CN219109196U - Heat dissipation thermos bottle - Google Patents

Abstract

The utility model provides a heat-dissipation boiled water bottle. The utility model provides a heat dissipation vacuum flask, is including being used for boiling the inner bag of water and cladding be in the peripheral main shell of inner bag, wherein, be equipped with the cladding between inner bag and the main shell the lateral wall of inner bag and can to the all-round air supply of lateral wall of inner bag dispels the heat wind channel subassembly. The utility model has simple structure and convenient use, can realize the omnibearing blowing and heat dissipation of the inner container of the thermos bottle, can achieve higher heat dissipation efficiency, greatly shortens the cooling time and saves electric energy.

Description

Heat dissipation thermos bottle

Technical Field

The utility model relates to the technical field of small household appliances, in particular to a heat-dissipation water-boiling bottle.

Background

Because the drinking machine has a plurality of defects, the volume is large, the movement is inconvenient, the secondary pollution is caused, and the like, people start to purchase small and convenient electric heating thermos bottles. The electric heating thermos bottle is a small household appliance which is widely applied to families and offices, can boil water and has a heat preservation function. The electric heating thermos bottle has the characteristics of convenience, rapidness and the like, and gradually enters common families at present, so that the electric heating thermos bottle becomes a member of small kitchen appliances.

In order to enable the boiled water of the electric heating boiled water bottle to be cooled rapidly, the heat dissipation fans are arranged between the outer shell and the inner container of the electric heating boiled water bottle, the heat dissipation fans radiate heat by blowing air towards the inner container, the quantity of the heat dissipation fans is one or more, but due to the fact that the size of the heat dissipation fans is limited, the heat dissipation fans can only directly blow air against one or more parts of the side wall of the inner container, the air cannot be blown to other parts of the inner container, so that the heat dissipation of hot water in the whole inner container is slower, the heat dissipation efficiency is very low, the time consumption is long, and the heat dissipation fans are relatively power-consuming when running for a long time.

Disclosure of Invention

The utility model provides a heat-dissipation thermos bottle, which aims to overcome the defects that the heat dissipation efficiency is extremely low and the cooling time is too long in the cooling mode of adopting a heat dissipation fan to directly blow and dissipate heat to a liner from a certain direction or a plurality of directions in the existing thermos bottle. The utility model has simple structure and convenient use, can realize the omnibearing blowing and heat dissipation of the inner container of the thermos bottle, can achieve higher heat dissipation efficiency, greatly shortens the cooling time and saves electric energy.

In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model provides a heat dissipation vacuum flask, is including being used for boiling the inner bag of water and cladding be in the peripheral main shell of inner bag, wherein, be equipped with the cladding between inner bag and the main shell the lateral wall of inner bag and can to the all-round air supply of lateral wall of inner bag dispels the heat wind channel subassembly. Therefore, when the water in the inner container is boiled and then needs to be cooled, cold air can be continuously blown to the outer side wall of the inner container by the heat dissipation air duct component, and the heat of the hot water in the inner container is taken away through heat exchange, so that the purpose of cooling the hot water in the inner container is achieved.

Further, the heat dissipation wind channel subassembly is including locating the inner bag bottom just follows the wind channel of circumference setting of inner bag bottom, and cladding is in the outside fan housing of lateral wall of inner bag, the top of wind channel with the bottom intercommunication of fan housing, the bottom surface of wind channel is spiral ascending form, the wind channel is connected with air supply component at its bottom surface extreme low, the fan housing is being close to one side of inner bag lateral wall is equipped with a plurality of blowholes, the fan housing with the lateral wall interval of inner bag is a distance. When the water in the inner container is boiled and then needs to be cooled, the air supply element is started at the moment, and the air supply element continuously supplies cold air into the air conveying channel. The bottom surface of the air conveying channel is spirally ascending, and the air supply element is communicated with the lowest end of the bottom surface of the air conveying channel, so that the flowing resistance of cold air entering the air channel is extremely low, and the cold air can keep high wind speed and high wind pressure in the whole air conveying channel only by using one air supply element, so that when the cold air is blown to the circumferential side wall of the inner container from the air conveying channel to the fan housing through the air blowing holes, the cold air in all directions blown to the circumferential side wall of the inner container can be ensured to have high and uniform wind speed and wind pressure, and heat in the inner container can be taken away rapidly, and hot water in the inner container can be cooled rapidly. Compared with the existing thermos bottle capable of reducing temperature, the temperature reducing time is greatly shortened, and electric energy can be saved.

