ENERGY-SAVING SIMULATION PROCESS FOR SNOW-BURNING FIREPLACE

Description

TECHNICAL FIELD

The invention relates to the field of simulated fireplaces, and particularly to an energy-saving simulated process snowfall fireplace.

BACKGROUND TECHNOLOGY

An electric fireplace is a household appliance that mimics the process of a traditional fireplace burning coal, wood, or natural gas by using an electric heater and presents this process through a 3D transistor plane. It features cleanliness, safety, reliability, ease of installation and removal, and high combustion efficiency. Compared to wood or gas fireplaces, it produces no soot, strange odors, or problems associated with flame combustion.

The patent application with the announcement number CN119042689A proposed in the existing technology includes a snowflake scattering sieve comprising a rotating disk and a simulated snowflake guiding pipe, the rotating disk is rotatably connected to the bottom of the simulated snowflake collection hopper, the rotating disk is equipped with multiple small holes matching the size of the simulated snowflakes, the simulated snowflake guiding pipes are set at the bottom of these small holes, each simulated snowflake guiding pipe has a different inclination angle, thus the snowflake scattering sieve can transport the simulated snowflakes to any corner of the front and rear snowfall chambers during rotation, effectively simulating the effect of real snowfall.

The front and back positions of the 3D display components are the front snow chamber and the rear snow chamber. When the front snow chamber and the rear snow chamber simulate snowfall, the overall effect of the fireplace has a strong sense of space.

However, modern simulation fireplaces simulate snowfall effects internally to achieve realism. However, simulating real-world scenarios through snowfall requires the generation of cold air during the process. In simulation fireplaces, only visual realism can be achieved, and there is no way to enhance realism through tactile means.

Therefore, it is necessary to provide an energy-saving simulation process for snow-burning fireplace to solve the above technical problems.

INVENTION CONTENT

This invention provides an energy-saving simulation process for a snowfall fireplace, addressing the issue that current simulation fireplaces set up snowfall effects internally for realism. However, simulating real-world scenarios through snowfall generates cold air during the snowfall process, whereas simulation fireplaces can only achieve a visual simulation effect and cannot enhance the realism through tactile means.

In order to solve the above technical problems, the invention provides an energy saving simulation process snow-burning fireplace, including:

The housing, one side of which is provided with a heating chamber, the center position of the inner wall of the heating chamber is provided with a snow falling device, and the surface of the housing is provided with an air outlet on both sides;

A simulated snowflake storage device, the simulated snowflake storage device is set at the center of the bottom wall of the heating chamber;

Two simulated snow transport devices, two of the simulated snow transport devices are respectively set on the left and right sides of the heating chamber;

Exhaust device, the exhaust device is set between the housing and the heating chamber, the exhaust device includes two conveying pipes, one side of the two conveying pipes sequentially sets multiple exhaust heads from left to right, between the two conveying pipes is connected a U-shaped conveying pipe, one end of one of the conveying pipes is connected to a connecting pipe, both sides of the conveying pipes are equipped with fixing hooks, the inner wall of the heating chamber has an installation hole adapted to match the connecting pipe.

The refrigeration machine body, the refrigeration machine body is connected to one end of the connecting pipe.

The preferred snowfall device includes a first rotary motor, one end of the output shaft of which is fixedly connected to a first rotating rod via a coupling, the bottom end of the first rotating rod is connected to a rotating disc, the rotating disc is equipped with a simulated snowflake collection hopper, and multiple simulated snowflake guide pipes are set at the bottom of the simulated snowflake collection hopper.

The preferred embodiment includes a simulated snowflake collection device comprising a simulated snowflake collection hopper, with simulated snowflake discharge ports on both sides of the simulated snowflake collection hopper, and a simulated snowflake shield plate set on one side of the simulated snowflake discharge port. A compression spring is installed between the simulated snowflake shield plate and the simulated snowflake collection hopper.

The preferred embodiment of the simulated snowflake transport device includes two rotating blades, each end of which is connected to a first rotary shaft, one end of the first rotary shaft is connected to a first bevel gear, one side of the first bevel gear meshes with a second bevel gear, the surface of the second bevel gear is connected to a ball screw, the surface of the ball screw is threaded with a nut, one side of the nut is connected to a transport hopper, one side of the bottom of the transport hopper is connected to a lower pressing block, and one side of the transport hopper is connected to a rotating shield through a rotating shaft.

