TWM588957U - Automatic black soldier fly breeding equipment - Google Patents

Abstract

This creation is about a fully automatic black water fly breeding equipment, including: a housing body, is equipped with a breeding space; a temperature detector, in order to detect a temperature value in the breeding space, and the temperature value is higher At a stirring standard value, a stirring signal is output; a stirring unit is provided with a stirring blade extending into the feeding space, the stirring blade is driven to rotate by a power source; a control unit is connected to the temperature detection signal respectively After receiving the stirring signal, the detector and the stirring unit control the power source of the stirring unit to start to drive the stirring blade to start rotating. The stirring blade can be used to break up the organic matter in the feeding space, so that the larvae and the organic matter can evenly contact with the outside air to help them dissipate heat and cool down.

Description

Automatic black water fly breeding equipment

This creation is about a feeding device that uses a stirring unit to quickly and uniformly cool the black water fly breeding space.

According to press, the black water fly is a carrion insect of the water fly family. Its larvae feed on rotten organic matter such as food waste, livestock manure, animal and plant corpses, etc. It is an important part of the natural detritus food chain. In addition to its decomposition, its larvae It is also a very good protein, which can be used for feeding chickens and pigs. Because of its rapid reproduction, large biomass, wide diet, high absorption and conversion rate, easy management, low feeding cost and good animal palatability, etc. It is used for resource utilization and as feed insects.

With the research on the breeding of black water flies, the habits have gradually been understood. The life cycle of black water flies is about 28 days: the egg period is about 3 to 4 days, the larval period is about 18 days, and the pupa after about 4 days. At this stage, the black water fly will become an adult, and the adult black water fly has only about 5 days of life left. Black water fly larvae have six instars, and their food intake increases with age, and before they grow into mature larvae to be pupated, they will leave the food substrate to find dry and cool places to pupate, except for black water flies. During the pupa period, it is preferred to be in a dry and cool place such as a gap. It can also be eaten by a companion as food after avoiding pupa, and after the pupa has become an adult, it only takes water and juice on the leaves. After flying and courting and mating, the female Insects lay eggs.

Among them, the breeding of black water flies is currently carried out in simple plastic containers. The edible biological waste of black water flies is placed, such as kitchen waste or bean dregs, and the water content is controlled at 60% to 70%. After incubation, the black water flies are fed, and then the insect bodies that have grown to the pre-pupa stage are collected manually for use as livestock feed.

At present, the artificial breeding equipment is used, such as the new patent No. M569133 "Biodynamic Ecological Circulation Box" patent case announced on November 1, 107, which discloses that it includes at least a bottom layer and a first layer body. The first layer is stacked above the bottom layer, the first layer has a bearing area, the bottom of the bearing area is provided with a mesh body, the bottom layer has a nutrient collection area, the nutrient collection area corresponds to the mesh body; At least one organic substance and at least one decomposer are put into the load-bearing area of a layered body. The decomposer disturbs organic materials such as kitchen waste and decomposes them to form a variety of amino acids, enzymes and active substances, which are provided to Plant nutrients, and local nutrients fall through the net to the bottom layer, users can recycle the aforementioned nutrients, such as earthworm feces, earthworm liquid fertilizer, etc., can effectively solve the problems caused by waste organic substances, and through The main advantage of natural circulation to improve the environment.

The pre-patent case is for placing organic substances such as kitchen waste and decomposers such as earthworms and black water flies in the organic substance collection area of the first layer to achieve the purpose of decomposing waste organic substances such as household kitchen waste. However, in summer, the larvae of the black water fly will decompose organic matter and produce high temperatures during fermentation, causing the larvae to die or affect growth. In winter, when the temperature is too low, the larvae may freeze to death or affect the growth, so it is not ideal for use.

For this purpose, there is a new patent application No. 108202150 "Feeding Device for Black Water Fly" applied on February 20, 108 in the Republic of China, which discloses: including: a housing body, a feeding space; at least one cold and hot exchange The tube is fixed to the accommodating body, the cold and heat exchange tube passes through the feeding space, and the two ends of the cold and heat exchange tube are respectively provided with an input end and an output end. A fluid is inputted at the input end, so that the fluid exchanges heat with the larvae or organic matter in the feeding space, and then is outputted by the output end. In this way, the temperature of the breeding space can be quickly reduced or increased to help the growth of larvae or the fermentation of organic matter.

