CN214905897U

CN214905897U - Novel energy-efficient double-end steam oven

Info

Publication number: CN214905897U
Application number: CN202120760413.5U
Authority: CN
Inventors: 张世忠
Original assignee: Shenzhen Yulong Kitchen Development Co ltd
Current assignee: Shenzhen Yulong Kitchen Development Co ltd
Priority date: 2021-04-14
Filing date: 2021-04-14
Publication date: 2021-11-30
Anticipated expiration: 2031-04-14

Abstract

The utility model relates to the field of energy conservation and environmental protection, and discloses a novel high-efficiency energy-saving double-head steam furnace, which comprises a furnace body, wherein the furnace body is internally connected with a snake-shaped heat conduction pipe, the outer side of the snake-shaped heat conduction pipe is connected with a connecting frame, the bottom side of the furnace body is connected with an electric heating pipe, the electric heating pipe is opened through the furnace body, the electric heating pipe and the snake-shaped heat conduction pipe, the water in the furnace body is heated and warmed up, the generated steam enters the snake-shaped heat conduction pipe after reaching the boiling point, the steam is contacted with the snake-shaped heat conduction pipe, the heat in the steam is volatilized through the snake-shaped heat conduction pipe, the water in the furnace body is heated, even if the electric heating pipe is powered off, the temperature of the raw water in the furnace body is gradually reduced, the heat in the steam in the snake-shaped heat conduction pipe can be relied on to preserve the heat of the water in the furnace body, and the problem that when the electric heating pipe is opened again is solved, the same electric energy is needed to be consumed to heat the raw water again, and the energy-saving effect is poor.

Description

Novel energy-efficient double-end steam oven

Technical Field

The utility model relates to an energy-concerving and environment-protective field specifically is a novel energy-efficient double-end steam oven.

Background

The steam oven is an indispensable tool in modern kitchens, is commonly used for steaming rice, steamed bread and the like, and the conventional double-head steam oven heating mode adopts an electric heating tube to directly heat water and utilizes high-temperature steam to heat food.

There are multiple steam stoves in the existing market, but these steam stoves ubiquitous, after the electrothermal tube outage, the inside raw water temperature of furnace body descends gradually, when opening the electrothermal tube once more, need consume same electric energy and heat the raw water once more, and energy-conserving effect is relatively poor, and the inside incrustation scale of steam stove is in the cleaning process, needs to spend a large amount of water resources, consequently, technical staff in the field provides a novel energy-efficient double-end steam stove to solve the problem that proposes in the above-mentioned background art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel high-efficient energy-conserving double-end steam oven to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

a novel high-efficiency energy-saving double-head steam furnace, which comprises a furnace body, wherein a wind shield is connected above the furnace body, the lower part of the furnace body is connected with four supporting legs, the interior of the furnace body is provided with a fourth through hole, a water inlet pipe is connected at the position of the outer side of the furnace body close to the fourth through hole, a third through hole is arranged at the position of the inner part of the furnace body close to the lower part of the fourth through hole, the outer side of the furnace body close to the third through hole is connected with a drain pipe, the inner part of the furnace body is connected with a group of heated holes far away from the third through hole, a first through hole is connected with the position far away from the heated hole in the furnace body, a snake-shaped heat conduction pipe is connected with the position near the first through hole in the furnace body, the outer side of the snake-shaped heat conduction pipe is connected with a group of connecting frames, the connecting frames are connected with the furnace body, and the bottom side of the furnace body is connected with an electric heating pipe.

As a further aspect of the present invention: the position that first through-hole was kept away from to the inside of furnace body has seted up the second through-hole, the position that the inside of furnace body is close to the second through-hole is connected with the shower nozzle, one side of furnace body is connected with the controller, the opposite side of furnace body is connected with the backup pad, the top of backup pad is connected with the condenser, the condenser is connected with snakelike heat pipe, one side of condenser is connected with the water pipe, there is the storage water tank one side of condenser through water piping connection, the storage water tank is connected with the condenser, there is the booster pump one side of storage water tank through water piping connection, the booster pump is connected with the backup pad, one side of booster pump is connected with the shower nozzle through the water pipe.

As a further aspect of the present invention: and the outer sides of the drain pipe and the water inlet pipe are both provided with connecting flanges.

As a further aspect of the present invention: the electric heating tube is electrically connected with the controller through a circuit.

As a further aspect of the present invention: the snakelike heat conduction pipe is a component made of copper.