Further, the main shell comprises a first shell coated at the bottom end of the inner container and a second shell coated on the circumferential outer wall of the inner container, an air inlet hole is formed in the first shell, and an air outlet hole is formed in the second shell at a position corresponding to the top end of the fan housing. The air supply element can suck the cold air outside the main shell into the main shell through the air inlet hole on the first shell, and then convey the cold air into the air conveying channel; because the fan housing is spaced from the outer side wall of the inner container by a certain distance, after cold air is blown to the outer side wall of the inner container from the fan housing, the cold air is discharged from a gap between the top of the fan housing and the outer side wall of the inner container and then discharged to the outside of the main shell through the air outlet.

Further, a heating component and a control board component are arranged on the bottom surface of the inner container, and the air supply element and the heating component are electrically connected with the control board component. The start and stop of the air supply element and the heating component are uniformly controlled by the control board component.

Further, a water outlet nozzle is arranged on one side of the top of the main shell, a water pump is arranged on the outer side of the bottom of the inner container, a water inlet of the water pump is communicated with the inner side of the bottom of the inner container, a water outlet of the water pump is communicated with the water outlet nozzle through a pipeline, and the water pump is connected with the control panel assembly. After the hot water in the inner container is cooled to a proper use temperature, the hot water in the inner container can be conveyed to the water outlet nozzle for discharging by controlling the water pump through the control panel assembly.

Further, one side of the water outlet nozzle is provided with an operation display panel, and the operation display panel is connected with the control panel assembly. The user can control and observe the operation state of the boiled water bottle by controlling the display panel.

Further, the wind direction at the air outlet of the air supply element is tangential to the spiral direction of the bottom surface of the air conveying channel. Therefore, the loss of wind speed and wind pressure when the cold wind blown out by the air supply element enters the air conveying channel can be further reduced, and the cold wind is ensured to have higher wind speed and wind pressure when flowing in the whole air conveying channel.

Further, the air supply element is a volute fan or a blower.

Further, a bottle cap assembly for covering the opening at the top of the inner container is arranged at the top of the main shell.

Further, a handle is arranged at the top of the main shell.

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the heat dissipation air duct component which wraps the outer side wall of the inner container and can blow air to the outer side wall of the inner container in an omnibearing manner is arranged between the inner container and the main shell, so that cold air can be blown to each position of the outer side wall of the inner container, heat exchange can be carried out with the cold air each time, the wind pressure and the wind speed of each position are uniform, higher heat dissipation efficiency can be achieved, and the time for cooling hot water in the inner container is greatly shortened.

The bottom surface of the novel air conveying channel is in a spiral ascending shape, the lowest end of the bottom surface of the air conveying channel is connected with an air supply element, so that the flowing resistance of cold air after entering the air conveying channel is extremely low, the cold air can keep high wind speed and high wind pressure in the whole air conveying channel only by using one air supply element, and when the cold air is blown into the circumferential side wall of the liner from the air conveying channel to the fan housing, the cold air in all directions of the circumferential side wall of the liner can be ensured to have high and uniform wind speed and wind pressure through the air blowing holes, and the heat of the kettle body can be taken away rapidly, so that hot water in the kettle body is cooled rapidly. Compared with the existing thermos bottle, the temperature reduction time is greatly shortened, and the electric energy can be saved.

Drawings

Fig. 1 is a schematic view of the overall structure of the present utility model.

Fig. 2 is a schematic view of the internal structure of the present utility model.

Fig. 3 is an exploded view of the present utility model.

Fig. 4 is a schematic structural diagram of the bottom of the heat dissipation air duct assembly according to the present utility model.

Fig. 5 is a schematic structural diagram of the top of the heat dissipation air duct assembly according to the present utility model.

