A multi-functional module and insulated box for deodorizing birds
By using a detachable multi-functional module design, combined with the synergistic effects of exhaust, negative ions, ozone, and activated carbon, the problems of short circuits in electrical components, large temperature differences, and incomplete odor removal in bird incubators are solved. This achieves uniform heating, sterilization, and deodorization, improving the safety and health benefits of using the incubator.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINGJIANG ZHIXING (SHENZHEN) TECH CO LTD
- Filing Date
- 2025-08-07
- Publication Date
- 2026-06-30
AI Technical Summary
Existing bird incubators suffer from problems such as easy short circuits in electrical components, difficulty in cleaning, large temperature differences, uneven heat transfer, low bacterial kill rate, and incomplete odor removal, which have a negative impact on the health of young birds.
It adopts a detachable multi-functional module, including an exhaust module, a negative ion module, an ozone generator, and activated carbon filter cotton. Through the synergistic effect of air blowing, negative ions, ozone, and activated carbon, it achieves air circulation, sterilization and deodorization, uniform heating, and disinfection.
It avoids the risk of short circuits in electrical components, provides uniform temperature distribution, improves air circulation, enhances the killing effect of bacteria and viruses, completely removes odors, reduces stress response and health risks, and improves the survival rate of young birds.
Smart Images

Figure CN224419739U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of bird storage technology, specifically to a multifunctional module and insulated box for removing odors from birds. Background Technology
[0002] Incubators used for bird breeding, rescue, or experiments have gradually integrated odor removal functions. Their core design concepts mostly revolve around single purification methods or basic temperature and humidity control. Some incubators use built-in activated carbon filters to adsorb odor gases or ozone generators for periodic disinfection. At the same time, they are equipped with heating wires and temperature control sensors to maintain the temperature inside the incubator. Such devices have solved the problems of odor diffusion and temperature runaway in open breeding environments to a certain extent and are widely used in scenarios such as chick rearing and sick bird rehabilitation.
[0003] Existing incubators with odor-removing functions often have their heating and disinfection electrical components directly embedded inside the enclosure. Cleaning requires either complete wiping or partial disassembly, which can easily lead to moisture seeping into the components and causing short circuits. Furthermore, the corners of the enclosure are difficult to clean thoroughly due to structural obstructions, leaving residual feather dust and droppings as breeding grounds for bacteria. Current equipment often relies on a single-sided heating wire or a bottom heating plate for heat compensation, with heat transfer depending on natural convection, easily creating a temperature difference between the top and bottom. This localized environmental fluctuation can cause stress in chicks or sick birds. In addition, existing incubators rely solely on activated carbon for physical adsorption or ozone disinfection alone, lacking a synergistic mechanism between negative ions, ozone, and filter media. This results in insufficient bacterial and viral kill rates and incomplete removal of odor molecules such as ammonia and hydrogen sulfide. Long-term storage can easily lead to health problems in birds, such as decreased appetite and feather loss, negatively impacting the survival rate of chicks with weaker immune systems. Utility Model Content
[0004] To solve the above-mentioned technical problems, this utility model provides a multi-functional module and insulated box for removing odors from birds.
[0005] The technical solution is as follows:
[0006] A multi-functional module for removing odors from birds includes a functional box, and an exhaust module is fixedly connected inside the functional box. The exhaust module includes an exhaust fan 1, an exhaust fan 2, a radiator 1, a radiator 2, and an exhaust fan 3.
[0007] The first exhaust fan and the second exhaust fan are fixedly connected to each other. The functional box has an exhaust port that is compatible with the first exhaust fan and the second exhaust fan. The positions of the first exhaust fan and the second exhaust fan correspond to the exhaust ports of the functional box. The first radiator is fixedly connected to the side of the first exhaust fan and the second exhaust fan away from the exhaust ports of the functional box. The second radiator is fixedly connected to the side of the first radiator away from the first exhaust fan and the second exhaust fan. The third exhaust fan is fixedly connected to the side of the second radiator away from the first radiator.
[0008] A negative ion module is fixedly connected inside the functional box. The negative ion module includes a negative ion generator and a negative ion brush wire. The negative ion generator is fixedly connected inside the functional box, and the negative ion brush wire is fixedly connected to the negative ion generator.
