RU2062031C1 - Domestic incubator - Google Patents

Abstract

FIELD: production of incubators and thermostatically controlled chambers. SUBSTANCE: small incubator with cylindrical casing mounted on tubular support is constructed for rotation in two planes: through 180 deg about axis of rotation and through 75 deg in axial direction. Heater and fan are mounted in axial alignment with axis of incubator. Incubator has perforated wall, with total area of perforation sections being 1.5-3.0 times smaller than fan channel effective section area. Perforated wall divides incubator chamber into two parts. EFFECT: increased efficiency, simplified construction and enhanced reliability in operation. 3 cl, 1 dwg

Description

 The proposed technical solution relates to the field of poultry farming, and more particularly to the design of incubators for breeding poultry, which can be used in a farm or selective breeding of poultry in small quantities.

Widely known are industrial incubators designed for mass breeding of poultry. The use of these incubators to solve the above problem of breeding poultry in small (50 100 pcs.) Quantities is of little use due to their relatively high cost (capital costs) and energy intensity. In addition, even taking into account the requirements of GOST 21056-75 "Incubators. Technical requirements", the accuracy of maintaining the temperature in them is quite low (± 0.3 ^o C) due to the geometry of industrial incubators and the layout of the egg chamber. This reduces the main indicator of incubator quality percent hatchability. Devices for turning eggs are also complicated, which leads to a large number of egg battles when they are turned.

 A large number of technical solutions are known for modifying the design of incubators, which improve the operation of individual units of incubators, nevertheless, without changing their design as a whole. However, to solve the problem, the breeding of poultry in small quantities with a high percentage of hatchability and a low percentage of battle specified technical solutions are ineffective.

 Recently there have been designs of incubators designed to raise poultry at low productivity (50,300 pcs.), For example, which is selected as a prototype as the closest in terms of function.

However, such an incubator is made according to the traditional design scheme and has the same drawbacks as industrial incubators. Its cost is high, the percentage of hatchability is insufficient (80%), the damage to the eggs when they are turned over is quite large (up to 5 10%), and the process of turning over provides an insufficient rotation angle (45 ± 3 ^o ) at sufficiently large dimensions (630x500x500 mm), which narrows the scope of its application (it can be used only for chicken eggs).

 The proposed technical solution is largely free from these shortcomings.

 The aim of the proposal is to expand the functionality of a domestic incubator while reducing its size and increasing the yield of products (increasing the percentage of hatchability and reducing the percentage of damage to eggs during incubation) by increasing the possibility of changing the angle of inclination of the egg relative to the horizontal plane when it is “rigidly” fixed relative to the body when at the same time increasing the accuracy of temperature maintenance, both in terms of incubator volume and incubation time.

This goal is achieved by the fact that a domestic incubator for breeding poultry containing a thermally insulated case with a lid, a ventilation device, a heater, a temperature control device with a sensor, an egg tray and a housing stand, differs in that the incubator body is cylindrical, mounted on a stand along the axis of the cylinder with the possibility of rotation around the axis by at least 180 ^o and with the possibility of rotation in the plane of the axial section of the housing at least 75 ^o from the horizontal position and fix by at least two positions, the ventilation device is located inside the case, along its axis above the heater and contains a bell, directing the air flow along the axis of the cylinder downward, followed by 180 ^° rotation along the cylindrical surface of the case and the cover, the egg tray is made in the form an annular cellular structure along the periphery of the ventilation device with a bell with the possibility of rigid attachment to the inner surface of the housing, and the mesh structure of the tray is removable and contains a device for rigid fixation of eggs with parallel axis of the eggs and the incubator, between the bottom of the incubator and the tray there is a partition with holes that divides the body into two parts in a plane perpendicular to the axis of the body, and the total area of the perforation holes is 1.5 3 times smaller than the area of the ventilation duct devices.

 In addition, the inner surface of the lid and housing, as well as the partition with holes, is made of highly conductive material, such as aluminum.

 The specified set of features, according to the authors, meets the criterion of "Novelty", since it is not found in the technical solutions known to us.

 At the same time, such a set of features meets the criterion of "Significant differences", since only such a set of features allows us to achieve this goal to expand the functionality of a domestic incubator while reducing its size and increasing the yield of products. (A more detailed proof of the last statement is given below in the description of the example of the implementation of the proposed technical solution).

 The drawing shows a structural diagram of the proposed technical solution.

 The incubator consists of the following main parts.

 1. Thermally insulated enclosure with cover.

 2. Ventilation device.

 3. Heater.

 4. Devices for controlling temperature, turning on the heater and fan.

 5. A temperature sensor located in the egg placement area.

 6. A tray for placement of eggs in the form of a cellular structure.

 7. Devices for fixing eggs in the cellular structure in the form of nets attached to the tray.

8. Stand as a hollow curved pipe, which is the axis of rotation of the housing about its axis allowing the housing to rotate Φ ₁ 180 ^o, simultaneously serving tube for diverting a portion of the heated air.

9. Fixed hinge stand, allowing you to change the inclination of the housing relative to the horizontal plane of the stand at an angle Φ ₂ 75 ^o .

 10. A guide bell of the ventilation device.

 11. Partitions with openings for air passage.

 12. The internal casing of the shell of a heat-conducting material (aluminum).

 13. The limiter of rotation of the incubator body relative to the axis.

 14. Bird eggs.

 The incubator works as follows.