FIG. 6 is a schematic view of the bottom of the liner of the present utility model.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the present patent; for the purpose of better illustrating the embodiments, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the actual product dimensions; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted. The positional relationship depicted in the drawings is for illustrative purposes only and is not to be construed as limiting the present patent.

Example 1

As shown in fig. 1 to 3, a heat dissipation vacuum flask comprises a liner 1 for boiling water and a main housing 2 coated on the periphery of the liner 1, wherein a heat dissipation air duct component which is coated on the outer side wall of the liner 1 and can supply air to the outer side wall of the liner 1 in all directions is arranged between the liner 1 and the main housing 2. Therefore, when the water in the inner container 1 needs to be cooled after boiling, cold air can be continuously blown to the outer side wall of the inner container 1 by the heat dissipation air duct component, and the heat of hot water in the inner container 1 is taken away through heat exchange, so that the purpose of cooling the hot water in the inner container 1 is achieved.

As shown in fig. 2 to 5, the heat dissipation air duct assembly comprises an air conveying channel 3 arranged at the bottom end of the inner container 1 and along the circumferential direction of the bottom end of the inner container 1, and an air cover 4 wrapping the outer side wall of the inner container 1, wherein the top end of the air conveying channel 3 is communicated with the bottom end of the air cover 4, the bottom surface of the air conveying channel 3 is in a spiral ascending shape, the lowest end of the bottom surface of the air conveying channel 3 is connected with an air supply element 5, one side, close to the side wall of the inner container 1, of the air cover 4 is provided with a plurality of air blowing holes 6, and the air cover 4 is spaced a certain distance from the outer side wall of the inner container 1. When the water in the inner container 1 still needs to be cooled after boiling, the air supply element 5 is started at the moment, the air supply element 5 continuously supplies cold air into the air conveying channel 3, and the cold air is blown to the circumferential outer wall of the inner container 1 from the air conveying channel 3 due to the fact that the air blowing holes 6 are formed in the circumferential side wall of the air cover 4, and the heat of hot water in the inner container 1 is taken away through heat exchange, so that the hot water in the inner container 1 is cooled. Because the bottom surface of the air conveying channel 3 is spirally rising, and the air supply element 5 is communicated with the lowest end of the bottom surface of the air conveying channel 3, the flowing resistance of cold air after entering the air channel is extremely small, and the cold air can keep high wind speed and high wind pressure in the whole air conveying channel 3 only by one air supply element 5, so that when the cold air is blown to the circumferential side wall of the liner 1 from the air conveying channel 3 to the fan housing 4 through the air blowing holes 6, the cold air in all directions blown to the circumferential side wall of the liner 1 can be ensured to have high and uniform wind speed and wind pressure, and heat in the liner 1 can be taken away rapidly, and hot water in the liner can be cooled rapidly. Compared with the existing thermos bottle capable of reducing temperature, the temperature reducing time is greatly shortened, and electric energy can be saved.

As shown in fig. 6, a heating assembly and a control board assembly 9 are disposed on the bottom surface of the liner 1, and the air supply element 5 and the heating assembly are electrically connected with the control board assembly 9. The start and stop of the air supply element 5 and the heating assembly are uniformly controlled by the control panel assembly 9.

As shown in fig. 4, the wind direction at the air outlet of the air supply element 5 is tangential to the spiral direction of the bottom surface of the air delivery channel 3. Therefore, the loss of wind speed and wind pressure when the cold wind blown out by the air supply element 5 enters the air conveying channel 3 can be further reduced, so that the cold wind has higher wind speed and wind pressure when flowing in the whole air conveying channel 3.

In this embodiment, the air supply element 5 is a volute fan.

As shown in fig. 1 and 2, a bottle cap assembly 13 for covering the top opening of the liner 1 is provided at the top of the main housing 2.

As shown in fig. 1 and 2, a handle 14 is provided on the top of the main housing 2.

Example 2

As shown in fig. 1 to 3, a heat dissipation vacuum flask comprises a liner 1 for boiling water and a main housing 2 coated on the periphery of the liner 1, wherein a heat dissipation air duct component which is coated on the outer side wall of the liner 1 and can supply air to the outer side wall of the liner 1 in all directions is arranged between the liner 1 and the main housing 2. Therefore, when the water in the inner container 1 needs to be cooled after boiling, cold air can be continuously blown to the outer side wall of the inner container 1 by the heat dissipation air duct component, and the heat of hot water in the inner container 1 is taken away through heat exchange, so that the purpose of cooling the hot water in the inner container 1 is achieved.

