CN112167140A - Automatic fodder of thawing of unnecessary energy recuperation device of throwing something and feeding - Google Patents

Abstract

The invention discloses a feed feeding device capable of automatically thawing redundant energy recovery, which comprises a shell, wherein a floating space is arranged on the right side of the shell, a power generation device is arranged on the lower side of the floating space, a feeding pipeline is arranged on the right side of the power generation device, and the feeding pipeline is arranged on the lower side of the power generation device.

Description

Automatic fodder of thawing of unnecessary energy recuperation device of throwing something and feeding

Technical Field

The invention relates to the field of storage batteries, in particular to a feed feeding device capable of automatically thawing redundant energy recovery.

Background

With the development of economy, a plurality of young families start to breed some protozoon fishes, the protozoon fishes are fed with biological feed such as red worms, brine shrimps and the like, but the feed is usually frozen when stored, the protozoon fishes need to be defrosted and then fed, and if the protozoon fishes are directly fed with the biological feed, when the fishes eat the feed without defrosted inside, gastrointestinal diseases of the fishes can be caused, and the fishes die.

The invention discloses a feed feeding device capable of automatically thawing excessive energy recovery, which is characterized in that a large water flow is often generated in the feeding environment of raw fishes, a wave making pump is required to be used for environment simulation in a fish tank, and electricity can be generated by waves made on the water surface.

Disclosure of Invention

In order to solve the problems, the embodiment designs the feed feeding device capable of automatically freezing by recovering the redundant energy, which comprises a shell, wherein the right side of the shell is provided with a floating space, the lower side of the floating space is provided with a power generation device, the right side of the power generation device is provided with a feeding pipeline, the lower side of the feeding pipeline is provided with a transmission space, the middle side of the shell is provided with a main space, the rear side of the main space is provided with a sliding space, the lower side of the main space is provided with a filtering space, the upper left side of the shell is provided with a control space, the lower side of the control space is provided with a water inlet pipeline, the water inlet pipeline can communicate with the main space, the right side of the main space is provided with a rotating space, the left side of the main space is provided with a red worm shell storage device, and the red worm shell storage device is communicated with the main space, the device is characterized in that a space for collecting dead red worm shells is arranged in the red worm shell storage device, a motor space is arranged on the lower side of the red worm shell storage device, a drain valve is arranged on the lower side of the sliding space and is a control water outlet valve communicated with an external pipeline, a red worm unfreezing and filtering device is arranged among the motor space, the red worm shell storage device, the main space, the sliding space and the rotating space, the red worm unfreezing and filtering device comprises a filtering motor fixedly arranged on the rear side wall of the motor space, the front side of the filtering motor is in power connection with a driving shaft, the driving shaft is sequentially and fixedly connected with a first belt wheel and a second belt wheel from back to front, a sliding rod is slidably connected between the side walls of the filtering space, the left side of the sliding rod is in sliding connection with a sliding block, and the upper side of, the solid particle placing plate is used for collecting solid particles falling after filtration, the lower side of the sliding block is rotatably connected with a short shaft, the short shaft is fixedly connected with a first hinged rod and a belt pulley from back to front in sequence, a belt is fixedly connected between the belt pulley and the second belt pulley, the right side of the sliding rod is slidably connected with a sliding plate, the upper side of the sliding plate is hinged with a filter plate, the filter plate is arranged on the upper side of the solid particle placing plate, unfrozen frozen red worms are placed in the filter plate, the lower side wall of the filter plate is a layer of filter screen, the red worms subjected to unfrozen can be filtered on the solid particle placing plate, the left side of the sliding plate is hinged with the first hinged rod, and springs are fixedly connected between the lower sides of the sliding plate and the side wall of the filtering space and used for resetting, when the second belt wheel rotates, the filter plate and the solid particle placing plate both move left and right to filter solids in the red worms on the solid particle placing plate, the right side of the filter plate is provided with a hinged door which can prevent the red worms from shaking out when the filter plate shakes, the right side of the filter plate is fixedly connected with a hose which is made of soft materials, the hose is communicated with the feeding pipeline, the rear side wall of the rotating space is rotatably connected with a bevel gear shaft, the bevel gear shaft is fixedly connected with a first bevel gear and a small belt wheel from back to front in sequence, a transmission belt is arranged between the small belt wheel and the first belt wheel, the right side wall of the rotating space is rotatably connected with a fan shaft, the fan shaft extends leftwards to penetrate through the left side wall of the rotating space to enter the main space, and the fan shaft is fixedly connected with a blowing fan and a second bevel gear from left to right in sequence, the second bevel gear is meshed with the first bevel gear, the blowing fan can enable the water surface to move leftwards when rotating, so that the red worm shells floating on the water surface are blown into the red worm shell storage device through an outlet, a water inlet device is arranged among the main space, the control space and the water inlet pipeline, a floating power generation device is arranged among the floating space, the power generation device and the water inlet pipeline, and a feeding device is arranged among the transmission space, the feeding pipeline and the sliding space.