As a further aspect of the present invention: the nozzle is a component made of a nickel-based alloy material.

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

1. through the furnace body, electrothermal tube and snakelike heat pipe, open the electrothermal tube, heat the intensification for the inside water of furnace body, reach the boiling point after, the vapor that produces gets into inside the snakelike heat pipe, contact with snakelike heat pipe through vapor, volatilize the heat in the vapor through snakelike heat pipe, the water to the furnace body inside is anti-hot, even behind the electrothermal tube outage, the inside raw water temperature of furnace body descends gradually, still can rely on the heat in the inside vapor of snakelike heat pipe, keep warm for the inside water of furnace body, solved when opening the electrothermal tube once more, need consume same electric energy and heat the raw water once more, the relatively poor problem of energy-conserving effect.

2. Through the condenser, the storage water tank, booster pump and shower nozzle, inside the inside vapor of snakelike heat conduction pipe gets into the condenser, convert to liquid back along the water pipe preserve to the storage water tank in, after the heating is ended, open the booster pump, utilize the inside water of storage water tank to enter the shower nozzle along the water pipe input, wash the incrustation scale of furnace body inside, avoided washing through the extra income water, solved the inside incrustation scale of steam boiler in the cleaning process, need spend the problem of a large amount of water resources.

Drawings

FIG. 1 is a schematic structural view of a novel high-efficiency energy-saving double-head steam boiler;

FIG. 2 is a front sectional view of a furnace body in a novel high-efficiency energy-saving double-head steam furnace;

FIG. 3 is a side view of the furnace body in a new high-efficiency energy-saving double-head steam furnace.

In the figure: 1. a wind deflector; 2. a condenser; 3. a water storage tank; 4. a booster pump; 5. a support plate; 6. a furnace body; 601. a first through hole; 602. a second through hole; 603. a third through hole; 604. a fourth via hole; 7. supporting legs; 8. a heated bore; 9. a controller; 10. a drain pipe; 11. a water inlet pipe; 12. a serpentine heat pipe; 121. a connecting frame; 13. a water pipe; 14. a spray head; 15. an electric heating tube.

Detailed Description

Referring to fig. 1-3, in the embodiment of the present invention, a novel energy-efficient double-ended steam boiler comprises a boiler body 6, a wind shield 1 is connected to the upper portion of the boiler body 6, four supporting legs 7 are connected to the lower portion of the boiler body 6, a fourth through hole 604 is formed in the boiler body 6, a water inlet pipe 11 is connected to the outer side of the boiler body 6 near the fourth through hole 604, a third through hole 603 is formed in the boiler body 6 near the lower portion of the fourth through hole 604, a water outlet pipe 10 is connected to the outer side of the boiler body 6 near the third through hole 603, a set of heated holes 8 is formed in the boiler body 6 at a position far from the third through hole 603, a first through hole 601 is formed in the boiler body 6 at a position far from the heated holes 8, a serpentine heat pipe 12 is connected to the inner portion of the boiler body 6 near the first through hole 601, a set of connecting frames 121 is connected to the outer side of the serpentine heat pipe 12, and a set of connecting frames 121 is connected to the boiler body 6, the bottom side of the furnace body 6 is connected with an electric heating tube 15.

In fig. 1 and 3: a second through hole 602 is arranged in the furnace body 6 far away from the first through hole 601, a spray head 14 is connected in the furnace body 6 near the second through hole 602, one side of the furnace body 6 is connected with a controller 9, the other side of the furnace body 6 is connected with a support plate 5, a condenser 2 is connected above the support plate 5, the condenser 2 is connected with a serpentine heat pipe 12, one side of the condenser 2 is connected with a water pipe 13, one side of the condenser 2 is connected with a water storage tank 3 through the water pipe 13, the water storage tank 3 is connected with the condenser 2, one side of the water storage tank 3 is connected with a booster pump 4 through the water pipe 13, the booster pump 4 is connected with the support plate 5, one side of the booster pump 4 is connected with the spray head 14 through the water pipe 13, water vapor in the serpentine heat pipe 12 enters the condenser 2, the water vapor is converted into liquid and then is stored in the water storage tank 3 along the water pipe 13, after heating, the booster pump 4 is started, utilize the inside water of storage water tank 3 to follow water pipe 13 input into shower nozzle 14, wash the incrustation scale of furnace body 6 inside, avoided washing through extra water, solved the incrustation scale of steam boiler inside in the cleaning process, need spend the problem of a large amount of water resources.