The previous case of the patent is a feeding structure that uses a heat exchange method to quickly cool or raise the temperature of the feeding space. However, because the larvae of black water fly and organic matter are mixed together, and the water content makes it stick together, it will cause the organic matter near the heat exchange tube to quickly cool down, while the organic matter away from the heat exchange tube will not cool down. Good, so that the overall heat dissipation is uneven, which will seriously affect the growth of black water fly larvae. Moreover, starting fluid flow for a long time for heat exchange will consume a lot of energy.

This is in view of the above-mentioned shortcomings of the black water fly breeding device currently used. Therefore, this creation provides a fully automatic black water fly breeding equipment, including: an accommodating body with a feeding space; a temperature detector fixed to the accommodating body to detect the feeding space A temperature value, and when the temperature value is higher than a stirring standard value, a stirring signal is output; a stirring unit is fixed to the housing body, the stirring unit is provided with a stirring blade extending into the rearing In the space, the stirring blade is driven to rotate by a power source; a control unit is connected to the temperature detector and the stirring unit respectively, so that after receiving the stirring signal, the stirring blade is controlled The power source of the stirring unit is started to drive the stirring blade to start rotating.

The control unit is provided for inputting and setting the stirring standard value, and the stirring standard value is set to 27°C.

The agitating unit is fixed at a lower position or an upper position of the accommodating body, the agitating blade extends into the bottom or top of the feeding space, and the agitating blade has a single blade or a plurality of blades.

The stirring blade is extended with a shaft, and the other end of the shaft is provided with a first pulley. The first pulley is sleeved with a first belt. The first belt is rotated by the power source. .

The above is provided with a plurality of accommodating bodies and a plurality of stirring blades, and the other end of the shaft of each stirring blade is provided with a second pulley, and between each adjacent second pulley, a The second belt is sleeved and driven, and the power source drives the first pulley, the first belt, the second pulley, and the second belt to drive each other, so that the stirring blades rotate synchronously.

The stirring blade is extended with a shaft, and the other end of the shaft is directly connected to the power source for transmission.

The above control unit is provided with a sending unit, so as to transmit the stirring signal to a handheld electronic device at a remote end, and use the handheld electronic device to install a mobile application for receiving the stirring signal, and through the handheld The electronic device directly controls activation or deactivation of the stirring unit, and remote input of the stirring standard value.

A cold and heat exchange tube and a temperature regulator are further provided, the cold and heat exchange tube is fixed to the housing body, the cold and heat exchange tube passes through the feeding space, and two ends of the cold and heat exchange tube are respectively provided with a An input end and an output end, the temperature regulator is connected to the input end and the output end for circulating a fluid, and the control unit is connected to the temperature regulator by a signal The detector outputs a cooling signal when the temperature value is higher than a cooling standard value, and the control unit automatically controls the temperature regulator to start after receiving the cooling signal.

The control unit is provided for inputting and setting the cooling standard value, and the cooling standard value is set to 33°C.

The control unit is provided with a sending unit, so as to transmit the cooling signal to a remote handheld electronic device, and use the handheld electronic device to install a mobile application for receiving the cooling signal, and through the handheld The electronic device directly controls to start or shut down the temperature regulator, and remotely input the cooling standard value.

The agitating unit is provided on a power pressure cylinder, the power pressure cylinder is provided on a slide rail, and the power pressure cylinder is provided with a telescopic pressure rod, one end of the telescopic pressure rod is coupled to the power source, Therefore, when the temperature detectors in the plurality of housing bodies detect that the temperature value in the feeding space is higher than the stirring standard value, the power pressure cylinder is controlled to slide on the slide rail Move to the position of the rearing space, and then extend through the telescopic pressure rod to drive the stirring blade to move into the rearing space for stirring and heat dissipation.

The bottom of the housing body is provided with an opening or a plurality of openings penetrating to the feeding space, and a valve or a plurality of valves are provided at the opening position, and the bottom of the feeding space is arranged in a plane or funnel shape. The periphery of the opening of the accommodating body is bent inwardly to provide a blocking portion.

According to the above technical features, the following effects can be achieved:

1. When it is detected that the temperature value in the feeding space is higher than the standard value of stirring [for example, 27°C], it will automatically control the power source of the stirring unit to start to drive the stirring blade to start rotating, so that the larvae and organic matter can be uniform To spread out and make full contact with the outside air to help it cool and cool down.

