CN219461496U - Broken beak subassembly, broken beak structure and injection broken beak all-in-one - Google Patents

Abstract

The utility model provides a broken beak subassembly, including first guide surface and second guide surface, through first guide and second guide, laser guide to the animal's beak with laser emitter transmission is gone up, carries out broken beak operation to the animal, through the controllability of laser energy, so can reduce the stress of broken beak to the animal, carry out injection operation together with broken beak operation simultaneously, improve operating efficiency, reduce birds stress. The application also discloses a beak-breaking structure and an injection beak-breaking integrated machine, comprising the beak-breaking assembly.

Description

Broken beak subassembly, broken beak structure and injection broken beak all-in-one

Technical Field

The application belongs to the technical field of bird breeding, and more specifically relates to a beak breaking assembly, a beak breaking structure and an injection beak breaking integrated machine.

Background

In the animal raising process of the farm, the phenomenon that animals peck feathers and toes frequently occurs, so that young animals die, and economic loss is caused.

Part of farms break the beak by means of hot blades or heat, but both of these approaches tend to cause greater stress in the animals, thereby affecting the subsequent growth of birds.

Disclosure of Invention

An aim of the embodiment of the application is to provide a beak breaking assembly, a beak breaking structure and an injection beak breaking integrated machine, so as to solve the technical problem of high stress in the prior art.

In order to achieve the above purpose, the technical scheme adopted in the application is as follows: there is provided a beak breaking assembly comprising: a laser generator;

a first guide comprising a first guide surface and a second guide comprising a second guide surface, the first guide surface and the second guide surface being disposed at an angle, the first guide surface being configured to redirect laser light emitted via the laser generator, the second guide surface being configured to receive the laser light directed via the first guide surface and direct the laser light onto at least a portion of a beak of a bird;

a driving section; the driving part comprises a first driving part and a second driving part, the first driving part comprises a first output part, the first output part is used for being connected with the first guide part to drive the first guide surface to rotate, and/or the second driving part comprises a second output part, and the second output part is used for being connected with the second guide part to drive the second guide surface to rotate.

Optionally, a convex lens is also included through which light passing through the second guide surface is directed toward at least a portion of the beak of the bird.

Optionally, the device further comprises a housing, the first guide piece, the second guide piece and the convex lens are all located in the housing, the first guide piece, the second guide piece and the convex lens are all connected with the housing, an outlet is formed in the housing, and the convex lens is arranged on the outlet.

Optionally, an inlet is formed on the housing, an emission port of the laser generator is aligned with the inlet, and the first guide surface is disposed on a laser generation path of the laser generator.

Optionally, the device further comprises a housing and an L-shaped bracket, wherein the L-shaped bracket is used for supporting the first guide piece and the second guide piece, the L-shaped bracket is connected with the housing, the L-shaped bracket comprises a first side wall and a second side wall, one end of the first side wall is connected with one end of the second side wall, the first driving piece comprises a first shell, the second driving piece comprises a second shell, the first shell is connected with the first side wall, and the second shell is connected with the second side wall.

Optionally, the laser device further comprises an adjusting assembly, the adjusting assembly comprises a base and a first moving block, the base comprises a first track, the first moving block can move along the first track, and the laser generator, the first guide piece and the second guide piece can move along the first track in the same displacement mode. Optionally, the adjusting assembly further comprises a second moving block, the second moving block being arranged as follows:

the first moving block is provided with a second track, the second moving block can move along the second track, and the directions of the first track and the second track are inconsistent;

or, be equipped with first connecting hole on the first movable block, be equipped with the second connecting hole on the second movable block, first connecting hole with the second connecting hole is coaxial, makes through the fastener can make the second movable block is optional around first movable block rotates, be equipped with the second track on the second movable block, laser generator first guide with the second guide all can be followed the motion of same displacement is done to the second track, first track with the orbital direction of second is inconsistent.

A beak-breaking structure comprising at least a first beak-breaking assembly and a second beak-breaking assembly, the laser emitted via the first beak-breaking assembly being capable of performing a beak-breaking operation on a part of the beak of an animal, the laser emitted via the second beak-breaking assembly being capable of performing a beak-breaking operation on a part of the beak of an animal.