Preferably, the water installations include slidable mounting and are in sliding control valve between the control space lateral wall, be equipped with connecting line in the sliding control valve, connecting line can be with the pipeline switch-on, side fixedly connected with water inlet on the shell, the water inlet is the water inlet, sliding control valve right side fixedly connected with butt piece, the butt piece extends right and runs through control space right side wall gets into in the main space, the left rear side wall of main space articulates there is first door that opens and shuts, first door rear side fixedly connected with butt wheel that opens and shuts, butt wheel with butt piece butt, the rear side wall on main space right side articulates there is the second door that opens and shuts, the second open and shut with the door that opens and shuts is constituteed to first door that opens and shuts.

Preferably, the floating power generation device comprises a power storage motor fixedly mounted on the left side wall of the power generation device, the power storage motor can store power, the right side of the power storage motor is in power connection with a motor shaft, the right side of the motor shaft is fixedly connected with a one-way meshing gear, a rack is connected between the side walls of the power generation device in a sliding manner and meshed with the one-way meshing gear, the rack extends upwards to penetrate through the upper side wall of the power generation device to enter the floating space, the left side and the right side of the floating space are provided with sliding rails capable of penetrating water, a floating block is fixedly connected to the upper side of the rack, an air outlet hole is formed in the floating block, an inflation air bag is fixedly connected to the outer side of the floating block and can be inflated and floated, an inflation pump is fixedly connected to the upper side of, can give the inflatable air bag inflates, sliding connection has rivers to block the board between the lateral wall, rivers block the board and upwards extend and run through go up the lateral wall and get into in the outer space, rivers block the board and can block the right side in unsteady space, with the inflator pump communicates with each other, and gas can enter into in.

Preferably, the feeding device comprises a rotating motor fixedly arranged on the left side wall of the transmission space, the right side of the rotating motor is in power connection with a rotating shaft, the rotating shaft is sequentially and fixedly connected with a reel and a driving bevel gear from left to right, the reel is fixedly connected with the left side of the filter plate, the side wall of the transmission space is in rotating connection with a threaded rod, the upper side of the threaded rod is provided with threads, the lower side of the threaded rod is fixedly connected with a driven bevel gear, the driven bevel gear is meshed with the driving bevel gear, the side wall of the transmission space is in sliding connection with a first threaded block and a second threaded block from top to bottom, the upper side of the feeding pipeline is in sliding connection with a convex block, the lower side of the convex block is provided with a convex block, the lower side of the feeding pipeline is in sliding connection with a concave block, the concave block is provided with a concave groove, and, the feeding pipeline is communicated with the outside, the right side of the convex block is fixedly connected with the first threaded block, the right side of the concave block is fixedly connected with the second threaded block, the sliding connection and the connecting block are arranged between the side walls of the sliding space, the upper side of the connecting block is rotatably connected with the roller, the friction force can be reduced by the roller, the connecting rod is fixedly connected with the lower side of the connecting block, the lower side of the connecting rod is provided with a tangential component, the right side of the connecting rod is fixedly connected with an ejector rod, and the ejector rod can be abutted against a cross-over door on the right side of the filter.

