooling mechanism 32 is a compressor, has sufficient cooling capacity, can maintain the cooling mechanism 31 at a low temperature, and can provide a low temperature of the air flow blown out from the first air supply port 100 even if the temperature of the surrounding environment is high, thereby achieving a good cooling effect.

As shown in fig. 4, the integrated stove of the present embodiment further includes a heat exchange mechanism 35 disposed in the housing 1, the heat dissipation mechanism 33 is disposed in the heat exchange mechanism 35, and a liquid inlet (not shown in the figure) through which a heat exchange medium is introduced is disposed on the heat exchange mechanism 35. The heat dissipation mechanism 33, which is a condenser, generates more heat that, if not transferred, can affect the proper operation of the entire refrigeration system, and also raise the temperature inside the housing 1 and transfer it to the surrounding environment. By arranging the heat dissipation mechanism 33 inside the heat exchange mechanism 35 and immersing the heat dissipation mechanism in the liquid heat exchange medium, the heat of the heat dissipation mechanism 33 can be effectively absorbed, and the over-high temperature of the heat dissipation mechanism 33 and the rapid diffusion of the heat into the surrounding environment are avoided.

Example eight

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

Further, the second air outlet 300 and the air outlet 400 are both elongated and horizontally disposed. The air flow generated by the air curtain generator 4 is directed obliquely downwards, and in order to effectively block the flue gas generated above the kitchen range, the air flow generated by the air curtain generator 4 also needs to have a sufficient width, so that the second air supply opening 300 and the air outflow opening 400 are both in a strip shape and horizontally arranged, and the air flow blown out from the second air supply opening 300 can form an air curtain with a large width to block the flue gas.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes a refrigeration mechanism 32, a heat dissipation mechanism 33 and a refrigerant pipe 34 that are disposed in the housing 1, and the refrigeration mechanism 31 and the heat dissipation mechanism 33 are connected to the refrigeration mechanism 32 through the refrigerant pipe 34. The refrigerating mechanism 32 is a compressor, the cooling mechanism 31 and the heat dissipation mechanism 33 are respectively used as an evaporator and a condenser, and the refrigerant pipeline 34 is used for circulating the refrigerant, so that the refrigerating principle is the same as that of the air conditioner. The cooling mechanism 32 is a compressor, has sufficient cooling capacity, can maintain the cooling mechanism 31 at a low temperature, and can provide a low temperature of the air flow blown out from the first air supply port 100 even if the temperature of the surrounding environment is high, thereby achieving a good cooling effect.

As shown in fig. 4, the integrated stove of the embodiment further includes a heat exchange mechanism 35 disposed in the housing 1, the heat dissipation mechanism 33 is disposed in the heat exchange mechanism 35, and a liquid inlet through which a heat exchange medium is introduced is disposed on the heat exchange mechanism 35. The heat dissipation mechanism 33, which is a condenser, generates more heat that, if not transferred, can affect the proper operation of the entire refrigeration system, and also raise the temperature inside the housing 1 and transfer it to the surrounding environment. By arranging the heat dissipation mechanism 33 inside the heat exchange mechanism 35 and immersing the heat dissipation mechanism in the liquid heat exchange medium, the heat of the heat dissipation mechanism 33 can be effectively absorbed, and the over-high temperature of the heat dissipation mechanism 33 and the rapid diffusion of the heat into the surrounding environment are avoided.

Further, the heat exchange medium is water, and specifically, tap water is used as the heat exchange medium in this embodiment. The specific heat capacity of water is large, a large amount of heat can be absorbed, and the water is convenient to obtain and low in cost. In order to use the heated water in the heat exchange mechanism 35, a corresponding water outlet pipeline and a switch (not shown) may also be provided on the heat exchange mechanism 35.

Example nine

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

Further, the second air outlet 300 and the air outlet 400 are both elongated and horizontally disposed. The air flow generated by the air curtain generator 4 is directed obliquely downwards, and in order to effectively block the flue gas generated above the kitchen range, the air flow generated by the air curtain generator 4 also needs to have a sufficient width, so that the second air supply opening 300 and the air outflow opening 400 are both in a strip shape and horizontally arranged, and the air flow blown out from the second air supply opening 300 can form an air curtain with a large width to block the flue gas.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes a refrigeration mechanism 32, a heat dissipation mechanism 33 and a refrigerant pipe 34 that are disposed in the housing 1, and the refrigeration mechanism 31 and the heat dissipation mechanism 33 are connected to the refrigeration mechanism 32 through the refrigerant pipe 34. The refrigerating mechanism 32 is a compressor, the cooling mechanism 31 and the heat dissipation mechanism 33 are respectively used as an evaporator and a condenser, and the refrigerant pipeline 34 is used for circulating the refrigerant, so that the refrigerating principle is the same as that of the air conditioner. The cooling mechanism 32 is a compressor, has sufficient cooling capacity, can maintain the cooling mechanism 31 at a low temperature, and can provide a low temperature of the air flow blown out from the first air supply port 100 even if the temperature of the surrounding environment is high, thereby achieving a good cooling effect.