The utility model provides a broken beak structure, its characterized in that includes at least first broken beak subassembly and the broken beak subassembly of second, and first broken beak subassembly and the broken beak subassembly of second of shown are located respectively the both sides of base that shows, and the second subassembly of shown can move the position of the laser that has adjusted and sent out by the broken beak subassembly of shown second with respect to the base that shows.

An injection beak breaking integrated machine comprises an injection assembly, a clamping assembly and a beak breaking assembly, wherein the injection assembly is used for injecting vaccine to birds, and the beak breaking assembly is used for performing beak breaking operation;

the clamping assembly is used for clamping the head of the bird;

the injection assembly comprises a needle, a pump body and a transfusion tube, wherein the needle is connected with the pump body through the transfusion tube.

Optionally, it is characterized in that:

the injection device also comprises a displacement assembly and an integrated machine shell, wherein the displacement assembly comprises a displacement driving piece, the clamping assembly is connected to the output end of the displacement driving piece, the output end of the displacement assembly can drive the clamping assembly to do translational motion, the injection assembly is movably connected with the integrated machine shell, the clamping device is characterized in that the needle head of the injection assembly is arranged above the clamping assembly, when the displacement driving piece drives the clamping assembly to move to an operation position, the beak of the animal is positioned at a beak breaking position, the rear neck of the animal is attached to the injection assembly, and the animal is positioned at the injection position;

the metering assembly is arranged between the pump body and the injection bottle, the metering assembly comprises an initial liquid level sensor, a final liquid level sensor and a hollow metering bottle, the metering bottle comprises a recognition piece, a metering inlet and a metering outlet, the recognition piece is positioned in the metering bottle, the cross section of the recognition piece is larger than the area of the metering inlet and the area of the metering outlet, and the initial liquid level sensor and the final liquid level sensor are used for sensing the recognition piece;

the weighing assembly is used for weighing the injection bottle;

the clamping structure comprises a neck positioning groove and an injection bracket, wherein the neck positioning groove is used for accommodating the front side neck of the poultry, the injection bracket is provided with a groove, the groove is used for extruding the rear neck of the poultry, and the needle head can move into the groove and is used for performing injection operation on the poultry;

the clamping assembly is arranged in a way that the displacement driving piece drives the clamping structure and poultry positioned on the clamping structure to move towards the injection assembly, and the injection assembly moves to the groove to squeeze the back neck of the poultry; the neck positioning groove and the groove are arranged in a straight line with the same angle;

still include the extrusion, the extrusion with injection subassembly is connected, the extrusion is connected the injection support is close to the tip of clamp structure, the extrusion sets up to, the poultry is to the removal in-process of injection position, the extrusion is used for exerting to the poultry neck below the position keep away from the power of recess.

The beneficial effect of the disconnected beak subassembly that this application provided lies in: the laser emitted by the laser emitter is guided to the beak of the animal through the first guide piece and the second guide piece, the beak breaking operation is performed on the animal, and the stress of the beak breaking operation on the animal can be reduced through the controllability of laser energy, and meanwhile, the injection operation and the beak breaking operation are performed together, so that the operation efficiency is improved, and the stress of birds is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required for the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a beak assembly of an embodiment of the present application;

FIG. 2 is a schematic diagram of a portion of the structure of FIG. 1;

FIG. 3 is a schematic view of the structure of FIG. 2 at another angle;

FIG. 4 is a schematic view of the structure of FIG. 2 at another angle;

FIG. 5 is a schematic view of another angular configuration of the beak assembly of FIG. 1;

FIG. 6 is a schematic illustration of a beak assembly in accordance with another embodiment of the present disclosure;

FIG. 7 is a right side view of a portion of the structure of FIG. 6;

FIG. 8 is a schematic view of a beak structure of a beak type cutter according to an embodiment of the disclosure;

FIG. 9 is a schematic view showing a structure of a beak breakage structure according to another embodiment of the present utility model;

FIG. 10 is a schematic view of a part of an injection beak-breaking integrated machine according to an embodiment of the present application;

FIG. 11 is a schematic view of the structure of FIG. 10 at another angle;

FIG. 12 is a schematic perspective view of a portion of the structure of FIG. 11;

FIG. 13 is a schematic perspective view of the partial result of FIG. 12;

FIG. 14 is a schematic perspective view of the partial result of FIG. 12;

FIG. 15 is a schematic view of another angle of FIG. 14;

FIG. 16 is a schematic view of a metering assembly of an injection beak-breaking integrated machine according to an embodiment of the disclosure;

FIG. 17 is a schematic view of the structure of FIG. 16 at another angle;

fig. 18 is a cross-sectional view taken along the direction A-A in fig. 17.