[0009] An ozone generator is fixedly connected inside the functional box.
[0010] Furthermore, an adjustment module is fixedly connected to the function box, and the adjustment module includes a temperature decrease button, a temperature increase button, a ventilation button, a heating button, a switch button, and an adjustment plate;
[0011] The adjustment plate is fixedly connected to the outer surface of the function box. The temperature decrease button, temperature increase button, ventilation button, heating button, and switch button are sequentially installed on the side of the adjustment plate located on the outside of the function box. A display screen is fixedly connected to the side of the function box near the adjustment module.
[0012] Furthermore, a display screen is fixedly connected to the outer surface of the function box near the adjustment module, a heating power board is fixedly connected to the inside of the function box, and a negative ion module is fixedly connected to the inside of the function box.
[0013] Furthermore, the bottom of the functional box is hollowed out, and a constant temperature heating module is fixedly connected to the middle of the hollowed-out part of the functional box. The constant temperature heating module includes a constant temperature box, a constant temperature cover, a heating wire, a blower, and a temperature sensor.
[0014] The constant temperature box is fixedly connected to the middle of the hollow part of the functional box. The constant temperature cover is snapped into the bottom of the constant temperature box. The constant temperature cover is set in a mesh shape. The heating wire is fixedly connected to the inside of the constant temperature box. The blower is rotatably connected to the inside of the constant temperature box. The temperature sensor is fixedly connected to the bottom of the outer surface of the functional box. The end of the negative ion brush wire away from the negative ion generator is located below the blower.
[0015] Furthermore, a filter module is fixedly connected inside the functional box, and the filter module includes a filter box, a filter cover, and activated carbon filter cotton.
[0016] The filter box is fixedly connected to both sides of the hollow part of the functional box, and the filter box is symmetrical about the constant temperature box. The filter cover is snapped into the bottom of the filter box, and the activated carbon filter cotton is placed inside the filter box.
[0017] Furthermore, the exhaust module, negative ion module, ozone generator, and constant temperature heating module are all electrically controlled by the heating power board.
[0018] A bird odor-removing incubator uses the aforementioned multi-functional bird odor-removing module;
[0019] It includes an insulated box body, a front door panel rotatably connected to the insulated box body, the front door panel being made of transparent acrylic material, and the insulated box body being detachably connected to the functional box.
[0020] Furthermore, the front door panel has a slot corresponding to the shape and position of the adjustment plate, and magnetic strips are fixedly connected to the edges of the insulated box and the front door panel that are close to each other, and the magnetic properties of the two magnetic strips on the insulated box and the front door panel are opposite.
[0021] Based on the above, the beneficial effects of the multifunctional module and insulated box for odor removal in birds according to this utility model are as follows:
[0022] The detachable function box avoids the risk of short circuits to the electrical components inside the function box during the cleaning of the insulation box. At the same time, removing the function box from the insulation box allows for a more thorough cleaning of the internal space of the insulation box.
[0023] By blowing air, heat can be quickly spread to every corner of the insulation box, avoiding the temperature difference caused by traditional insulation boxes that only rely on local heating. A uniform temperature environment can reduce stress response caused by local overheating or undercooling. In addition, blowing air can also enhance air circulation, and the flow of hot air can reduce the accumulation of local humidity in the insulation box, reducing the risk of mold growth.
[0024] Through the combined action of a negative ion generator, an ozone generator, and activated carbon filter cotton, bacteria, viruses, and fungi inside the incubator can be eliminated in a timely manner during air circulation. It can also effectively remove feather dust or pollen inside the incubator, as well as eliminate odors from gases such as ammonia and hydrogen sulfide. This ensures that the inside of the incubator is sterile and odorless, reduces the stress caused by pathogens to birds, and improves the survival rate of birds stored in the incubator. Attached Figure Description
[0025] Figure 1 This is a three-dimensional schematic diagram of the overall appearance of the components of this utility model;
[0026] Figure 2 This is a three-dimensional schematic diagram of the internal structure of the insulated box of this utility model;
[0027] Figure 3 This is a three-dimensional schematic diagram of the functional box, adjustment module, and display screen of this utility model;
[0028] Figure 4 This is a three-dimensional schematic diagram of the internal structure of the functional box of this utility model;
[0029] Figure 5This is a three-dimensional schematic diagram of the components of this utility model, including the negative ion generator, negative ion brush wire, and constant temperature heating module.