As shown in fig. 4, the integrated stove of the embodiment further includes a heat exchange mechanism 35 disposed in the housing 1, the heat dissipation mechanism 33 is disposed in the heat exchange mechanism 35, and a liquid inlet through which a heat exchange medium is introduced is disposed on the heat exchange mechanism 35. The heat dissipation mechanism 33, which is a condenser, generates more heat that, if not transferred, can affect the proper operation of the entire refrigeration system, and also raise the temperature inside the housing 1 and transfer it to the surrounding environment. By arranging the heat dissipation mechanism 33 inside the heat exchange mechanism 35 and immersing the heat dissipation mechanism in the liquid heat exchange medium, the heat of the heat dissipation mechanism 33 can be effectively absorbed, and the over-high temperature of the heat dissipation mechanism 33 and the rapid diffusion of the heat into the surrounding environment are avoided.

Further, the heat exchange medium is water. The specific heat capacity of water is large, a large amount of heat can be absorbed, and the water is convenient to obtain and low in cost. In order to use the heated water in the heat exchange mechanism 35, a corresponding water outlet pipeline and a switch (not shown) may also be provided on the heat exchange mechanism 35.

As shown in fig. 2, the integrated kitchen range of the embodiment further includes a smoke ventilator 5 disposed in the housing 1, and the housing 1 is provided with a smoke inlet 500 and a smoke outlet 600, and the refrigerant pipeline 34 passes through a smoke inlet of the smoke ventilator 5. The negative pressure generated by the smoke ventilator 5 can suck the smoke from the smoke inlet 500 and then discharge the smoke from the smoke outlet 600. Between the flue gas entering the oil smoke fan 5, the flue gas can be cooled through the refrigerant pipeline 34 at first, so that grease in the flue gas is separated, and the performance of the oil smoke fan 5 is prevented from being reduced due to the fact that excessive grease is attached to the impeller of the oil smoke fan 5.

Examples ten

As shown in fig. 1 to 3, the integrated kitchen includes a housing 1, a blower mechanism 2 and a cooling mechanism 31, a first air supply port 100 is provided on the housing 1, the blower mechanism 2 is disposed in the housing 1, an air outlet 200 of the blower mechanism 2 faces the first air supply port 100, and the cooling mechanism 31 is disposed in the housing 1 and is located between the first air supply port 100 and the air outlet 200.

The air outlet 200 of the air blowing mechanism 2 faces the first air outlet 100 on the shell 1, the temperature of the air flow generated by the air blowing mechanism 2 is reduced after passing through the cooling mechanism 31, and the low-temperature air flow is blown to a preset area through the first air outlet 100 on the shell 1, so that the air temperature of the preset area near the integrated kitchen range is effectively reduced, and a relatively comfortable cooking environment is provided. The predetermined area refers to a standing area of a person when the integrated kitchen range is operated, and in order to avoid discomfort caused by direct blowing of low-temperature air flow to the head, the first air supply opening 100 in this embodiment is formed into a certain shape, so that the blown air flow can be directed obliquely downward, that is, toward the direction where the trunk and limbs of the human body are located.

The plurality of first air outlets 100 may be disposed, and the first air outlets 100 may be parallel to each other, so that an area of the air supply area is larger. In this embodiment, each first air supply opening 100 is horizontally disposed and has a strip shape, so that the low-temperature air flow can be dispersed in a larger space range, and the cooling effect on the predetermined area near the integrated stove is good.

The number of the blower mechanisms 2 may be two or more, and in the present embodiment, the number of the blower mechanisms 2 is two and is set at the same height.