The invention has the beneficial effects that: the invention relates to a feed feeding device capable of recycling redundant energy and automatically thawing, which can be used for putting frozen feed which is not thawed into a cavity by a person, wherein water can enter the cavity to submerge the frozen feed to accelerate thawing.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

fig. 3 is a partially enlarged view at B in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-3, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to a feed feeding device capable of recycling redundant energy and automatically thawing, which comprises a shell 11, wherein a floating space 12 is arranged on the right side of the shell 11, a power generation device 14 is arranged on the lower side of the floating space 12, a power generation device 13 is arranged on the right side of the power generation device 14, a feeding pipeline 15 is arranged on the lower side of the power generation device 14, a transmission space 16 is arranged on the lower side of the feeding pipeline 15, a main space 19 is arranged on the middle side of the shell 11, a sliding space 18 is arranged on the rear side of the main space 19, a filtering space 17 is arranged on the lower side of the main space 19, a control space 22 is arranged on the upper left side of the shell 11, a water inlet pipeline 23 is arranged on the lower side of the control space 22, the water inlet pipeline 23 can communicate with the main space 19, a rotating space 24 is arranged on the right side of the main space 19, a red worm shell storage device 20 is arranged on the, the red worm shell storage device 20 is a space for collecting dead red worm shells, a motor space 21 is arranged on the lower side of the red worm shell storage device 20, a drain valve 77 is arranged on the lower side of the sliding space 18, the drain valve 77 is a control water outlet valve and is communicated with an external pipeline, a red worm unfreezing and filtering device 104 is arranged between the motor space 21, the red worm shell storage device 20, the main space 19, the sliding space 18 and the rotating space 24, the red worm unfreezing and filtering device 104 comprises a filtering motor 35 fixedly arranged on the rear side wall of the motor space 21, the front side of the filtering motor 35 is dynamically connected with a driving shaft 34, the driving shaft 34 is fixedly connected with a first belt wheel 32 and a second belt wheel 33 from back to front in sequence, a sliding rod 42 is slidably connected between the side walls of the filtering space 17, and a sliding block is slidably connected on the left side of the sliding rod 42, a solid particle placing plate 43 is fixedly connected to the upper side of the sliding block, the solid particle placing plate 43 is used for collecting solid particles falling after filtration, a short shaft 37 is rotatably connected to the lower side of the sliding block, a first hinged rod 39 and a belt pulley 38 are fixedly connected to the short shaft 37 from the back to the front in sequence, a belt 36 is fixedly connected between the belt pulley 38 and the second belt pulley 33, a sliding plate 41 is slidably connected to the right side of the sliding rod 42, a filter plate 44 is hinged to the upper side of the sliding plate 41, the filter plate 44 is arranged on the upper side of the solid particle placing plate 43, unfrozen frozen red worms are placed in the filter plate 44, the lower side wall of the filter plate 44 is a filter screen, the solid particle placing plate 43 can be filtered by mixing with unfrozen red worms, the left side of the sliding plate 41 is hinged to the first hinged rod 39, and the sliding plate 41 and the sliding blocks on the lower side of the solid particle placing plate 43 and a spring is fixedly connected and used for resetting, when the second belt wheel 33 rotates, the filter plate 44 and the solid particle placing plate 43 both move left and right to filter solids in red worms on the solid particle placing plate 43, a hinged door is arranged at the right side of the filter plate 44 and can prevent the red worms from shaking out when the filter plate 44 shakes, a hose 49 is fixedly connected at the right side of the filter plate 44, the hose 49 is made of soft material, the hose 49 is communicated with the feeding pipeline 15, a bevel gear shaft 28 is rotatably connected at the rear side wall of the rotating space 24, a first bevel gear 30 and a small belt wheel 29 are fixedly connected with the bevel gear shaft 28 from back to front in sequence, a transmission belt 31 is arranged between the small belt wheel 29 and the first belt wheel 32, a fan shaft 26 is rotatably connected at the right side wall of the rotating space 24, and the fan shaft 26 extends leftwards to penetrate through the left side wall of the rotating space 24 to enter the main space 19, the fan shaft 26 is fixedly connected with a blowing fan 25 and a second bevel gear 27 in sequence from left to right, the second bevel gear 27 is meshed with the first bevel gear 30, the blowing fan 25 can move the water surface leftwards when rotating, so that the red worm shells floating on the water surface are blown to the red worm shell storage device 20 through an outlet, a water inlet device 101 is arranged among the main space 19, the control space 22 and the water inlet pipeline 23, a floating power generation device 102 is arranged among the floating space 12, the power generation device 14 and the sliding space 18, and a feeding device 103 is arranged among the transmission space 16, the feeding pipeline 15 and the sliding space 18.