Preferably, the heating chamber is provided with a ventilation plate on both sides of the inside, and the top and bottom of the ventilation plate on one side are connected with a protruding plate.

Preferably, the surface of the refrigeration machine body is provided with a protective cover.

Preferably, one side of the protective cover is provided with a disassembly component, the disassembly component includes a rectangular slot, one side of the interior of the rectangular slot is provided with a heat dissipation net, between the heat dissipation net and the protective cover is provided with a fixing block, between the fixing block and the protective cover is provided with a bolt.

Compared with related technologies, the energy saving simulation process snow-burning stove provided by this invention has the following beneficial effects:

This invention provides an energy-saving simulation process for a snowfall fireplace, where multiple air outlets are set on both the upper and lower sides inside the heating chamber, along with U-shaped conveying pipes, connecting pipes, and refrigeration unit components cooperating with the snowfall device, simulated snow collection device, and simulated snow transportation device. During the simulated snowfall process, cold air can flow outward from the outlets, thus achieving realistic snowfall operations both visually and tactically, enhancing the authenticity of the entire device.

FIGURE DESCRIPTION

FIG. 1 is a structural diagram of the first embodiment of an energy saving simulation process snow-burning fireplace provided by the invention;

FIG. 2 is a structural diagram of the interior of the processing cavity in the first embodiment shown in FIG. 1;

FIG. 3 is an enlarged view of part A shown in FIG. 2;

FIG. 4 is an enlarged view of part B shown in FIG. 2;

FIG. 5 is an enlarged view of part C shown in FIG. 4.

FIG. 6 is a structural diagram of the second embodiment of the energy saving simulation process snow-burning fireplace provided by the invention;

FIG. 7 is an enlarged view of part D shown in FIG. 6.

The number in the figure: 1. Shell; 2. Heating chamber; 3. Air outlet;

4. Snowfall device; 41. First rotary motor; 42. First rotating rod; 43. Rotary disk; 44. Simulation snowflake concentrating hopper; 45. Simulation snowflake guiding pipe;

5, simulated snowflake storage device; 51, simulated snowflake storage hopper; 52, simulated snowflake discharge port; 53, simulated snowflake shield plate; 54, compressed spring;

6. Simulation Snowflake Handling Device; 61. Rotary Blade; 62. First Rotary Shaft; 63. First Bevel Gear; 64. Second Bevel Gear; 65. Ball Screw; 66. Handling Bucket; 67. Lower Press Block; 68. Rotary Barrier; 69. Threaded Coupling;

7. Air outlet device; 71. conveying pipe; 72. air outlet head; 73. U-shaped conveying pipe; 74. connecting pipe; 75. installation hole; 76. fixing bolt;

8. Protective cover; 9. Refrigeration unit; 10. Air change plate; 11. Extending plate;

12. Disassemble the components; 121. Rectangular groove; 122. Heat dissipation net; 123. Fixing block; 124. Bolt.

SPECIFIC IMPLEMENTATION METHODS

The following description of the invention is further illustrated by reference to the drawings and embodiments.

First Embodiment

Please refer to FIGS. 1, 2, 3, 4, and 5, where FIG. 1 is a structural diagram of the first embodiment of an energy-saving simulation process snowflake fireplace provided by this invention; FIG. 2 is a structural diagram of the processing chamber inside the first embodiment shown in FIG. 1; FIG. 3 is an enlarged view of part A shown in FIG. 2; FIG. 4 is an enlarged view of part B shown in FIG. 2; FIG. 5 is an enlarged view of part C shown in FIG. 4.