Specifically, the cooling mechanism 31 may be an evaporator or a semiconductor refrigeration sheet. If the cooling mechanism 31 adopts an evaporator, a corresponding pipeline and a compressor are also required to realize the refrigeration effect. If the cooling mechanism 31 is a semiconductor refrigeration sheet, a compressor is not required, but the refrigeration power is relatively weak. No matter which form the cooling mechanism 31 takes, it should allow the air flow to pass through, and the resistance to the air flow is small, so that the air flow generated by the air blowing mechanism 2 does not lose great kinetic energy when passing through the cooling mechanism 31, and the air flow blown out from the first air blowing port 100 is strong and powerful.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes an air curtain generator 4 disposed in the casing 1, as shown in fig. 1 and 2, a second air supply port 300 is further disposed on the casing 1, as shown in fig. 5, an air inlet (not shown in the drawing) and an air outlet 400 are disposed on the air curtain generator 4, as shown in fig. 5, the air inlet is connected with the air outlet 200, and the air outlet 400 faces the second air supply port 300. The air curtain generator 4 generates strong air flow by using the coanda effect and forms an air curtain to isolate smoke generated during cooking and prevent the smoke from diffusing to the head of a person. The double arrow in fig. 4 indicates the flow direction of the flue gas, and the gas flow outlet 400 is directed obliquely downwards for effective separation of the flue gas.

The coanda effect, also known as coanda effect or coanda effect, changes the tendency of a fluid to flow with a convex object surface from deviating from the original direction of flow. When there is surface friction (also known as fluid viscosity) between the fluid and the surface of the object over which it flows, the fluid will flow along the surface of the object as long as the curvature is not large. As shown in fig. 4, the dotted arrow in the drawing indicates the direction of the air flow, and when the air flow is blown out from the air flow outlet 400, the air flow flows along the lower surface of the air curtain generator 4 and is blown out from the second air supply port 300.

As shown in fig. 4, the air flow outlet 400 and the air outlet 200 are respectively disposed at two sides of the cooling mechanism 31, and as shown in fig. 5, the area of the air flow inlet is smaller than that of the air outlet 200, and the air flow blown out from the air outlet 200 includes a first portion flowing into the air curtain generator 4 and a second portion flowing through the cooling mechanism 31. That is, the air curtain generator 4 only receives part of the air flow generated by the air blowing mechanism 2, and part of the air flow generated by the air blowing mechanism 2 is directly blown out from the air blowing mechanism 2 and is cooled by the cooling mechanism 31, and then is blown out from the first air supply outlet 100, so that the original cooling function still exists and the air curtain can be generated to isolate the flue gas.

Specifically, as shown in fig. 5, the air curtain generator 4 includes an air inlet pipe 41 and a generator body 42, an air inlet is provided at one end of the air inlet pipe 41, the other end of the air inlet pipe 41 is connected with the generator body 42, an air outlet 400 is provided on the generator body 42, and the generator body 42 and the blower mechanism 2 are provided on both sides of the cooling mechanism 31, respectively. Since there are two blower mechanisms 2 in the present embodiment, the number of the air intake pipes 41 is also two, and the air intake pipes 41 are provided to guide the air flow generated by the blower mechanisms 2 into the generator body 42. In order to reduce the energy loss, the air inlet pipe 41 is abutted against the air outlet 200 of the blower mechanism 2.

Furthermore, by providing the air intake duct 41, the generator body 42 can also be spaced apart from the blower mechanism 2 to provide sufficient space for installation of the cooling mechanism 31.

Further, the second air outlet 300 and the air outlet 400 are both elongated and horizontally disposed. The air flow generated by the air curtain generator 4 is directed obliquely downwards, and in order to effectively block the flue gas generated above the kitchen range, the air flow generated by the air curtain generator 4 also needs to have a sufficient width, so that the second air supply opening 300 and the air outflow opening 400 are both in a strip shape and horizontally arranged, and the air flow blown out from the second air supply opening 300 can form an air curtain with a large width to block the flue gas.

As shown in fig. 4, the integrated kitchen range of the present embodiment further includes a refrigeration mechanism 32, a heat dissipation mechanism 33 and a refrigerant pipe 34 that are disposed in the housing 1, and the refrigeration mechanism 31 and the heat dissipation mechanism 33 are connected to the refrigeration mechanism 32 through the refrigerant pipe 34. The refrigerating mechanism 32 is a compressor, the cooling mechanism 31 and the heat dissipation mechanism 33 are respectively used as an evaporator and a condenser, and the refrigerant pipeline 34 is used for circulating the refrigerant, so that the refrigerating principle is the same as that of the air conditioner. The cooling mechanism 32 is a compressor, has sufficient cooling capacity, can maintain the cooling mechanism 31 at a low temperature, and can provide a low temperature of the air flow blown out from the first air supply port 100 even if the temperature of the surrounding environment is high, thereby achieving a good cooling effect.