Advantageously, said water intake means 101 comprise a sliding control valve 70 slidingly mounted between the side walls of said control space 22, the sliding control valve 70 is provided with a connecting pipeline 71, the connecting pipeline 71 can connect the pipeline, the upper side surface of the shell 11 is fixedly connected with a water inlet 69, the water inlet 69 is a water inlet, the right side of the sliding control valve 70 is fixedly connected with an abutting block 72, the abutting block 72 extends rightwards to penetrate through the right side wall of the control space 22 to enter the main space 19, a first opening and closing door 73 is hinged on the rear side wall of the left side of the main space 19, a butting wheel 74 is fixedly connected on the rear side of the first opening and closing door 73, the abutting wheel 74 abuts against the abutting block 72, a second opening and closing door 75 is hinged to the rear side wall on the right side of the main space 19, and the second opening and closing door 75 and the first opening and closing door 73 form an opening and closing door.

Advantageously, the floating power generation device 102 comprises an electric storage motor 68 fixedly installed on the left side wall of the power generation device 14, the electric storage motor 68 can store electricity, the right side of the electric storage motor 68 is in power connection with a motor shaft 67, the right side of the motor shaft 67 is fixedly connected with a one-way meshing gear 66, a rack 65 is slidably connected between the side walls of the power generation device 14, the rack 65 is meshed with the one-way meshing gear 66, the rack 65 extends upwards to penetrate through the upper side wall of the power generation device 14 to enter the floating space 12, the left side and the right side of the floating space 12 are sliding rails which can penetrate water, a floating block 63 is fixedly connected on the upper side of the rack 65, an air outlet is arranged in the floating block 63, an inflatable air bag 64 is fixedly connected on the outer side of the floating block 63, the inflatable air bag 64 can be inflated, the inflator 61 with link to each other through coupling hose 62 between the floating block 63, can give the air bag 64 inflates, sliding connection has water flow baffle 60 between 13 lateral walls, water flow baffle 60 upwards extends and runs through 13 lateral wall gets into in the outer space, water flow baffle 60 can block the right side of floating space 12, 13 with inflator 61 communicates with each other, and gas can enter into 13 in.