[0030] The reference numerals in the accompanying drawings of this utility model are as follows:
[0031] 1. Insulated cabinet body; 2. Front door panel; 3. Function box;
[0032] 4. Adjustment module; 41. Temperature decrease button; 42. Temperature increase button; 43. Ventilation button; 44. Heating button; 45. Switch button; 46. Adjustment plate;
[0033] 5. Display screen; 6. Heating power board;
[0034] 7. Exhaust module; 71. Exhaust fan one; 72. Exhaust fan two; 73. Radiator one; 74. Radiator two; 75. Exhaust fan three;
[0035] 8. Negative ion module; 81. Negative ion generator; 82. Negative ion brush wire;
[0036] 9. Ozone generator;
[0037] 10. Constant temperature heating module; 101. Constant temperature box; 102. Constant temperature cover; 103. Heating wire; 104. Fan; 105. Temperature sensor;
[0038] 11. Filter module; 111. Filter box; 112. Filter cover; 113. Activated carbon filter cotton. Detailed Implementation
[0039] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.
[0040] The embodiments provided by this utility model will be described in detail below:
[0041] Example 1
[0042] like Figures 2 to 5 As shown, a multi-functional module for removing odors from birds includes a functional box 3, and an exhaust module 7 is fixedly connected inside the functional box 3. The exhaust module 7 includes an exhaust fan 1 71, an exhaust fan 2 72, a radiator 1 73, a radiator 2 74, and an exhaust fan 3 75.
[0043] Exhaust fan 1 71 and exhaust fan 2 72 are fixedly connected to each other. The function box 3 has an exhaust port that is compatible with exhaust fan 1 71 and exhaust fan 2 72. The exhaust fan 1 71 and exhaust fan 2 72 are positioned corresponding to the exhaust port of function box 3. Radiator 1 73 is fixedly connected to the side of exhaust fan 1 71 and exhaust fan 2 72 away from the exhaust port of function box 3. Radiator 2 74 is fixedly connected to the side of radiator 1 73 away from exhaust fan 1 71 and exhaust fan 2 72. Exhaust fan 3 75 is fixedly connected to the side of radiator 2 74 away from radiator 1 73.
[0044] The internal part of the function box 3 is fixedly connected to a negative ion module 8. The negative ion module 8 includes a negative ion generator 81 and a negative ion brush wire 82. The negative ion generator 81 is fixedly connected to the internal part of the function box 3, and the negative ion brush wire 82 is fixedly connected to the negative ion generator 81.
[0045] An ozone generator 9 is fixedly connected inside the function box 3.
[0046] Furthermore, an adjustment module 4 is fixedly connected to the function box 3. The adjustment module 4 includes a temperature decrease button 41, a temperature increase button 42, a ventilation button 43, a heating button 44, a switch button 45, and an adjustment plate 46.
[0047] The adjustment plate 46 is fixedly connected to the outer surface of the function box 3. The temperature decrease button 41, temperature increase button 42, ventilation button 43, heating button 44, and switch button 45 are sequentially installed on the side of the adjustment plate 46 located on the outside of the function box 3. The display screen 5 is fixedly connected to the side of the function box 3 near the adjustment module 4.
[0048] Furthermore, a display screen 5 is fixedly connected to the outer surface of the function box 3 near the adjustment module 4, a heating power plate 6 is fixedly connected to the inside of the function box 3, and a negative ion module 8 is fixedly connected to the inside of the function box 3.
[0049] Furthermore, the bottom of the functional box 3 is hollowed out, and a constant temperature heating module 10 is fixedly connected to the middle of the hollowed-out part of the functional box 3. The constant temperature heating module 10 includes a constant temperature box 101, a constant temperature cover 102, an electric heating wire 103, a blower 104, and a temperature sensor 105.
