CN216693704U - Built-in energy-saving intelligent electric heating stove - Google Patents

Abstract

The application relates to a built-in energy-saving intelligent electric heating stove which comprises a protective shell, a water storage tank, a power supply, a heating pipe, a water suction pump and a plurality of heating pipes, wherein the water storage tank and the power supply are fixed inside the protective shell; the heating tube includes electric heat pole and heat conduction section of thick bamboo, and the electric heat pole card inlays in storage water tank inner wall and links with the power electricity, and the heat conduction section of thick bamboo is sealed heat conduction material, and heat conduction section of thick bamboo opening is towards the storage water tank inner wall that the electric heat pole card inlayed, heat conduction section of thick bamboo and storage water tank threaded connection, and this application has the effect that reduces water and heating element contact and lead to the circuit short circuit.

Description

Built-in energy-saving intelligent electric heating stove

Technical Field

The application relates to the technical field of heating engineering, in particular to a built-in energy-saving intelligent electric heating stove.

Background

At present, with the increasing shortage of non-renewable resources, the heating by using natural gas is limited, so that the use of an electric heating stove is brought to the schedule. The electric heating stove is a clean and environment-friendly heating product and can be used in a narrow range. The electric heating stove is convenient to carry and move, and can control the switch of the equipment to enable the ambient temperature to reach the set temperature, so that people can heat and the electric heating stove is stopped when no people are available.

Research personnel discover in the research improvement, at electric heating stove during operation, the heating stove produces the heat transfer effect through the inside heating element of storage water tank with water heating to make indoor temperature promote, but the heating element in the storage water tank easily contacts with the water in the storage water tank, has the defect that the circuit easily shorts circuit.

SUMMERY OF THE UTILITY MODEL

In order to embody and reduce water and lead to the circuit short circuit with the contact of heating element, this application provides a built-in energy-conserving intelligent electric heating stove.

The application provides a pair of built-in energy-conserving intelligent electric heating stove adopts following technical scheme:

a built-in energy-saving intelligent electric heating stove comprises a protective shell, a water storage tank, a power supply, heating pipes, a water suction pump and a plurality of heating pipes, wherein the water storage tank and the power supply are fixed inside the protective shell; the heating tube comprises an electric heating rod and a heat conducting tube, the electric heating rod is clamped and embedded in the inner wall of the water storage tank and is electrically connected with a power supply, the heat conducting tube is made of a sealing heat conducting material, the opening of the heat conducting tube faces to the inner wall of the water storage tank, which is clamped and embedded by the electric heating rod, and the heat conducting tube is in threaded connection with the water storage tank.

By adopting the technical scheme, after the water is injected and the power supply is started to drive the water flow to move, the heating pipe heats the flowing water. Because the heating tube is sealed in the water storage tank and is not contacted with liquid, the short circuit phenomenon is not easy to occur at the electric connection part of the heating tube and the power supply.

Optionally, a water outlet pipe is arranged below the heating pipe, penetrates through the side wall of the protective shell and is fixedly communicated with the heating pipe; the water outlet pipe is provided with a control valve for controlling the water discharge of the water outlet pipe.

By adopting the technical scheme, the control valve can be switched on and off as required, and the waste water in the water storage tank and the heating pipe is discharged from the water outlet pipe.

Optionally, the water storage tank is a transparent toughened glass box.

Through adopting above-mentioned technical scheme, because the toughened glass material easily conducts heat, also easily follow the condition in the outside observation storage water tank.

Optionally, a sealing rubber ring is arranged on the water storage tank, and the sealing rubber ring is sleeved and fixed at the communication position of the heating pipe and the water storage tank.

By adopting the technical scheme, the sealing rubber ring can reduce the occurrence of water leakage caused by the communication of the heating pipe and the water storage tank.

Optionally, a plurality of ventilation grooves are formed in the side wall, perpendicular to the ground, of the protective shell, and the ventilation grooves are arranged in an array mode along the length direction of the protective shell in the perpendicular direction.

Through adopting above-mentioned technical scheme, because the protective housing itself is not heat-conducting, and air current is through passing ventilation slot and heating pipe and storage water tank contact in the air, can be with heat transfer to outside the heating stove.

Optionally, an observation window is arranged on the protective shell, the observation window is a toughened glass plate, the observation window is clamped and embedded on one side wall of the protective shell perpendicular to the ground along the direction perpendicular to the ground, and the position of the observation window on the protective shell corresponds to the water storage tank.

By adopting the technical scheme, the water level condition in the water storage tank can be conveniently observed by the observation device, and a user can conveniently determine when water is injected and discharged.

Optionally, a plurality of groups of rollers are further arranged on the protective shell, the rollers are all fixed on the side wall of the protective shell close to the ground, and the rollers are distributed in an array along the length direction of the side wall of the protective shell close to the ground.

Through adopting above-mentioned technical scheme, the gyro wheel is convenient for electric heating stove whole indoor removal.

Optionally, a push rod is further arranged on the protective shell, the push rod is fixed to the upper portion of the side wall, perpendicular to the ground, of the protective shell, and the push rod is arranged along the direction of the horizontal ground.