As shown in fig. 2 to 5, the heat dissipation air duct assembly comprises an air conveying channel 3 arranged at the bottom end of the inner container 1 and along the circumferential direction of the bottom end of the inner container 1, and an air cover 4 wrapping the outer side wall of the inner container 1, wherein the top end of the air conveying channel 3 is communicated with the bottom end of the air cover 4, the bottom surface of the air conveying channel 3 is in a spiral ascending shape, the lowest end of the bottom surface of the air conveying channel 3 is connected with an air supply element 5, one side, close to the side wall of the inner container 1, of the air cover 4 is provided with a plurality of air blowing holes 6, and the air cover 4 is spaced a certain distance from the outer side wall of the inner container 1. When the water in the inner container 1 still needs to be cooled after boiling, the air supply element 5 is started at the moment, the air supply element 5 continuously supplies cold air into the air conveying channel 3, and the cold air is blown to the circumferential outer wall of the inner container 1 from the air conveying channel 3 due to the fact that the air blowing holes 6 are formed in the circumferential side wall of the air cover 4, and the heat of hot water in the inner container 1 is taken away through heat exchange, so that the hot water in the inner container 1 is cooled. Because the bottom surface of the air conveying channel 3 is spirally rising, and the air supply element 5 is communicated with the lowest end of the bottom surface of the air conveying channel 3, the flowing resistance of cold air after entering the air channel is extremely small, and the cold air can keep high wind speed and high wind pressure in the whole air conveying channel 3 only by one air supply element 5, so that when the cold air is blown to the circumferential side wall of the liner 1 from the air conveying channel 3 to the fan housing 4 through the air blowing holes 6, the cold air in all directions blown to the circumferential side wall of the liner 1 can be ensured to have high and uniform wind speed and wind pressure, and heat in the liner 1 can be taken away rapidly, and hot water in the liner can be cooled rapidly. Compared with the existing thermos bottle capable of reducing temperature, the temperature reducing time is greatly shortened, and electric energy can be saved.

As shown in fig. 1 to 3, the main casing 2 includes a first casing 21 coated at the bottom end of the liner 1, and a second casing 22 coated on the circumferential outer wall of the liner 1, where the first casing 21 is provided with an air inlet 7, and the second casing 22 is provided with an air outlet 8 at a position corresponding to the top end of the fan housing 4. The air supply element 5 can suck the cold air outside the main housing 2 into the main housing 2 through the air inlet 7 on the first housing 21, and then convey the cold air into the air conveying channel 3; because the fan housing 4 is spaced from the outer side wall of the inner container 1 by a certain distance, after the cold air is blown from the fan housing 4 to the outer side wall of the inner container 1, the cold air is discharged from a gap between the top of the fan housing 4 and the outer side wall of the inner container 1 and then discharged to the outside of the main casing 2 through the air outlet 8.

As shown in fig. 6, a heating assembly and a control board assembly 9 are disposed on the bottom surface of the liner 1, and the air supply element 5 and the heating assembly are electrically connected with the control board assembly 9. The start and stop of the air supply element 5 and the heating assembly are uniformly controlled by the control panel assembly 9.

As shown in fig. 4, the wind direction at the air outlet of the air supply element 5 is tangential to the spiral direction of the bottom surface of the air delivery channel 3. Therefore, the loss of wind speed and wind pressure when the cold wind blown out by the air supply element 5 enters the air conveying channel 3 can be further reduced, so that the cold wind has higher wind speed and wind pressure when flowing in the whole air conveying channel 3.

In this embodiment, the air supply element 5 is a blower.

As shown in fig. 1 and 2, a bottle cap assembly 13 for covering the top opening of the liner 1 is provided at the top of the main housing 2.

As shown in fig. 1 and 2, a handle 14 is provided on the top of the main housing 2.