Wherein, each reference sign in the figure:

the beak assembly 101, bird 102, beak 103, laser generator 104, housing 105, outlet 106, laser 107, inlet 108, heat sink 109, first drive 201, first housing 202, first output 203, second drive 204, second housing 205, second output 206, first guide 207, second guide 208, first guide surface 209, L-shaped support 210, first sidewall 211, second sidewall 212, second guide surface 401, convex lens 501, adjustment assembly 601, base 602, first moving block 603, second moving block 604, first rail 605, second rail 606, first connecting hole 607, first beak assembly 701, second beak assembly 702, upper beak 703, lower beak 704, first laser 705, second laser 706, connecting piece 707, third moving block 708, third rail 1405, i third connecting hole 710, injection assembly 901, 902, clamping assembly 906, displacement assembly 904, displacement assembly 905, back neck, integral housing 1106, neck positioning groove 1106, neck holder 1206, liquid level sensing bottle holder 1602, liquid level sensing bottle holder 1302, liquid level sensing bottle holder 1404, liquid level sensing bottle holder 1602, metering bottle holder 1401, liquid level sensing bottle holder 1302, metering bottle holder 1401, metering bottle holder 1404, liquid level sensing bottle holder, metering bottle holder 1401, metering bottle top mount, etc.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved by the present application more clear, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the present application.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present application and simplify description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and therefore should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

The embodiment of the application provides a plurality of technical scheme that breaks the beak through laser, and the beak principle of breaking at this scheme is: a part of the area is moved on the beak of the animal by the laser so that the beak of the animal is bounded by the trajectory of the laser movement, the part of the beak that is acted on by the laser will die, but the part of the beak will not fall off immediately (i.e. a broken beak in this context will not cause the pointed beak stand Ma Tuola) but will still be connected to the beak that is not acted on by the laser, and the part of the beak will fall off automatically a few days after the broken beak, during which time the animal's feeding, drinking etc. activities are not affected.

It will be appreciated that the animals mentioned in the examples of the present application are birds with beaks, such as pigeons, chickens, ducks, geese, quails, turkeys, etc., but may also be other birds.

It will be appreciated that the lasers shown in the drawings of the present application are schematic. Such as laser 107, first laser 705, second laser 706.

As an example, as shown in fig. 1 to 5, the present embodiment discloses a beak breaking assembly 101, where the beak breaking assembly 101 includes a laser generator 104, a first guide 207 and a second guide 208, the first guide 207 includes a first guide surface 209, the second guide 208 includes a second guide surface 401, the first guide surface 209 and the second guide surface 401 are capable of reflecting laser light, the laser generator 104 is configured to generate laser light and emit the laser light, the laser light 107 emitted by the laser generator 104 is first directed to the first guide surface 209, the laser light 107 reflected by the first guide surface 209 is directed to the second guide surface 401, and the laser light 107 reflected by the second guide surface 401 is in contact with the beak 103 of the bird 102 for breaking the beak of the bird 102.

In this embodiment, the apparatus further includes a first driving member 201 and a second driving member 204, where the first driving member 201 includes a first housing 202 and a first output portion 203, and the second driving member 204 includes a second housing 205 and a second output portion 206, where the first output portion 203 is connected to the first guiding member 207 and is configured to drive a first guiding surface 209 on the first guiding member 207 to rotate, and the second output portion 206 is connected to the second guiding member 208 and is configured to drive a second guiding surface 401 on the second guiding member 208 to rotate, and by driving of the first driving member 201 and the second driving member 204, the first guiding surface 209 and the second guiding surface 401 are respectively driven to rotate, so as to adjust a movement track of the laser 107 and complete a beak breaking operation on the bird 102.

The method of operation of the beak breaking assembly 101 according to this embodiment is as follows: first, the laser generator 104 emits laser light, the laser light 107 is received by the first guide surface 209, and the laser light 107 is reflected to the second guide surface 401, the second guide surface 401 reflects the laser light 107 onto the beak 103 of the bird 102, and then the first driving member 201 and the second driving member 204 start to operate, and the first guide surface 209 and the second guide surface 401 are driven to rotate by the cooperation of the first driving member 201 and the second driving member 204, so that the motion track of the laser light 107 on the beak 103 of the bird 102 is adjusted, and thus the beak breaking operation (the motion track is a part of the broken beak for separating the beak 103) is completed.