An energy-saving simulation process snowflake fireplace comprises:

Shell 1, the side of which is provided with a heating chamber 2, the center position of the inner wall top of which is provided with a snow falling device 4, and the surface side of the shell 1 is provided with an air outlet 3 at the top and bottom;

The simulated snowflake storage device 5 is set at the center position of the bottom of the inner wall of the heating chamber 2;

Two simulation snow transfer devices 6, two of the simulation snow transfer devices 6 are respectively set on the left and right sides inside the heating chamber 2;

Exhaust Device 7, the exhaust device 7 is set between the housing 1 and the heating chamber 2, the exhaust device 7 comprises two conveying pipes 71, on one side of each of the two conveying pipes 71 from left to right are multiple exhaust heads 72, between the two conveying pipes 71 is a U-shaped conveying pipe 73, one end of one of the two conveying pipes 71 is connected to a connecting pipe 74, both sides of the conveying pipe 71 are equipped with fixing hooks 76, the inner wall of the heating chamber 2 has an installation hole 75 that is compatible with the connecting pipe 74;

The refrigeration unit 9, the refrigeration unit 9 is connected to one end of the connecting pipe 74.

The two conveying pipes 71 are respectively installed on the top and bottom of the inner wall of the heating chamber 2 through multiple fixing hooks 76.

The snowfall device 4 includes a first rotary motor 41, one end of the output shaft of which is fixedly connected to a first rotating rod 42 via a coupling, the bottom end of the first rotating rod 42 is connected to a rotating disc 43, the rotating disc 43 is equipped with a simulated snowflake collection hopper 44, and the bottom of the simulated snowflake collection hopper 44 is provided with multiple simulated snowflake guide pipes 45.

The rotating disk 44 has a number of small holes that match the size of the simulated snowflake, and the simulated snowflake guide pipe 45 is set at the bottom of the small holes, and the number of simulated snowflake guide pipes 45 is the same as the number of small holes, and each simulated snowflake guide pipe 45 has a different inclination angle.

The simulated snowflake collection device 5 includes a simulated snowflake collection hopper 51, and on both sides of the simulated snowflake collection hopper 51, there are simulated snowflake discharge ports 52, and on one side of the simulated snowflake discharge port 52, there is a simulated snowflake shield plate 53, and between the simulated snowflake shield plate 53 and the simulated snowflake collection hopper 51, there is a compression spring 54.

When the snowflakes fall downward, they are collected by the simulated snowflake collection hopper 51. After the simulated snowflake collection hopper 51 collects the snowflakes, it rotates the rotating blade 61 through gas drive. When the rotating blade 61 rotates, it drives the first rotary shaft 62 to rotate the first bevel gear 63. When the first bevel gear 63 rotates, it drives the second bevel gear 64 to rotate. When the second bevel gear 64 rotates, it drives the ball screw 65 to rotate. When the ball screw 65 rotates, it moves the surface nut 69. When the surface nut 69 rotates, it moves the conveying hopper 66 up and down. When the conveying hopper 66 moves downward, it contacts the simulated snowflake barrier plate 53 through the bottom pressing block 67 and opens the simulated snowflake barrier plate 53 by squeezing. Then, the simulated snowflakes inside the simulated snowflake collection hopper 51 flow into the interior of the conveying hopper 66. Finally, the conveying hopper 66 is conveyed to the top through the ball screw 65 and the surface nut 69, and the simulated snowflakes inside the conveying hopper 66 are poured into the simulated snowflake concentration hopper 44 for further use.

The simulated snow transfer device 6 is driven by the high temperature air inside the ventilation duct.

The side of the shell 1 is equipped with an audio that can produce the sound of charcoal burning, and the 3D display component can show any weather conditions. The audio and 3D display component produce corresponding sound effects.

The 3D display component shows two scenes: when it snows, the mountain in the 3D display component turns white, and when it is lit, the mountain turns black charcoal.

The snow device 4 and the simulated snow storage device 5 in the front snow chamber and the rear snow chamber are both provided with two sets, and the rotation direction of the same side rotating blades 61 in the front snow chamber and the rear snow chamber is consistent.

The simulated snowflake conveying device 6 includes two rotating blades 61, each end of the two rotating blades 61 is connected to a first rotating shaft 62, one end of the first rotating shaft 62 is connected to a first bevel gear 63, one side of the first bevel gear 63 meshes with a second bevel gear 64, the surface of the second bevel gear 64 is connected to a ball screw 65, the surface of the ball screw 65 is threaded and connected to a nut 69, one side of the nut 69 is connected to a conveying hopper 66, one side of the bottom of the conveying hopper 66 is connected to a lower pressing block 67, one side of the conveying hopper 66 is connected to a rotating shield plate 68 through a rotating shaft.