Advantageously, the feeding device 103 comprises a rotating motor 50 fixedly installed on the left side wall of the transmission space 16, a rotating shaft 51 is dynamically connected to the right side of the rotating motor 50, a reel 52 and a driving bevel gear 53 are fixedly connected to the rotating shaft 51 from left to right in sequence, a 76 is fixedly connected between the reel 52 and the left side of the filter plate 44, a threaded rod 55 is rotatably connected to the upper side wall of the transmission space 16, threads are arranged on the upper side of the threaded rod 55, a driven bevel gear 54 is fixedly connected to the lower side of the threaded rod 55, the driven bevel gear 54 is meshed with the driving bevel gear 53, a first threaded block 57 and a second threaded block 56 are slidably connected to the side wall of the transmission space 16 from top to bottom, a convex block 58 is slidably connected to the upper side of the feeding pipeline 15, a convex block 58 is arranged on the lower side of the convex block 58, and a, the feeding device is characterized in that the concave block 59 is provided with a concave groove, the convex block 58 is matched with the concave block 59 to seal the feeding pipeline 15, the feeding pipeline 15 is communicated with the outside, the right side of the convex block 58 is fixedly connected with the first thread block 57, the right side of the concave block 59 is fixedly connected with the second thread block 56, the side walls of the sliding space 18 are in sliding connection with the connecting block 45, the upper side of the connecting block 45 is rotatably connected with a roller 48, the roller 48 can reduce friction force, the lower side of the connecting block 45 is fixedly connected with a connecting rod 46, the lower side of the connecting rod 46 is provided with a tangential block, the right side of the connecting rod 46 is fixedly connected with a push rod 47, and the push rod 47 can be abutted against a transfer door on the right side of the filter plate 44 to open the.

The use steps herein are described in detail below with reference to fig. 1-3:

in the initial state, the connecting block 45 is positioned at the rightmost side, the sliding control valve 70 is positioned at the rightmost side, the water inlet pipeline 23 of the fish tank 23 is not communicated with the main space 19 at this time, the inflatable air bag 64 is not inflated, the floating block 63 is positioned at the bottommost side, the water flow blocking plate 60 is positioned at the uppermost side, the right side of the floating space 12 is blocked by the water flow blocking plate 60 at this time, water in the fish tank can be blocked by the water flow blocking plate 60 at this time, and the convex block 58 and the concave block 59 are in the closed state at.

When the frozen red worms are placed in the main space 19, the frozen red worms touch the first opening and closing door 73 and the second opening and closing door 75, the abutting wheel 74 rotates to abut against the abutting block 72, the abutting block 72 moves to the left, the water inlet pipeline 23 is communicated with the main space 19 at this time, external water enters the main space 19 through a pipeline to reach a certain water amount and then does not enter the water inlet 69, the water level is fixed at this time, the frozen red worms are submerged by the water and start to thaw, after a fixed time, the red worms are thawed at this time, the shells with the dead red worms float to the water level, the filter motor 35 starts, the first hinge rod 39 rotates through the transmission belt 31 and the belt 36, the blowing fan 25 rotates to start to blow water on the surface, the shells of the red worms are blown into the red worm shell storage device 20, and the solid particle placing plate 43 and the left and right movement 44 are simultaneously realized under the action of the first hinge rod 39 and the second hinge rod 40, the red worms on the filter plate 44 are filtered so that the solid particles mixed in the red worms fall on the solid particle placing plate 43 to be collected, and after the filtering is completed, the drain valve 77 is started to flow the water in the sliding space 18 and the main space 19 to the external pipeline through the drain valve 77, and the filtered water cannot be directly discharged into the fish tank.

When the filtering is finished, the rotating motor 50 is started to rotate the rotating shaft 51, so that the reels 52 retract 76, the filter plate 44 starts to rotate relative to the sliding plate 41 to form an angle, the connecting rod 46 starts to move rightwards due to the rotation of the filter plate 44, the filtered red worms on the filter plate 44 move rightwards, the ejector rod 47 moves rightwards, a hinged door is arranged on the right side of the filter plate 44 from the top, the hose 49 is opened, the red worms are pushed into the feeding pipeline 15, meanwhile, the threaded rod 55 rotates due to the rotation of the driven bevel gear 54, the first threaded block 57 in threaded connection with the threaded rod is moved upwards, the second threaded block 56 moves downwards, the convex block 58 moves upwards, the concave block 59 moves downwards, the feeding pipeline 15 is opened, the filtered red worms are fed into the fish tank through the feeding pipeline 15, after the completion, the rotating motor 50 rotates reversely for the communication time, and at this time, the feeding device is reset.