[0050] The thermostatic box 101 is fixedly connected to the middle of the hollow part of the functional box 3. The thermostatic cover 102 is snapped into the bottom of the thermostatic box 101. The thermostatic cover 102 is set in a mesh shape. The heating wire 103 is fixedly connected to the inside of the thermostatic box 101. The fan 104 is rotatably connected to the inside of the thermostatic box 101. The temperature sensor 105 is fixedly connected to the bottom of the outer surface of the functional box 3. The end of the negative ion brush wire 82 away from the negative ion generator 81 is located below the fan 104.
[0051] Furthermore, a filter module 11 is fixedly connected inside the function box 3. The filter module 11 includes a filter box 111, a filter cover 112, and activated carbon filter cotton 113.
[0052] The filter box 111 is fixedly connected to both sides of the hollow part of the function box 3, and the filter box 111 is symmetrical about the constant temperature box 101. The filter cover 112 is snapped into the bottom of the filter box 111, and the activated carbon filter cotton 113 is placed inside the filter box 111.
[0053] Furthermore, the exhaust module 7, negative ion module 8, ozone generator 9, and constant temperature heating module 10 are all electrically controlled by the heating power board 6.
[0054] Example 2
[0055] like Figure 1 and Figure 2 As shown, a bird odor-removing insulated box uses the multi-functional bird odor-removing module in the first embodiment above. The multi-functional bird odor-removing module is installed inside the insulated box body 1 for odor removal.
[0056] It includes an insulated box 1, a front door panel 2 rotatably connected to the insulated box 1, the front door panel 2 being made of transparent acrylic material, and the insulated box 1 being detachably connected to the functional box 3.
[0057] Furthermore, the front door panel 2 has a slot that corresponds to the shape and position of the adjustment plate 46. Magnetic strips are fixedly connected to the edges of the insulated box 1 and the front door panel 2 that are close to each other, and the magnetic properties of the two magnetic strips on the insulated box 1 and the front door panel 2 that are close to each other are opposite.
[0058] Based on the above preferred embodiments, the following is the complete working process and working principle of the above embodiments:
[0059] The working status is:
[0060] The staff places the function box 3 horizontally on the top of the inner cavity of the insulated box 1, so that the function box 3 and the insulated box 1 are locked together. When it is necessary to store the bird, the bird can be placed directly into the insulated box 1. Then the front door panel 2 is closed and locked to the insulated box 1, thus completing the bird storage process.
[0061] It should be noted that if the inside of the insulation box 1 needs to be cleaned, the function box 3 can be slid out of the insulation box 1 in the same way. The detachable function box 3 can avoid the risk of short circuit to the electrical components inside the function box 3 during the cleaning process of the insulation box 1. At the same time, removing the function box 3 from the insulation box 1 can more clearly clean the internal space of the insulation box 1.
[0062] When birds are placed in the incubator 1, staff can press switch button 45. Switch button 45 activates the equipment via heating power board 6. At this time, heating power board 6 controls display screen 5 to show the temperature inside the incubator 1. The temperature inside the incubator 1 can be adjusted according to the bird species. When a temperature increase is needed, staff can press temperature increase button 42. Temperature increase button 42 activates the constant temperature heating module 10 via heating power board 6. The heating wire 103 is energized and begins heating. At the same time, the fan 104 starts simultaneously, blowing air into the incubator. Air is blown inside the insulation box 1, allowing the heat generated by the heating wire 103 to enter the interior of the insulation box 1, thereby achieving the effect of heating the interior of the insulation box 1. The air blowing method allows the heat to be quickly diffused to all corners of the insulation box 1, avoiding the temperature difference caused by the traditional insulation box 1 relying only on local heating. The uniform temperature environment can reduce the stress response caused by local overcooling or overheating. In addition, the air blowing method can enhance air circulation, and the flow of hot air can reduce the accumulation of local humidity inside the insulation box 1, reducing the risk of mold growth.
[0063] It should be noted that when it is necessary to lower the temperature inside the insulation box 1, the operator can press the temperature reduction button 41. The temperature reduction button 41 controls the heating power of the heating wire 103 to decrease through the heating power board 6, or directly turns off the heating function of the heating wire 103, leaving only the blowing function of the fan 104.