2. When it is detected that the temperature value in the feeding space is higher than the cooling standard value [such as 33°C], it will automatically control the temperature regulator to start, and input low-temperature fluid through the cold and heat exchange tube, which can communicate with the feeding The larvae and organic matter in the space are in contact for heat exchange to take away the heat energy generated by the larvae and organic matter, so that the temperature in the feeding space can be quickly cooled, and the energy consumption of the temperature regulator can be greatly reduced, which can effectively save energy.

3. The system can further send the stirring signal and the cooling signal to the remote handheld electronic device, and directly control the activation or shutdown of the temperature regulator and the stirring unit through the handheld electronic device, and the remote input of the standard stirring value and The standard cooling value can help managers quickly understand the temperature status of the black water fly breeding equipment.

Based on the above technical features, the main functions of the fully automatic black water fly breeding equipment will be clearly presented in the following embodiments.

Please refer to the first picture and the second picture, the first embodiment of the creation includes: accommodating body (1), cold and heat exchange tube (2), temperature regulator (3), temperature detector (4) , Mixing unit (5) and control unit (6), including:

The housing body (1) is provided with a round feeding space (11), the feeding space (11) is used for feeding black water fly larvae, and the food waste or animals can be put into it for feeding Organic matter such as feces. The bottom of the housing body (1) is provided with an opening (12) penetrating to the feeding space (11), and a valve (13) or a plurality of valves (13) are provided at the position of the opening (12), which can be automatically Or manually control the valve (13) to open. In addition, the periphery of the opening of the accommodating body (1) is bent inwardly to provide a blocking portion (14), so as to prevent the larvae from climbing out of the breeding space (11). In addition, the bottom of the feeding space (11) is arranged in a plane or funnel shape.

The cold and heat exchange tube (2) is fixed to the containing body (1) and passes through the feeding space (11). The cold and heat exchange tubes (2) pass through the rearing space (11) in a side-by-side arrangement. And the two ends of the cold and heat exchange tube (2) are respectively provided with an input end (21) and an output end (22), the input end (21) and the output end (22) are penetrated through the accommodating body (1) ), a fluid is input from the input end (21), the fluid is used to exchange heat with the larvae and the organic matter in the feeding space (11), and then output from the output end (22). The flow system can be a liquid or a gas.

The temperature regulator (3) is connected to the input end (21) and the output end (22) for circulating the fluid for heat exchange.

The temperature detector (4) is fixed to the housing body (1), so as to detect a temperature value in the feeding space (11), and output a stirring signal when the temperature value is higher than a stirring standard value Or, when the temperature value is higher than a cooling standard value, a cooling signal is output.

The stirring unit (5) is fixed at a position below the containing body (1). The stirring unit (5) is provided with a stirring blade (51) extending into the bottom of the feeding space (11). The stirring blade (51) is extended with a shaft (52), the other end of the shaft (52) is provided with a first pulley (53), and the first pulley (53) is sleeved with a first belt (54) , The first belt (54) is driven and rotated by a power source (55), through the transmission of the first belt (54), the shaft (52) is connected to the stirring blade (51) in the feeding space ( 11) Internal rotation. The stirring blade (51) has a single blade or a plurality of blades.

Control unit (6), which is connected to the temperature regulator (3), the temperature detector (4) and the stirring unit (5) respectively, so as to automatically control the stirring unit after receiving the stirring signal The power source (55) of (5) is started to drive the stirring blade (51) to start rotating. After receiving the cooling signal, the control unit (6) automatically controls the temperature regulator (3) to start to output the fluid for heat exchange. Furthermore, the control unit (6) can be used to input and set the stirring standard value and the cooling standard value, the stirring standard value is set to 27°C, and the cooling standard value is set to 33°C. Furthermore, the control unit (6) is provided with a sending unit (61), by which the stirring signal and the cooling signal are transmitted to a remote handheld electronic device (62), and the handheld electronic device (62) is used to install a mobile Application program [APP], which can receive the stirring signal and the cooling signal, and can manually control the activation or shutdown of the temperature regulator (3) and the stirring unit (5) through the handheld electronic device (62) , And the remote input of the standard value of stirring and cooling standard, which can help managers quickly understand the temperature status of black water fly breeding equipment.