The beneficial effects of this embodiment are: 1) Compared with a cutting and heating beak-breaking method, the laser-based beak-breaking method can reduce damage to the birds 102 (such as excessive bleeding, scalded birds 102 and the like) and reduce stress of the birds 102 in the beak-breaking process; 2) Because the first driver 201 and the second driver 204 are operated so that the laser beam is moving and not always irradiated on the same position of the beak 103, the present solution not only can complete the beak breaking operation, but also can prevent the laser beam from damaging the tongue in the mouth of the animal bird 102 as much as possible.

It will be appreciated that during the beak breaking process described above, the entire beak 103 (upper beak 703 and lower beak 704) may be simultaneously subjected to the beak breaking operation by the beam of laser light, or only a part of the beak 103 (e.g., the upper beak 703, the lower beak 704, a part of the upper beak 703, a part of the lower beak 704, or a combination of the part of the upper beak 703 and a part of the lower beak 704) may be subjected to the beak breaking operation by the beam of laser light.

In comparison with the above embodiment, it is understood that in other embodiments, the first driving member 201 and the second driving member 204 may be omitted, i.e., only one of the first guiding surface 209 and the second guiding surface 401 may be rotated, which is also within the scope of the present application.

In another embodiment of the present application, the beak breaking assembly 101 further includes a convex lens 501, and the light passing through the second guide surface 401 passes through the convex lens 501 and is focused by the convex lens 501 and then irradiates onto the beak 103 (or at least part of the beak 103) of the bird 102, so that the energy of the laser is stronger by focusing the convex lens 501, which makes the laser beam irradiate on the beak 103 for a shorter time (i.e. the laser beam can move on the beak 103 faster) while ensuring the quality of the beak, and further reduces the possibility that the laser beam damages the tongue of the bird 102.

In another embodiment of the present application, as shown in fig. 1-5, the beak assembly 101 comprises a housing 105, the housing 105 comprising an inlet 108 and an outlet 106, the emission port of the laser generator 104 aligned with the inlet 108, a first guide 207 and a second guide 208 each positioned in the housing 105, the first guide 207 and the second guide 208 each connected to the housing 105, and a convex lens 501 mounted at the outlet 106, the first guide surface 209 being disposed on the illumination path of the laser generator 104. In this embodiment, the housing 105 may protect the first guide 207 and the second guide 208, ensuring stability of the beak operation.

In another embodiment of the present application, as shown in fig. 2 to 3, the beak assembly 101 further includes an L-shaped bracket 210, where the L-shaped bracket 210 is used to connect the first driving member 201 and the second driving member 204 with the housing 105, the L-shaped bracket 210 includes a first side wall 211 and a second side wall 212, one end of the first side wall 211 is connected with one end of the second side wall 212, the two together form the L-shaped bracket 210, the first housing 202 of the first driving member 201 is connected with the first side wall 211, and the second housing 205 of the second driving member 204 is connected with the second side wall 212. In this embodiment, since the first sidewall 211 and the second sidewall 212 form an L-shaped structure, the laser beam can move in two directions through the first driving member 201 and the second driving member 204, so that the beak breaking operation is suitable for the beaks 103 of different birds 102 or the beaks 103 of birds 102 of the same kind and different ages (i.e. the track of the laser beam on the beaks 103 of birds 102 can be adjusted in two directions to adapt to different beaks 103) in the operation process.

It can be understood that the L-shaped bracket 210 in the present embodiment refers to a bracket having a substantially L-shape, and is not particularly limited to the first side wall 211 and the second side wall 212 being disposed at 90 degrees, so long as the arrangement is reasonable and the first side wall 211 and the second side wall 212 are not disposed in a straight line. It will be appreciated that in other embodiments, a split bracket may be used to limit the first drive member 201 and the second drive member 204, respectively.