The heating chamber 2 is provided with a ventilation plate 10 on both sides inside, and the top and bottom of one side of the ventilation plate 10 are connected with a protruding plate 11.

The surface of the refrigeration machine body 9 is provided with a protective cover 8.

The working principle of the energy saving simulation process snowflake fireplace provided by this invention is as follows:

When in use, when simulating snowfall, first start the first rotary motor 41 to rotate the rotating disk 43 through the first rotary rod 42. When the rotating disk 43 rotates the surface simulation snowflake collector 44, when the rotating disk 43 rotates the simulation snowflake collector 44, the internal simulation snowflakes will flow downward through multiple simulation snowflake guide pipes 45 at the bottom of the rotating disk 43. When the simulation snowflakes flow downward through multiple simulation snowflake guide pipes 45 to mimic snowflakes, start the refrigerant main body 9 to deliver cold air through connecting pipe 74 to one of the delivery tubes 71. After the cold air reaches the interior of one delivery tube 71, it is then conveyed through U-shaped delivery pipe 73 to another delivery tube 71. After the cold air reaches the interiors of both delivery tubes 71, it is finally delivered to the exterior through multiple surface outlets 72 and outlet 3.

Compared with related technologies, the energy saving simulation process snow-burning stove provided by this invention has the following beneficial effects:

This invention provides an energy-saving simulation process snowmaking fireplace, which sets up conveying pipes 71 with multiple air outlets 72, U-shaped conveying pipes 73, connecting pipes 74, and the main body of the refrigeration unit 9 in conjunction with the snowmaking device 4, simulation snowflake collection device 5, and simulation snowflake transportation device 6 on both sides inside the heating chamber 2. During the simulated snowfall process, cold air can flow outward from the outlets 3, thus achieving a realistic snowfall operation both visually and tactically, enhancing the authenticity of the entire device.

Second Embodiment

Please refer to FIGS. 6 and 7, a type of energy-saving simulation process snow-burning fireplace is provided based on the first embodiment of this application, and the second embodiment of this application proposes another type of energy-saving simulation process snow-burning stove. The second embodiment is merely an optional method of the first embodiment, and the implementation of the second embodiment will not affect the independent implementation of the first embodiment.

Specifically, the second embodiment of this application provides a different energy-saving simulation process snow-burning stove, the characteristic of which lies in the fact that one energy-saving simulation process snow-burning fireplace has a disassembly component 12 on one side of the protective cover 8, the disassembly component 12 includes a rectangular slot 121, one side inside the rectangular slot 121 is equipped with a heat dissipation net 122, between the heat dissipation net 122 and the protective cover 8, there is a fixing block 123, and between the fixing block 123 and the protective cover 8, there is a bolt 124.

Rectangular slot 121 is provided on the surface of the protective cover 8, and a threaded hole adapted to the bolt 124 is provided on the surface of the protective cover 8.

The working principle of the energy saving simulation process snowflake fireplace provided by this invention is as follows:

When using, when the heat dissipation network 122 is disassembled and cleaned, first remove the bolt 124 between the fixing block 123 and the protective cover 8. After removing the bolt 124, pull the two fixing blocks 123 to separate the heat dissipation network 122 from the rectangular groove 121 for cleaning the heat dissipation network 122.

Compared with related technologies, the energy saving simulation process snow-burning fireplace provided by this invention has the following beneficial effects:

The invention provides an energy-saving simulation process snow-burning fireplace, in which a disassembly component 12 is set on one side of the protective cover 8 to discharge the heat generated by the refrigeration unit 9 while it is working, and to clean the dust from the heat dissipation network 122 after it is disassembled regularly.

The above description is only an embodiment of the present invention and does not limit the scope of the patent of the present invention. Any equivalent structural or equivalent process transformation made by utilizing the content of the present inventions specification and drawings, or directly or indirectly applied to other related technical fields, shall be equally included within the scope of patent protection of the present invention.