When in use, as shown in the third figure, an appropriate number of black water fly larvae can be built into the feeding space (11) of the housing body (1), and the food waste that can be eaten by the larvae can be placed regularly Or organic matter (F) such as animal feces for feeding the larvae, and the larvae and the organic matter (F) can be brought into contact with the cold and heat exchange tube (2). By opening the valve (13), the larvae or the organic matter (F) can be discharged at any time. When the temperature is high in summer, the temperature regulator (3) can be used as a cooler for lowering the temperature in the rearing space (11). When the temperature is low in winter, the temperature regulator (3) can choose a heating machine for raising the temperature in the feeding space (11), but the first embodiment of this creation is mainly used for cooling in summer, so No heating machine is used. The first embodiment of the present invention takes the cooling machine to lower the temperature in the feeding space (11) as an example. In this way, when the larvae decompose the organic matter (F) and ferment, a high temperature is generated, causing the temperature in the rearing space (11) to rise. When the temperature detector (4) detects that the temperature value in the feeding space (11) is higher than the stirring standard value [27°C], it will output the stirring signal. After receiving the stirring signal, the control unit (6) controls the power source (55) of the stirring unit (5) to start, so as to drive the stirring blade (51) to start rotating. The agitating blade (51) can disperse the clumped organic matter (F), so that the larvae and the organic matter (F) can be evenly spread out and come into full contact with the outside air to help them dissipate heat and cool down.

When the temperature in the breeding space (11) continues to rise. When the temperature detector (4) detects that the temperature value in the feeding space (11) is higher than the cooling standard value [33°C], it will output the cooling signal. After receiving the cooling signal, the control unit (6) controls the thermostat (3) to start, and inputs the low-temperature fluid to the input end (not shown) so that the fluid can flow through the side-by-side The cold and heat exchange tube (2) can contact the larvae and the organic matter (F) in the feeding space (11) for heat exchange, so as to take away the heat energy generated by the larvae and the organic matter (F), so that the The temperature in the feeding space (11) can be quickly reduced. At the same time, by means of the continuous rotation of the stirring blade (51), the larvae and the organic matter (F) in the feeding space (11) can be brought into full contact with the cold and heat exchange tube (2) to help heat dissipation and cooling And can greatly reduce the energy consumption of the temperature regulator (4) to effectively save energy. The heat energy after the heat exchange can be taken away by the fluid, output through the output end (22), and sent back to the temperature regulator (3) for heat dissipation, and then repeatedly circulated and transported for heat exchange. The temperature of the breeding space (11) can be continuously reduced. In addition, if it is necessary to increase the temperature of the feeding space (11) in winter, the temperature regulator (4) may be a heating machine, and the implementation manner is the same, which is not repeated here.

Please refer to the fourth figure, the second embodiment of the creation includes: accommodating body (1A), cold and heat exchange tube (2A), temperature regulator (3A), temperature detector (4A), stirring unit ( 5A) and control unit (6A). The difference between the second embodiment of the present invention and the first embodiment described above is only that a plurality of accommodating bodies (1A) and a plurality of stirring blades (51A) are provided, and the shaft (52A) of each stirring blade (51A) The other end of each is provided with a first pulley (53A) and a second pulley (56A), and between each adjacent second pulleys (56A), a second belt (57A) can be used respectively Set the transmission, so that the single power source (55A) can be used to pass through the first pulley (53A), the first belt (54A), the second pulley (56A) and the Waiting for the mutual transmission of the second belt (57A), the stirring blades (51A) can be rotated synchronously for heat dissipation, thereby achieving the same effect as the first embodiment.

Please refer to the fifth figure, the third embodiment of the creation includes: accommodating body (1B), cold and heat exchange tube (2B), temperature regulator (3B), temperature detector (4B), stirring unit ( 5B) and control unit (6B). The third embodiment of the present invention differs from the first embodiment described above only in that the stirring unit (5B) is fixed at an upper position of the housing body (1B), and the stirring blade (5B) of the stirring unit (5B) 51B) extends into the top of the rearing space (11B) for installation in accordance with different types of the rearing space (11B), so as to achieve the same effect as the first embodiment.

Please refer to the sixth figure, the fourth embodiment of the creation includes: accommodating body (1C), cold and heat exchange tube (2C), temperature regulator (3C), temperature detector (4C), stirring unit ( 5C) and control unit (6C). The difference between the fourth embodiment of the present invention and the first embodiment described above is only that the other end of the shaft (52C) is directly connected to the power source (55C) for transmission, so that the same effect as the first embodiment can be achieved.