Example 3

As shown in fig. 1 to 3, a heat dissipation vacuum flask comprises a liner 1 for boiling water and a main housing 2 coated on the periphery of the liner 1, wherein a heat dissipation air duct component which is coated on the outer side wall of the liner 1 and can supply air to the outer side wall of the liner 1 in all directions is arranged between the liner 1 and the main housing 2. Therefore, when the water in the inner container 1 needs to be cooled after boiling, cold air can be continuously blown to the outer side wall of the inner container 1 by the heat dissipation air duct component, and the heat of hot water in the inner container 1 is taken away through heat exchange, so that the purpose of cooling the hot water in the inner container 1 is achieved.

As shown in fig. 2 to 5, the heat dissipation air duct assembly comprises an air conveying channel 3 arranged at the bottom end of the inner container 1 and along the circumferential direction of the bottom end of the inner container 1, and an air cover 4 wrapping the outer side wall of the inner container 1, wherein the top end of the air conveying channel 3 is communicated with the bottom end of the air cover 4, the bottom surface of the air conveying channel 3 is in a spiral ascending shape, the lowest end of the bottom surface of the air conveying channel 3 is connected with an air supply element 5, one side, close to the side wall of the inner container 1, of the air cover 4 is provided with a plurality of air blowing holes 6, and the air cover 4 is spaced a certain distance from the outer side wall of the inner container 1. When the water in the inner container 1 still needs to be cooled after boiling, the air supply element 5 is started at the moment, the air supply element 5 continuously supplies cold air into the air conveying channel 3, and the cold air is blown to the circumferential outer wall of the inner container 1 from the air conveying channel 3 due to the fact that the air blowing holes 6 are formed in the circumferential side wall of the air cover 4, and the heat of hot water in the inner container 1 is taken away through heat exchange, so that the hot water in the inner container 1 is cooled. Because the bottom surface of the air conveying channel 3 is spirally rising, and the air supply element 5 is communicated with the lowest end of the bottom surface of the air conveying channel 3, the flowing resistance of cold air after entering the air channel is extremely small, and the cold air can keep high wind speed and high wind pressure in the whole air conveying channel 3 only by one air supply element 5, so that when the cold air is blown to the circumferential side wall of the liner 1 from the air conveying channel 3 to the fan housing 4 through the air blowing holes 6, the cold air in all directions blown to the circumferential side wall of the liner 1 can be ensured to have high and uniform wind speed and wind pressure, and heat in the liner 1 can be taken away rapidly, and hot water in the liner can be cooled rapidly. Compared with the existing thermos bottle capable of reducing temperature, the temperature reducing time is greatly shortened, and electric energy can be saved.

As shown in fig. 1 to 3, the main casing 2 includes a first casing 21 coated at the bottom end of the liner 1, and a second casing 22 coated on the circumferential outer wall of the liner 1, where the first casing 21 is provided with an air inlet 7, and the second casing 22 is provided with an air outlet 8 at a position corresponding to the top end of the fan housing 4. The air supply element 5 can suck the cold air outside the main housing 2 into the main housing 2 through the air inlet 7 on the first housing 21, and then convey the cold air into the air conveying channel 3; because the fan housing 4 is spaced from the outer side wall of the inner container 1 by a certain distance, after the cold air is blown from the fan housing 4 to the outer side wall of the inner container 1, the cold air is discharged from a gap between the top of the fan housing 4 and the outer side wall of the inner container 1 and then discharged to the outside of the main casing 2 through the air outlet 8.

As shown in fig. 6, a heating assembly and a control board assembly 9 are disposed on the bottom surface of the liner 1, and the air supply element 5 and the heating assembly are electrically connected with the control board assembly 9. The start and stop of the air supply element 5 and the heating assembly are uniformly controlled by the control panel assembly 9.

As shown in fig. 1, a water outlet nozzle 10 is arranged on one side of the top of the main housing 2, a water pump 11 is arranged on the outer side of the bottom of the inner container 1, a water inlet of the water pump 11 is communicated with the inner side of the bottom of the inner container 1, a water outlet of the water pump 11 is communicated with the water outlet nozzle 10 through a pipeline, and the water pump 11 is connected with the control panel assembly 9. After the hot water in the inner container 1 is cooled to a proper use temperature, the hot water in the inner container 1 can be conveyed to the water outlet nozzle 10 for discharging by controlling the water pump 11 through the control panel assembly 9.