A poultry egg 14 (chicken, duck, goose, etc.) is placed in the tray 6 and fixed in it by the egg fixing device 7. The tray 6 is installed in the housing 1 and is fixed by the housing cover when it is closed. Using the hinge 9, the incubator angle required for this type of egg is set to the horizontal plane (for hens 45 ^o , for ducks 60 ^o , for goose eggs 75 ^o ).

 The temperature control device, turning on the heater and fan 4 is connected to the mains, after which the incubator goes to the set temperature mode automatically. In this case, the heater 3 is periodically turned on, and the fan runs continuously until the incubation process is completed.

Periodically, manually, or, if provided by the design, the incubator body is automatically rotated around the axis of the stand 8 by 180 ^° until it stops against the latch 13. This ensures that without damage to the eggs, they rotate 180 ^° relative to the horizontal plane.

When the fan 2 is operating, air inside the case begins to circulate, passing through the fan 2 from top to bottom, the heater 3, the guiding bell 10, turns 90 ^° and spreads along the bottom of the incubator body. Then, due to the fact that the orifice in the baffle 11 is 1.5 3 times smaller than the orifice of the fan 2, it stops creating a zone of heated air with increased pressure under the partition 11 and a zone with a lower area above the partition with the tray 6 and eggs 14 pressure. Such an incubator device provides a uniform, jet air flow to the tray 6 with eggs 14, and, as a result, their uniform heating over the entire cross-sectional area of the tray 6, which is not found in all known incubator designs. Experiments on a prototype incubator showed that this ensures the accuracy of maintaining the temperature in the working area (egg placement area) ± 0.2 ^o C in volume and ± 0.1 ^o C in incubator operating time (up to 35 days for goose eggs) independently from fluctuations in ambient temperature from 15 to 35 ^o C compared with the prototype, which provides accuracy of only ± 0.5 ^o C. This allowed to increase the percentage of excretion from 65 to 80% in the prototype to 94% in the proposed solution.

 To monitor the temperature in the working area, a standard temperature sensor is installed in the form of a thermally resistive low-inertia thermistor 5, which is electrically connected to a control device 4. To account for and compensate for the eggs' own heat generation, as well as remove carbon dioxide emitted during egg incubation in openings for air inlet and outlet are provided for the lid and the housing, the outlet being the stand pipe 8. A predetermined humidity level inside the incubator is provided due to pouring water through the lid into it once a day (drawing). Thus, the internal shelling of the housing 12 performs a dual function, being, on the one hand, a water bath, and on the other hand, due to its high heat conductivity, equalizes the temperature over the volume of the incubator, increasing the efficiency of the partition with holes 11. The hinge 9 allows the use of the incubator for different types of eggs (ducks, geese, chickens, etc.) and allows you to put the incubator in egg hatching mode (the last three days from 21 days for chickens). In this case, the incubator using the hinge 9 is set horizontally, and the eggs are freed from the cellular structure 6, the fixing devices 7 and placed in the incubator in a horizontal position.

 Currently, a prototype of an incubator for 84 chicken (or 30 goose, or 54 duck eggs) has been manufactured; conducted his full-scale tests for breeding. A high degree of hatching (up to 94%) was achieved with a zero percentage of egg fighting. Planned launch into mass production.

 Compared to the prototype, the average time consumed electric power is reduced from 200 to 40 W, and the dimensions due to the rotation of the case instead of tilting the trays (technical solution of the prototype) are reduced by more than 2 times.

 Tests of the prototype and prototype also allowed us to determine the optimal value of the total cross section of the holes in the partition 11, which turned out 1.5 to 3 times less than the area of the fan inlet section. With a larger and smaller value, the temperature non-uniformity sharply increases over the volume of the incubator's working area, which significantly affects the timing of hatching and the percentage of hatching eggs.

Claims (3)

 1. A household incubator containing a thermally insulated body with a lid mounted on a support element, a ventilation device, a heater, a heating temperature control device with a sensor and an egg tray, characterized in that the incubator is equipped with a partition with openings with a total area of l, 5 3 times smaller than the cross-sectional area of the passage channel of the ventilation device, the mentioned partition is installed under the egg tray perpendicular to the axis of the incubator and divides the incubator into two parts, the incubator body is non-cylindrical, mounted on the supporting element on the axis of the cylinder with the possibility of rotation around it by at least 180 ° and with the possibility of rotation in the plane of the axial section of the housing at least 75 ° from the horizontal position and fixing at least two positions, ventilation device located inside the housing along its axis above the heater and contains a bell directing the air flow along the axis of the cylinder down, followed by 180 ° rotation along the cylindrical surface of the housing and the cover, a tray with s is formed as a removable annular honeycomb structure is disposed on the periphery of the ventilating device, with rigid attachment to the inner surface of the housing and comprises means for rigidly fixing the eggs in the tray with the axis parallel to the major axis of the egg incubator.  2. The incubator according to claim 1, characterized in that the inner surfaces of the housing, the lid and the partition with holes are made of highly heat-conducting material, such as aluminum.  3. Incubator in paragraphs. 1 and 2, characterized in that the supporting element of the housing is made in the form of a curved hollow pipe and is connected to the internal space of the housing with the possibility of leaving part of the air from it.