Please refer to the seventh figure, the fifth embodiment of the invention, in which the stirring unit (5D) is arranged on a power cylinder (7D), and the power cylinder (7D) is arranged on a slide rail (71D) Slide up and down. The power pressure cylinder (7D) is provided with a telescopic pressure rod (72D). One end of the telescopic pressure rod (72D) is coupled to the power source (55D) of the stirring unit (5D). 72D) telescopic operation can drive the stirring blade (51D) to move up and down. When the temperature detector (4D) of any housing body (1D) detects that the temperature value in the feeding space (11D) is higher than the stirring standard value, it will control the power pressure cylinder (7D) ) Slide on the slide rail (71D) to the upper position of the feeding space (11D), and then extend through the telescopic pressure rod (72D) to drive the stirring blade (51D) to move down to the feeding Stir heat in the space (11D). In this way, a single stirring unit (5D) can be slid by using the slide rail (71D), and a plurality of accommodating bodies (1D) can be stirred and radiated.

Based on the description of the above embodiments, the operation, use and effects of this creation can be fully understood, but the above-mentioned embodiments are only the preferred embodiments of the creation, and should not be used to limit the implementation of this creation. The scope, that is, simple equivalent changes and modifications made in accordance with the scope of the patent application for the creation and the content of the creation description, are all covered by the scope of the creation.

(1)‧‧‧Accommodation (11)‧‧‧ Feeding space (12) ‧‧‧ opening (13)‧‧‧Valve (14)‧‧‧block (2)‧‧‧cold heat exchange tube (21)‧‧‧input (22)‧‧‧Output (3)‧‧‧Temperature regulator (4)‧‧‧Temperature detector (5)‧‧‧Stirring unit (51)‧‧‧Stirring blade (52)‧‧‧Shaft (53)‧‧‧The first pulley (54)‧‧‧First Belt (55)‧‧‧Power source (6)‧‧‧Control unit (61)‧‧‧Sending unit (62)‧‧‧Handheld electronic device (1A)‧‧‧Accommodation (2A)‧‧‧cold heat exchange tube (3A)‧‧‧Temperature Regulator (4A)‧‧‧Temperature detector (5A)‧‧‧Stirring unit (51A)‧‧‧Stirring blade (52A)‧‧‧Shaft (53A)‧‧‧The first pulley (54A)‧‧‧First Belt (55A)‧‧‧Power source (56A)‧‧‧Second pulley (57A)‧‧‧Second belt (6A)‧‧‧Control unit (1B)‧‧‧Accommodation (11B)‧‧‧ Feeding space (2B) ‧‧‧ cold and heat exchange tube (3B)‧‧‧Temperature Regulator (4B)‧‧‧Temperature detector (5B)‧‧‧Stirring unit (51B)‧‧‧Stirring blade (6B)‧‧‧Control unit (1C)‧‧‧Accommodation (2C) ‧‧‧ cold and heat exchange tube (3C)‧‧‧Temperature Regulator (4C)‧‧‧Temperature detector (5C)‧‧‧Stirring unit (52C)‧‧‧Shaft (55C)‧‧‧Power source (6C)‧‧‧Control unit (1D)‧‧‧Accommodation (11D)‧‧‧ Feeding space (4D)‧‧‧Temperature detector (5D)‧‧‧Stirring unit (51D)‧‧‧Stir blade (55D)‧‧‧Power source (7D)‧‧‧Power Cylinder (71D)‧‧‧slide (72D)‧‧‧Extendable lever (F) ‧‧‧ organic matter

[The first picture] is a three-dimensional appearance drawing of the first embodiment of the creation.

[The second picture] is a schematic diagram of the structure of the first embodiment of the creation.

[Third Picture] is a schematic diagram of the first embodiment of the creation.

[Fourth figure] This is a schematic diagram of the structure of the second embodiment of this creation.

[Fifth figure] is a schematic diagram of the structure of the third embodiment of the creation.

[Sixth figure] It is a schematic diagram of the structure of the fourth embodiment of this creation.

[Seventh figure] It is a schematic diagram of the structure of the fifth embodiment of this creation.