[0064] When birds are stored inside the incubator 1, their excrement, leftover food, shed feathers, and other organic matter accumulate inside. If not cleaned promptly, these substances will be decomposed by bacteria, producing harmful gases such as ammonia. Furthermore, the quill hooks and rachis at the base of the bird's feathers secrete keratin powder during growth. Although the bird is stored inside the incubator 1, it will still spread its wings and move around, causing some feather dust to diffuse inside the incubator 1. The synergistic effect of bacteria and feather dust will deteriorate the microenvironment of the incubator 1, making it unsuitable for storing birds inside for extended periods. Therefore, the ventilation module 7 within the functional box 3 can be used to ventilate the air inside the incubator 1. Operators can press the ventilation button 43, which controls the ventilation module 7 to start via the heating power board 6. Ventilation fans 1 and 72 expel air from inside the incubator 1, while ventilation fan 3 expels outside air. The airflow module 7 blows air into the insulated enclosure 1, which can extract air from the enclosure 1 and discharge fresh air from the outside into the functional box 3, thus ensuring air circulation within the insulated enclosure 1. In addition, when the exhaust module 7 extracts gas from the insulated enclosure 1, the gas passes through the activated carbon filter cotton 113 in the filter box 111. The activated carbon filter cotton 113 filters the feather dust that is diffused inside the insulated enclosure 1, preventing the feather dust from spreading around the enclosure 1 after being extracted. This further reduces the air pollution inside the insulated enclosure 1, preventing feather dust particles from being suspended in the enclosed space for a long time and being inhaled by birds, accumulating in the trachea and alveoli. This reduces stress reactions such as wheezing and ruffled feathers when birds are kept in the insulated enclosure 1. Furthermore, by reducing feather dust, bacteria and mold spores cannot be transmitted as carriers, reducing the spread of pathogens.
[0065] It should be noted that when the constant temperature heating module 10 is activated, the heating power board 6 will also activate the negative ion module 8. When the negative ion generator 81 is activated, it will generate negative ions and transmit them to the bottom of the constant temperature heating module 10 through the negative ion brush wire 82. The negative ions are then blown downward into the interior of the insulation box 1 by the blowing action of the fan 104. The negative ions can destroy the molecular protein structure of bacteria, mold and other microorganisms in the insulation box 1, thereby achieving the effect of sterilization. At the same time, when the negative ions come into contact with the positively charged odor gas in the insulation box 1, a neutralization reaction occurs, causing it to lose its charge and settle, thereby eliminating the odor and achieving the effect of sterilization and deodorization at the same time.
[0066] Furthermore, when no birds are stored in the incubator 1, the ozone generator 9 can be activated via the heating power board 6. Once activated, the ozone generator 9 produces ozone, which is stored inside the functional box 3 and blown into the incubator 1 by the fan 104. The oxidizing power of ozone far exceeds that of negative ions and traditional disinfectants, and it can quickly destroy the cell membranes and protein structures of bacteria, viruses, and fungi, achieving a killing effect. The fan 104 can evenly diffuse the ozone to every corner of the incubator, solving the problem of incomplete local disinfection. In addition, ozone can react with ammonia, hydrogen sulfide, and other gas molecules in the incubator, decomposing them into harmless carbon dioxide, water, and inorganic salts, eliminating odors at the source rather than masking them. At the same time, ozone can oxidize and decompose the protein components in feather powder, reducing its risk as a carrier of pathogens. Ozone will also decompose into oxygen after disinfection, avoiding the irritation of birds' skin or respiratory tract by conventional disinfectants, improving disinfection and deodorization without affecting the subsequent storage of birds.