In fig. 1: flange is all installed in the outside of drain pipe 10 and inlet tube 11, with inlet tube 11 and outside water pipe flange joint, guarantees the stable output of water yield, through drain pipe 10, with waste water input to appointed container after sewage or the heating in, avoid causing the pollution to the environment.

In fig. 1 and 2: the electric heating tube 15 is electrically connected with the controller 9 through a circuit, and the controller 9 controls the opening or closing of the electric heating tube 15.

In fig. 2: the serpentine heat pipe 12 is made of copper material, and copper has excellent heat conductivity, so that heat in water vapor can be dissipated through the serpentine heat pipe 12.

In fig. 2: the nozzle 14 is made of a nickel-based alloy material, and the nickel-based alloy has excellent heat resistance and is beneficial to preventing the nozzle 14 from being damaged due to high water temperature.

The utility model discloses a theory of operation is: open electrothermal tube 15, heat the intensification for the inside water of furnace body 6, after reaching the boiling point, the vapor of production gets into inside snakelike heat pipe 12, contact with snakelike heat pipe 12 through vapor, volatilize the heat in the vapor through snakelike heat pipe 12, the water to furnace body 6 inside is anti-hot, even after electrothermal tube 15 outage, the inside raw water temperature of furnace body 6 descends gradually, still can rely on the heat in the inside vapor of snakelike heat pipe 12, keep warm for the inside water of furnace body 6, the inside vapor of snakelike heat pipe 12 gets into inside condenser 2, change into liquid and preserve to in storage water tank 3 along water pipe 13, after the heating end, open booster pump 4, utilize the inside water of storage water tank 3 to follow water pipe 13 input intake nozzle 14, wash the incrustation scale of furnace body 6 inside.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. The novel efficient energy-saving double-head steam furnace comprises a furnace body (6) and is characterized in that a wind shield (1) is connected above the furnace body (6), four supporting legs (7) are connected below the furnace body (6), a fourth through hole (604) is formed in the furnace body (6), a water inlet pipe (11) is connected to the position, close to the fourth through hole (604), of the outer side of the furnace body (6), a third through hole (603) is formed in the position, close to the lower position of the fourth through hole (604), of the inner side of the furnace body (6), a drain pipe (10) is connected to the position, close to the third through hole (603), of the outer side of the furnace body (6), a group of heated holes (8) are formed in the position, far away from the heated holes (8), of the inner side of the furnace body (6), and a first through hole (601) is formed in the position, the furnace is characterized in that a snake-shaped heat conduction pipe (12) is connected to the position, close to the first through hole (601), in the furnace body (6), the outer side of the snake-shaped heat conduction pipe (12) is connected with a group of connecting frames (121), the group of connecting frames (121) are connected with the furnace body (6), and the bottom side of the furnace body (6) is connected with an electric heating pipe (15).

2. The novel high-efficiency energy-saving double-head steam boiler as claimed in claim 1, characterized in that a second through hole (602) is formed in the furnace body (6) at a position far away from the first through hole (601), a spray head (14) is connected to the position close to the second through hole (602) in the furnace body (6), a controller (9) is connected to one side of the furnace body (6), a support plate (5) is connected to the other side of the furnace body (6), a condenser (2) is connected above the support plate (5), the condenser (2) is connected with a serpentine heat pipe (12), a water pipe (13) is connected to one side of the condenser (2), a water storage tank (3) is connected to one side of the condenser (2) through the water pipe (13), the water storage tank (3) is connected with the condenser (2), and a booster pump (4) is connected to one side of the water storage tank (3) through the water pipe (13), the booster pump (4) is connected with the supporting plate (5), and one side of the booster pump (4) is connected with the spray head (14) through a water pipe (13).

3. A novel high-efficiency energy-saving double-head steam oven as claimed in claim 1, characterized in that the outside of the water outlet pipe (10) and the water inlet pipe (11) are provided with connecting flanges.

4. The new high efficiency energy saving double-ended steam oven according to claim 1, characterized in that the electric heating tube (15) is electrically connected with the controller (9) through an electric circuit.

5. A new type of high efficiency energy saving double-ended steam furnace according to claim 2, characterized in that the serpentine heat conducting pipe (12) is made of copper material.

6. A new high efficiency energy saving double ended steam furnace as claimed in claim 2 wherein, said nozzle (14) is a nickel based alloy component.