Through adopting above-mentioned technical scheme, the catch bar can cooperate the gyro wheel to act together, has made things convenient for the user to remove the electric heating stove indoor and has placed.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the contact of water and components in the heating tube is reduced to cause short circuit of a circuit;

2. the water in the water storage tank is convenient to check and replace;

3. has good heat transfer performance;

4. is convenient to move indoors and is convenient to place.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present application;

FIG. 2 is a cross-sectional view of an embodiment of the present application;

fig. 3 is an exploded view for highlighting the heat-generating tube.

In the figure, 1, a protective shell; 11. a ventilation slot; 12. an observation window; 2. a water storage tank; 21. a water injection pipe; 22. sealing the rubber ring; 3. a heat generating tube; 31. an electric heating rod; 32. a heat conducting tube; 4. a power source; 5. a heating pipe; 51. a water outlet pipe; 511. a control valve; 6. a water pump; 7. a roller; 71. a rotating seat; 72. a rolling wheel; 8. a push rod.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses a built-in energy-conserving intelligent electric heating stove.

Referring to fig. 1, a built-in energy-saving intelligent electric heating stove comprises a protective shell 1, a water storage tank 2, a power supply 4, a heating pipe 5, a water pump 6 and a plurality of heating pipes 3, wherein the water storage tank 2 and the power supply 4 are fixed inside the protective shell 1, the water storage tank 2 is located above the inside of the protective shell 1, the heating pipe 5 is located below the water storage tank 2, one end of the heating pipe 5 is fixedly communicated with one end of the side wall of the bottom of the water storage tank 2, and the other end of the heating pipe is fixedly communicated with the other end of the side wall of the bottom of the water storage tank 2. The water pump 6 is fixed on the outer wall of the heating pipe 5 and communicated with the heating pipe 5. The heating pipes 3 are all fixed in the water storage tank 2, and the power supply 4 is respectively electrically connected with the heating pipes 3 and the water pump 6.

Referring to fig. 2 and 3, a plurality of heating tubes 3 are arranged inside the water storage tank 2, the heating tubes 3 are fixed on the inner wall of one side of the water storage tank 2 perpendicular to the ground, and the heating tubes 3 are distributed along the horizontal direction at equal intervals. The heating tube 3 includes an electric heating rod 31 and a heat conducting tube 32, the electric heating rod 31 is made of metal material with high resistivity, in this embodiment, the electric heating rod 31 may be a nickel-chromium alloy rod, the electric heating rod 31 is vertically inserted and embedded in the inner wall of the water storage tank 2 where the heating tube 3 is located, and the electric heating rod 31 is electrically connected with the power supply 4. The heat conduction cylinder 32 is a cylinder with an opening at one end, the heat conduction cylinder 32 is a sealing heat conduction material, and the heat conduction cylinder 32 can be a toughened glass cylinder in the embodiment. The outer wall of the heat conducting cylinder 32 is provided with threads, and the heat conducting cylinder 32 wraps the electric heating rod 31 and then is in threaded connection with the inner wall of the water storage tank 2 where the electric heating rod 31 is located. Waterproof glue is coated at the joint of the heat conducting cylinder 32 and the inner wall of the water storage tank 2.

Referring to fig. 2, the water storage tank 2 is a transparent glass fiber reinforced plastic water tank, a water injection pipe 21 is disposed on a far side wall of the water storage tank 2, the water injection pipe 21 vertically penetrates through the protective housing 1, and the water injection pipe 21 is communicated with the water storage tank 2. The heating pipe 5 is provided with a water outlet pipe 51, the water outlet pipe 51 is positioned on the pipe wall of the heating pipe 5 close to the ground, the water outlet pipe 51 vertically penetrates through the protective shell 1, and the water outlet pipe 51 is communicated with the heating pipe 5. The water outlet pipe 51 is provided with a control valve 511, and the control valve 511 vertically penetrates through the protective shell 1 close to the water outlet pipe 51 and then is communicated with the water outlet pipe 51. The water storage tank 2 is also provided with a sealing rubber ring 22, and the sealing rubber ring 22 is sleeved and fixed at the communication part of the water storage tank 2 and the heating pipe 5.

Referring to fig. 1 and 2, the protective housing 1 is a hollow cube, an observation window 12 is arranged on the protective housing 1, the observation window 12 is a strip-shaped transparent glass fiber reinforced plastic plate, the observation window 12 is located on one side wall of the protective housing 1 perpendicular to the ground and corresponds to the position of the water storage tank 2 inside the protective housing 1, and the observation window 12 is connected with the protective housing 1 in a snap-fit manner along the direction perpendicular to the ground. The observation window 12 is provided with a graduated scale for observing the water storage capacity of the water storage tank 2. A plurality of ventilation grooves 11 are formed in the side wall, perpendicular to the ground, of the protective shell 1, the ventilation grooves 11 are arranged in the horizontal direction, and the adjacent ventilation grooves 11 are arranged in the vertical direction at equal intervals.