As shown in fig. 4, the integrated stove of the embodiment further includes a heat exchange mechanism 35 disposed in the housing 1, the heat dissipation mechanism 33 is disposed in the heat exchange mechanism 35, and a liquid inlet through which a heat exchange medium is introduced is disposed on the heat exchange mechanism 35. The heat dissipation mechanism 33, which is a condenser, generates more heat that, if not transferred, can affect the proper operation of the entire refrigeration system, and also raise the temperature inside the housing 1 and transfer it to the surrounding environment. By arranging the heat dissipation mechanism 33 inside the heat exchange mechanism 35 and immersing the heat dissipation mechanism in the liquid heat exchange medium, the heat of the heat dissipation mechanism 33 can be effectively absorbed, and the over-high temperature of the heat dissipation mechanism 33 and the rapid diffusion of the heat into the surrounding environment are avoided.

Further, the heat exchange medium is water. The specific heat capacity of water is large, a large amount of heat can be absorbed, and the water is convenient to obtain and low in cost. In order to use the heated water in the heat exchange mechanism 35, a corresponding water outlet pipeline and a switch (not shown) may also be provided on the heat exchange mechanism 35.

As shown in fig. 2, the integrated kitchen range of the embodiment further includes a smoke ventilator 5 disposed in the housing 1, and the housing 1 is provided with a smoke inlet 500 and a smoke outlet 600, and the refrigerant pipeline 34 passes through a smoke inlet of the smoke ventilator 5. The negative pressure generated by the smoke ventilator 5 can suck the smoke from the smoke inlet 500 and then discharge the smoke from the smoke outlet 600. Between the flue gas entering the oil smoke fan 5, the flue gas can be cooled through the refrigerant pipeline 34 at first, so that grease in the flue gas is separated, and the performance of the oil smoke fan 5 is prevented from being reduced due to the fact that excessive grease is attached to the impeller of the oil smoke fan 5.

As shown in fig. 2, the integrated kitchen range of the present embodiment further includes a steam box 6 disposed in the housing 1, and a refrigerant pipe 34 is disposed on an outer wall of the steam box 6. The refrigerant pipe 34 can lower the temperature in the steam box 6, and can be used as a refrigerator when the steam box 6 does not perform cooking operation, so that the integrated cooker has more functions.

In this embodiment, the integrated kitchen further includes an oven 7, and the oven 7 is also disposed in the housing 1, so that the food material can be baked, and the integrated kitchen has more functions.

While the utility model has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In particular, the technical features mentioned in the respective embodiments may be combined in any manner as long as there is no structural conflict. The present utility model is not limited to the specific embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.

Claims (11)

1. An integrated cooktop, comprising:

The shell is provided with a first air supply outlet;

The air blower mechanism is arranged in the shell, and an air outlet of the air blower mechanism faces the first air supply outlet; and

The cooling mechanism is arranged in the shell and is positioned between the first air supply outlet and the air outlet.

2. The integrated cooker of claim 1, further comprising an air curtain generator disposed in the housing, wherein a second air supply port is further disposed on the housing, an air inlet and an air outlet are disposed on the air curtain generator, the air inlet is connected with the air outlet, and the air outlet faces the second air supply port.

3. The integrated cooker of claim 2, wherein the air flow outlet and the air outlet are provided on both sides of the cooling mechanism, respectively, the area of the air flow inlet is smaller than the area of the air outlet, and the air flow blown out from the air outlet includes a first portion flowing into the air curtain generator and a second portion flowing through the cooling mechanism.

4. The integrated cooker according to claim 2, wherein the air curtain generator comprises an air inlet pipe and a generator body, one end of the air inlet pipe is provided with the air flow inlet, the other end of the air inlet pipe is connected with the generator body, the air flow outlet is arranged on the generator body, and the generator body and the air blowing mechanism are respectively arranged on two sides of the cooling mechanism.

5. The integrated cooker of claim 4, wherein the generator body includes a boss disposed at the airflow outlet.

6. The integrated cooker of claim 2, wherein the second air supply opening and the air flow outlet are both elongated and horizontally disposed.

7. The integrated cooker of any one of claims 1-6, further comprising a cooling mechanism, a heat dissipation mechanism, and a refrigerant conduit disposed in the housing, both the cooling mechanism and the heat dissipation mechanism being connected to the cooling mechanism by the refrigerant conduit.

8. The integrated cooker of claim 7, further comprising a heat exchange mechanism disposed in the housing, wherein the heat dissipation mechanism is disposed in the heat exchange mechanism, and wherein the heat exchange mechanism is provided with a liquid inlet through which a heat exchange medium is introduced.

9. The integrated cooker of claim 8, wherein the heat exchange medium is water.

10. The integrated cooker of claim 7, further comprising a smoke blower disposed in the housing, wherein the housing is provided with a smoke inlet and a smoke outlet, and wherein the refrigerant pipe passes through a smoke inlet of the smoke blower.

11. The integrated cooker of claim 7, further comprising a steam box disposed in the housing, an outer wall of the steam box being provided with the refrigerant pipe.