When power generation is required to be performed by utilizing water flow generated by the wave making pump, the inflator 61 is started to emit gas, so that the inflatable air bag 64 is inflated, the floating block 63 starts floating, meanwhile, the gas enters the space 13, the water flow blocking plate 60 descends, the water flow directly impacts the floating block 63 in the floating space 12, the water flow enables the floating block 63 to move up and down, and the power storage motor 68 can be used for generating power at the moment due to the fact that the one-way meshing gear 66 is meshed with the rack 65 in a one-way mode.

The invention has the beneficial effects that: the invention relates to a feed feeding device capable of recycling redundant energy and automatically thawing, which can be used for putting frozen feed which is not thawed into a cavity by a person, wherein water enters the cavity to submerge the frozen feed to accelerate thawing.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (4)

1. The utility model provides a fodder feeding device that automatic thawing of unnecessary energy recuperation, includes its characterized in that of shell: the device is characterized in that a floating space is arranged on the right side of the shell, a power generation device is arranged on the lower side of the floating space, a feeding pipeline is arranged on the lower side of the power generation device, a transmission space is arranged on the lower side of the feeding pipeline, a main space is arranged on the middle side of the shell, a sliding space is arranged on the rear side of the main space, a filtering space is arranged on the lower side of the main space, a control space is arranged on the upper left side of the shell, a water inlet pipeline is arranged on the lower side of the control space and can be communicated with the main space, a rotating space is arranged on the right side of the main space, a red worm shell storage device is arranged on the left side of the main space and is communicated with the main space, a space for collecting dead red worm shells is arranged in the red worm shell storage device, a motor space is arranged on the lower side of the, the water discharge valve is a control water outlet valve and is communicated with an external pipeline, the motor space, the red worm shell storage device, the main space, the sliding space and the rotating space are provided with a red worm thawing filtering device, the red worm thawing filtering device comprises a filtering motor fixedly arranged on the rear side wall of the motor space, the front side of the filtering motor is in power connection with a driving shaft, the driving shaft is sequentially and fixedly connected with a first belt wheel and a second belt wheel from back to front, a sliding rod is slidably connected between the side walls of the filtering space, the left side of the sliding rod is in sliding connection with a sliding block, the upper side of the sliding block is fixedly connected with a solid particle placing plate, the solid particle placing plate is used for collecting solid particles falling after filtering, the lower side of the sliding block is rotatably connected with a short shaft, and the short shaft is sequentially and fixedly connected with a first hinge rod and a belt, a belt is fixedly connected between the belt pulley and the second belt pulley, a sliding plate is connected to the right side of the sliding rod in a sliding manner, a filter plate is hinged to the upper side of the solid particle placing plate and is used for placing unfrozen frozen red worms, a filter screen layer is arranged on the lower side wall of the filter plate and can filter the red worms mixed with the unfrozen red worms onto the solid particle placing plate, the left side of the sliding plate is hinged to the first hinge rod, springs are fixedly connected between the sliding plate and the sliding block on the lower side of the solid particle placing plate and the side wall of the filtering space and used for resetting, when the second belt pulley rotates, the filter plate and the solid particle placing plate can move left and right and can filter the solids in the red worms onto the solid particle placing plate, and a hinged door is arranged on the right side of the filter plate, the hand-over door can prevent the red worms from shaking out when the filter plate is shaken, the right side of the filter plate is fixedly connected with a hose which is made of soft material, the hose is communicated with the feeding pipeline, the rear side wall of the rotating space is rotatably connected with a bevel gear shaft, the bevel gear shaft is fixedly connected with a first bevel gear and a small belt wheel from back to front in sequence, a transmission belt is arranged between the small belt wheel and the first belt wheel, the right side wall of the rotating space is rotatably connected with a fan shaft, the fan shaft extends leftwards to penetrate through the left side wall of the rotating space to enter the main space, the fan shaft is fixedly connected with a blowing fan and a second bevel gear from left to right in sequence, the second bevel gear is meshed with the first bevel gear, the blowing fan can move leftwards on the water surface when rotating, so that the red worm shells floating on the water surface are blown into the red worm shell storage device through an outlet, the feeding device is characterized in that a water inlet device is arranged among the main space, the control space and the water inlet pipeline, a floating power generation device is arranged among the floating space, the power generation device and the sliding space, and a feeding device is arranged among the transmission space, the feeding pipeline and the sliding space.