[0067] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A multifunctional module for deodorizing birds, comprising a functional box (3), characterized in that, The internal structure of the functional box (3) is fixedly connected to an exhaust module (7), which includes exhaust fan one (71), exhaust fan two (72), radiator one (73), radiator two (74), and exhaust fan three (75). The exhaust fan 1 (71) and exhaust fan 2 (72) are fixedly connected to each other. The function box (3) is provided with an exhaust port that is compatible with the exhaust fan 1 (71) and exhaust fan 2 (72). The exhaust fan 1 (71) and exhaust fan 2 (72) are located in the same position as the exhaust port of the function box (3). The radiator 1 (73) is fixedly connected to the side of the exhaust fan 1 (71) and exhaust fan 2 (72) away from the exhaust port of the function box (3). The radiator 2 (74) is fixedly connected to the side of the radiator 1 (73) away from the exhaust fan 1 (71) and exhaust fan 2 (72). The exhaust fan 3 (75) is fixedly connected to the side of the radiator 2 (74) away from the radiator 1 (73). The internal part of the functional box (3) is fixedly connected to a negative ion module (8). The negative ion module (8) includes a negative ion generator (81) and a negative ion brush wire (82). The negative ion generator (81) is fixedly connected inside the functional box (3), and the negative ion brush wire (82) is fixedly connected to the negative ion generator (81). An ozone generator (9) is fixedly connected inside the functional box (3).
2. The multi-functional module for deodorizing birds according to claim 1, wherein, An adjustment module (4) is fixedly connected to the function box (3). The adjustment module (4) includes a temperature decrease button (41), a temperature increase button (42), a ventilation button (43), a heating button (44), a switch button (45), and an adjustment plate (46). The adjustment plate (46) is fixedly connected to the outer surface of the function box (3). The temperature decrement button (41), temperature increase button (42), ventilation button (43), heating button (44), and switch button (45) are sequentially installed on the side of the adjustment plate (46) located outside the function box (3). The function box (3) is fixedly connected to the side near the adjustment module (4) with a display screen (5).
3. The multi-functional module for deodorizing birds according to claim 2, wherein, The outer surface of the functional box (3) near the adjustment module (4) is fixedly connected to a display screen (5), a heating power plate (6) is fixedly connected inside the functional box (3), and a negative ion module (8) is fixedly connected inside the functional box (3).
4. The multifunctional module for removing odors from birds according to claim 3, characterized in that, The bottom of the functional box (3) is hollowed out. A constant temperature heating module (10) is fixedly connected to the middle of the hollowed-out part of the functional box (3). The constant temperature heating module (10) includes a constant temperature box (101), a constant temperature cover (102), an electric heating wire (103), a blower (104), and a temperature sensor (105). The constant temperature box (101) is fixedly connected to the middle of the hollow part of the functional box (3). The constant temperature cover (102) is snapped into the bottom of the constant temperature box (101). The constant temperature cover (102) is set in a mesh shape. The heating wire (103) is fixedly connected to the inside of the constant temperature box (101). The blower (104) is rotatably connected to the inside of the constant temperature box (101). The temperature sensor (105) is fixedly connected to the bottom of the outer surface of the functional box (3). The end of the negative ion brush wire (82) away from the negative ion generator (81) is located below the blower (104).
5. The multifunctional module for removing odors from birds according to claim 4, characterized in that, The internal structure of the functional box (3) is fixedly connected to a filter module (11), which includes a filter box (111), a filter cover (112), and activated carbon filter cotton (113). The filter box (111) is fixedly connected to both sides of the hollow part of the functional box (3), and the filter box (111) is symmetrical about the constant temperature box (101). The filter cover (112) is snapped into the bottom of the filter box (111), and the activated carbon filter cotton (113) is placed inside the filter box (111).
6. The multifunctional module for removing odors from birds according to claim 3, characterized in that, The exhaust module (7), negative ion module (8), ozone generator (9), and constant temperature heating module (10) are all electrically controlled by the heating power board (6).
7. A bird odor-removing insulated box, applied to the multi-functional bird odor-removing module according to any one of claims 1 to 6, characterized in that, It includes an insulated box (1), on which a front door panel (2) is rotatably connected. The front door panel (2) is made of transparent acrylic material. The insulated box (1) and the functional box (3) are detachably connected.
8. The bird odor-removing insulated box according to claim 7, characterized in that, The front door panel (2) has a slot that corresponds to the shape and position of the adjustment plate (46). The edges of the insulated box (1) and the front door panel (2) that are close to each other are fixedly connected with magnetic strips, and the magnetic properties of the two magnetic strips on the insulated box (1) and the front door panel (2) that are close to each other are opposite.