(1)‧‧‧Accommodation

(11)‧‧‧ Feeding space

(12) ‧‧‧ opening

(13)‧‧‧Valve

(14)‧‧‧block

(2)‧‧‧cold heat exchange tube

(22)‧‧‧Output

(3)‧‧‧Temperature regulator

(4)‧‧‧Temperature detector

(5)‧‧‧Stirring unit

(51)‧‧‧Stirring blade

(52)‧‧‧Shaft

(53)‧‧‧The first pulley

(54)‧‧‧First Belt

(55)‧‧‧Power source

(6)‧‧‧Control unit

(61)‧‧‧Sending unit

(62)‧‧‧Handheld electronic device

Claims (12)

A fully automatic black water fly breeding equipment, including: One housing body, with a feeding space; A temperature detector is fixed to the housing body, so as to detect a temperature value in the feeding space, and output a stirring signal when the temperature value is higher than a stirring standard value; A stirring unit is fixed to the housing body, the stirring unit is provided with a stirring blade extending into the feeding space, and the stirring blade is driven to rotate by a power source; A control unit is respectively connected to the temperature detector and the stirring unit, so that after receiving the stirring signal, the power source of the stirring unit is controlled to start to drive the stirring blade to start Spin. The automatic black water fly breeding equipment as described in item 1 of the patent application scope, wherein the control unit is provided for inputting and setting the stirring standard value, and the stirring standard value is set to 27°C. As described in item 1 of the patent application scope, the fully automatic black water fly breeding equipment, wherein the stirring unit is fixed at a lower position or an upper position of the housing body, and the stirring blade extends into the At the bottom or top of the feeding space, the stirring blade system has a single blade or a plurality of blades. As described in item 1 of the patent application scope, the automatic black water fly breeding equipment, wherein the stirring blade is extended with a shaft, the other end of the shaft is provided with a first pulley, and the first pulley is sleeved There is a first belt, which is driven to rotate by the power source. As described in item 4 of the scope of the patent application, the fully automatic black water fly breeding equipment is provided with a plurality of accommodating bodies and a plurality of stirring blades, and the other end of the shaft of each stirring blade is provided with a second pulley, and Between each adjacent second pulley, a second belt is used to set the transmission, and the power source passes through the first pulley, the first belt, the second pulley and all The mutual transmission of the second belts causes the stirring blades to rotate synchronously. As described in item 1 of the patent application, the automatic black water fly breeding equipment, wherein the stirring blade is extended with a shaft, and the other end of the shaft is directly connected to the power source for transmission. As described in item 1 of the patent application, the automatic black water fly breeding equipment, wherein the control unit is provided with a sending unit, by which the stirring signal is transmitted to a remote handheld electronic device, using the handheld electronic The device installs a mobile application program for receiving the stirring signal, and directly controls the stirring unit to be turned on or off through the handheld electronic device, and inputs the stirring standard value remotely. As described in item 1 of the scope of the patent application, the automatic black water fly breeding equipment is further provided with a cold and heat exchange tube and a temperature regulator. The cold and heat exchange tube is fixed to the housing body, and the cold and heat exchange tube is passed through The rearing space, and the two ends of the cold and heat exchange tube are respectively provided with an input end and an output end, the temperature regulator is connected with the input end and the output end, for circulating circulation of a fluid, The control unit is a signal connected to the temperature regulator, the temperature detector outputs a cooling signal when the temperature value is higher than a cooling standard value, and the control unit receives the cooling signal After that, the temperature regulator is automatically controlled to start. The automatic black water fly breeding equipment as described in item 8 of the patent application range, wherein the control unit is provided with an input to set the cooling standard value, and the cooling standard value is set to 33°C. As described in item 8 of the patent application scope, the automatic black water fly breeding equipment, wherein the control unit is provided with a sending unit to transmit the cooling signal to a remote handheld electronic device, using the handheld electronic The device installs a mobile application program for receiving the cooling signal, and directly controls activation or shutdown of the temperature regulator through the handheld electronic device, and inputs the cooling standard value remotely. As described in item 1 of the patent application scope, the automatic black water fly breeding equipment, wherein the stirring unit is provided on a power cylinder, the power cylinder is located on a slide rail, and the power cylinder is installed There is a telescopic pressure bar, one end of the telescopic pressure bar is coupled to the power source, so that the temperature detector in the plurality of housing bodies detects that the temperature value in the feeding space is higher than The stirring standard value controls the power pressure cylinder to slide on the slide rail to the position of the feeding space, and then extends through the telescopic pressure rod to drive the stirring blade to move to the feeding Stir heat in the space. As described in item 1 of the patent application scope, the automatic black water fly breeding equipment, wherein the bottom of the housing body is provided with an opening or a plurality of openings penetrating to the breeding space, and a valve or a plurality of For the valve, the bottom of the rearing space is provided in a plane or funnel shape, and the periphery of the opening of the accommodating body is bent inwardly to provide a blocking portion.

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