2. An excess energy recovery automated de-freezing feed feeding apparatus as claimed in claim 1, wherein: the water installations include slidable mounting and are in sliding control valve between the control space lateral wall, be equipped with connecting line in the sliding control valve, connecting line can be with the pipeline switch-on, side fixedly connected with water inlet on the shell, the water inlet is the water inlet, sliding control valve right side fixedly connected with butt piece, the butt piece extends right and runs through control space right side wall gets into in the main space, the left back lateral wall in main space articulates there is first door that opens and shuts, first door rear side fixedly connected with butt wheel that opens and shuts, butt wheel with butt piece butt, the back lateral wall on main space right side articulates there is the second door that opens and shuts, the second open and shut the door with first door that opens and shuts constitution door that opens and shuts.

3. An excess energy recovery automated de-freezing feed feeding apparatus as claimed in claim 1, wherein: the floating power generation device comprises a power storage motor fixedly arranged on the left side wall of the power generation device, the power storage motor can store power, the right side of the power storage motor is in power connection with a motor shaft, the right side of the motor shaft is fixedly connected with a one-way meshing gear, a rack is slidably connected between the side walls of the power generation device and meshed with the one-way meshing gear, the rack extends upwards to penetrate through the upper side wall of the power generation device to enter the floating space, the left side and the right side of the floating space are sliding rails capable of penetrating water, a floating block is fixedly connected to the upper side of the rack, an air outlet hole is formed in the floating block, an inflatable air bag is fixedly connected to the outer side of the floating block and can be inflated and floated, an inflator pump is fixedly connected to the upper side of the floating space, can give the inflatable air bag inflates, sliding connection has rivers to block the board between the lateral wall, rivers block the board and upwards extend and run through go up the lateral wall and get into in the outer space, rivers block the board and can block the right side in unsteady space, with the inflator pump communicates with each other, and gas can enter into in.

4. An excess energy recovery automated de-freezing feed feeding apparatus as claimed in claim 1, wherein: the feeding device comprises a rotating motor fixedly arranged on the left side wall of the transmission space, the right side of the rotating motor is in power connection with a rotating shaft, the rotating shaft is sequentially and fixedly connected with a reel and a driving bevel gear from left to right, the reel is fixedly connected with the left side of the filter plate, the side wall of the transmission space is in rotating connection with a threaded rod, the upper side of the threaded rod is provided with threads, the lower side of the threaded rod is fixedly connected with a driven bevel gear, the driven bevel gear is meshed with the driving bevel gear, the side wall of the transmission space is in sliding connection with a first threaded block and a second threaded block from top to bottom, the upper side of the feeding pipeline is in sliding connection with a convex block, the lower side of the convex block is provided with a convex block, the lower side of the feeding pipeline is in sliding connection with a concave block, the concave block is provided with a concave groove, the feeding pipeline is communicated with the outside, the right side of the convex block is fixedly connected with the first threaded block, the right side of the concave block is fixedly connected with the second threaded block, the sliding connection and the connecting block are arranged between the side walls of the sliding space, the upper side of the connecting block is rotatably connected with the roller, the friction force can be reduced by the roller, the connecting rod is fixedly connected with the lower side of the connecting block, the lower side of the connecting rod is provided with a tangential component, the right side of the connecting rod is fixedly connected with an ejector rod, and the ejector rod can be abutted against a cross-over door on the right side of the filter.

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