As shown in fig. 1, a control display panel 12 is disposed on one side of the water outlet nozzle 10, and the control display panel 12 is connected with the control panel assembly 9. The user can manipulate and observe the operation state of the vacuum flask by manipulating the display panel 12.

As shown in fig. 4, the wind direction at the air outlet of the air supply element 5 is tangential to the spiral direction of the bottom surface of the air delivery channel 3. Therefore, the loss of wind speed and wind pressure when the cold wind blown out by the air supply element 5 enters the air conveying channel 3 can be further reduced, so that the cold wind has higher wind speed and wind pressure when flowing in the whole air conveying channel 3.

In this embodiment, the air supply element 5 is a volute fan or a blower.

As shown in fig. 1 and 2, a bottle cap assembly 13 for covering the top opening of the liner 1 is provided at the top of the main housing 2.

As shown in fig. 1 and 2, a handle 14 is provided on the top of the main housing 2.

It is to be understood that the above examples of the present utility model are provided for clarity of illustration only and are not limiting of the embodiments of the present utility model. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (10)

1. The utility model provides a heat dissipation vacuum flask, is including being used for boiling inner bag (1) and cladding in inner bag (1) outlying main shell (2), its characterized in that is equipped with the cladding between inner bag (1) and main shell (2) the lateral wall of inner bag (1) and can to the heat dissipation wind channel subassembly of the all-round air supply of lateral wall of inner bag (1).

2. The heat dissipation vacuum flask according to claim 1, wherein the heat dissipation air duct component comprises an air conveying channel (3) arranged at the bottom end of the inner container (1) and arranged along the circumference of the bottom end of the inner container (1), and an air cover (4) wrapping the outer side of the side wall of the inner container (1), the top end of the air conveying channel (3) is communicated with the bottom end of the air cover (4), the bottom surface of the air conveying channel (3) is in a spiral ascending shape, the lowest end of the bottom surface of the air conveying channel (3) is connected with an air supply element (5), a plurality of air blowing holes (6) are formed in one side, close to the side wall of the inner container (1), of the air cover (4) and the outer side wall of the inner container (1) are spaced by a certain distance.

3. The heat dissipation vacuum flask as defined in claim 2, wherein the main housing (2) comprises a first housing (21) coated at the bottom end of the inner container (1) and a second housing (22) coated on the circumferential outer wall of the inner container (1), the first housing (21) is provided with an air inlet hole (7), and the second housing (22) is provided with an air outlet hole (8) at a position corresponding to the top end of the fan housing (4).

4. The heat dissipation vacuum flask as defined in claim 2, wherein a heating component and a control board component (9) are arranged on the bottom surface of the inner container (1), and the air supply element (5) and the heating component are electrically connected with the control board component (9).

5. The heat dissipation vacuum flask as defined in claim 4, wherein a water outlet nozzle (10) is arranged on one side of the top of the main housing (2), a water pump (11) is arranged on the outer side of the bottom of the inner container (1), a water inlet of the water pump (11) is communicated with the inner side of the bottom of the inner container (1), a water outlet of the water pump (11) is communicated with the water outlet nozzle (10) through a pipeline, and the water pump (11) is connected with the control panel assembly (9).

6. The heat dissipation thermos flask as defined in claim 5, wherein a control display panel (12) is provided on one side of the spout (10), and the control display panel (12) is connected to the control panel assembly (9).

7. A heat dissipating vacuum flask as defined in claim 2, wherein the direction of the air at the air outlet of the air supply element (5) is tangential to the spiral direction of the bottom surface of the air delivery channel (3).

8. A heat dissipating vacuum flask as claimed in claim 2, characterized in that the air supply element (5) is a volute fan or a blower.

9. A heat dissipating boiled water bottle according to claim 1, wherein the top of the main housing (2) is provided with a cap assembly (13) for closing the top opening of the inner container (1).

10. A heat dissipating boiled water bottle according to claim 1, wherein the top of the main housing (2) is provided with a handle (14).

Images