Referring to fig. 1 and 2, a push rod 8 and two sets of rollers 7 are further arranged on the protective shell 1, the push rod 8 is a cylindrical rod, the push rod 8 is located on the upper portion of one of the side walls of the protective shell 1, the side wall is perpendicular to the ground, the push rod 8 is fixedly connected with the protective shell 1, and the push rod 8 is arranged along the direction of the horizontal ground. Two sets of gyro wheels 7 all are located the lateral wall of the ground of subsides of protective housing 1, and the equal symmetric distribution of every group gyro wheel 7, the symmetry axis all sets up along the length trend of the lateral wall of the ground of protective housing 1 subsides, and two sets of gyro wheels 7 are fixed in the both ends that the lateral wall of the ground of protective housing 1 pastes respectively. The roller 7 comprises a rotating seat 71 and a rolling wheel 72, the rotating seat 71 is rotatably connected to the ground-contacting side wall of the protective shell 1, and the rolling wheel 72 is rotatably connected to the end face, close to the ground, of the rotating seat 71.

The implementation principle of this application embodiment built-in energy-conserving intelligent electric heating stove does: water is injected into the water storage tank 2 from the water injection pipe 21, the water injection depth is observed through the observation window 12, after the water injection is completed, the power supply 4 is started to enable the heating pipe 3 to heat the water in the water storage tank 2, and meanwhile, the water in the water storage tank 2 is driven by the water suction pump 6 to circularly flow in the heating pipe 5. The heat in the heating pipe 5 is transferred to the indoor through the air from the ventilation slot 11.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a built-in energy-conserving intelligent electric heating stove which characterized in that: the heating water tank comprises a protective shell (1), a water storage tank (2), a power supply (4), a heating pipe (5), a water suction pump (6) and a plurality of heating pipes (3), wherein the water storage tank (2) and the power supply (4) are fixed inside the protective shell (1), a water injection pipe (21) is fixed above the water storage tank (2), the water injection pipe (21) penetrates through the protective shell (1) and is communicated with the water storage tank (2), the plurality of heating pipes (3) are fixed inside the water storage tank (2), one end of the heating pipe (5) is communicated with one side below the water storage tank (2), the other end of the heating pipe is communicated with the other side below the water storage tank (2), the water suction pump (6) is fixed on the outer wall of the heating pipe (5) and is communicated with the heating pipe (5), and the power supply (4) is electrically connected with the water suction pump (6); the heating pipe (3) comprises an electric heating rod (31) and a heat conducting cylinder (32), the electric heating rod (31) is embedded in the inner wall of the water storage tank (2) and is electrically connected with the power supply (4), the heat conducting cylinder (32) is made of a sealed heat conducting material, the opening of the heat conducting cylinder (32) faces to the inner wall of the water storage tank (2) embedded with the electric heating rod (31), and the heat conducting cylinder (32) is in threaded connection with the water storage tank (2).

2. The built-in energy-saving intelligent electric heating stove according to claim 1, characterized in that: a water outlet pipe (51) is arranged below the heating pipe (5), and the water outlet pipe (51) penetrates through the side wall of the protective shell (1) and is fixedly communicated with the heating pipe (5); the water outlet pipe (51) is provided with a control valve (511) for controlling the water discharge of the water outlet pipe (51).

3. The built-in energy-saving intelligent electric heating stove according to claim 1, characterized in that: the water storage tank (2) is a transparent toughened glass box body.

4. The built-in energy-saving intelligent electric heating stove according to claim 3, characterized in that: the water storage tank (2) is provided with a sealing rubber ring (22), and the sealing rubber ring (22) is sleeved and fixed at the communication position of the heating pipe (5) and the water storage tank (2).

5. The built-in energy-saving intelligent electric heating stove according to claim 1, characterized in that: the protective housing (1) is perpendicular to the side wall on the ground and is provided with a plurality of ventilation grooves (11), and the ventilation grooves (11) are arranged in an array mode along the length direction of the protective housing (1) in the vertical direction.

6. The built-in energy-saving intelligent electric heating stove according to claim 5, characterized in that: the water storage tank is characterized in that an observation window (12) is arranged on the protective shell (1), the observation window (12) is a toughened glass plate, the observation window (12) is embedded on one side wall of the protective shell (1) perpendicular to the ground along the direction perpendicular to the ground, and the position of the observation window (12) on the protective shell (1) corresponds to the water storage tank (2).

7. The built-in energy-saving intelligent electric heating stove according to claim 6, characterized in that: still be provided with several groups of gyro wheels (7) on protective housing (1), gyro wheel (7) all are fixed in protective housing (1) and press close to the lateral wall on ground, and gyro wheel (7) move towards the array along the length of protective housing (1) ground lateral wall and distribute.

8. The built-in energy-saving intelligent electric heating stove according to claim 7, characterized in that: still be provided with catch bar (8) on protective housing (1), catch bar (8) are fixed in protective housing (1) perpendicular to the lateral wall upper portion on ground, and catch bar (8) set up along horizontal ground direction.

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