In another embodiment of the present application, the beak-breaking assembly 101 further includes an adjusting assembly 601, where the adjusting assembly 601 may adjust the positions of the laser generator 104, the first guide 207, the second guide 208, the first driving member 201, the second driving member 204, and the convex lens 501 (i.e., adjust the positions of the foregoing devices synchronously), so as to expand the usage scenario of the device, so that the device may adapt to the beak-breaking of different birds 102. Specifically, the adjusting component 601 includes a base 602, a first moving block 603 and a second moving block 604, as shown in fig. 6, a first track 605 is disposed on the base 602, the first moving block 603 can move on the base 602 along the first track 605, a first connecting hole 607 is disposed on the first moving block 603, a second connecting hole 607 is disposed on the second moving block 604, and the first connecting hole 607 and the second connecting hole are coaxial, so that the second moving block 604 can enable the first moving block 603 to be mutually fixed through a fastening piece, and when the fastening piece is screwed, the second moving block 604 can be made to rotate compared with the first moving block 603. The second moving block 604 is provided with a second rail 606, and the laser generator 104 can move along the second rail 606, so that the housing 105 connected with the laser generator, and the first guide 207, the second guide 208, the first driving member 201, the second driving member 204 and the convex lens 501 connected with the housing 105 can also do the same movement, and the directions of the first rail 605 and the second rail 606 are not consistent in the above arrangement. Through the scheme, the distance, the position and the angle between the beak breaking assembly 101 and the beak 103 of the bird 102 can be adjusted according to the birds 102 or the positions of the birds 102 needing beak breaking, so that beak breaking operation in different scenes is adapted.

In the above embodiment, the adjusting assembly 601 includes the base 602, the first moving block 603 and the second moving block 604, it is understood that in other embodiments, the adjusting assembly 601 may not include the second moving block 604, i.e., the laser generator 104, the first guide 207, the second guide 208, the first driving member 201, the second driving member 204 and the convex lens 501 are all connected to the first moving block 603, so that the distance and/or the position between the light emitted from the convex lens 501 and the beak of the poultry is adjusted by the movement of the first moving block 603 on the first track 605 (in which case the second track 606 is also not required).

In the above embodiment, the first moving block 603 is provided with the first connection hole 607, and the second moving block 604 is provided with the second connection hole, it is understood that in other embodiments, the first moving block 603 has no first connection hole 607, and the second moving block 604 has no second connection hole, that is, the angle between the first connecting block 603 and the second connecting block 607 is fixed, and the first moving block 603 moves on the first track 605, and the second moving block 604 moves on the second track 606, so as to adjust the distance and/or position between the light emitted from the convex lens 501 and the beak of the poultry.

The application also discloses a beak-breaking structure, the beak-breaking structure includes the beak-breaking assembly 101 in two above-mentioned embodiments, specifically, first beak-breaking assembly 701 and second beak-breaking assembly 702, specifically, as shown in fig. 8, first laser 705 sent out by first beak-breaking assembly 701 performs the beak-breaking operation to the upper beak 703 of bird 102, second laser 706 sent out by second beak-breaking assembly 702 performs the beak-breaking operation to the lower beak 704 of bird 102, this kind of mode, the time that the laser beam stays on beak 103 of bird 102 is shorter, the effect of protecting the tongue can be better played, and, because the length of beak 703 is different on bird 102 and lower beak 704, when performing the beak-breaking operation through first beak-breaking assembly 701 and second beak-breaking assembly 702, can control the position and the route of two laser beams respectively, realize more accurate beak-breaking operation.

In another embodiment of the present application, as shown in fig. 9, a first beak breaking assembly 701 and a second beak breaking assembly 702 are disposed at two left and right ends of the beak 103 of the bird 102, the first laser 705 emitted by the first beak breaking assembly 701 is used to perform beak breaking operations on the upper left beak 703 and the lower left beak 704 of the bird 102, and the second laser 706 emitted by the second beak breaking assembly 702 is used to perform beak breaking operations on the upper right beak 703 and the lower right beak 704 of the bird 102.

In other embodiments, as shown in fig. 7, the apparatus further includes a third moving block 708, a third track 709 and a connection position are disposed on the third connecting block, a second beak-breaking assembly 702 is disposed on the other side of the base opposite to the first beak-breaking assembly 701, a plurality of connecting members 707 are disposed on one side of the base 602 to which the second beak-breaking assembly 702 is connected, a third connecting hole 710 is disposed on the connecting member 707, the third connecting hole 710 corresponds to the connection position, and the third connecting hole 710 and the connection position can be fixed by a fastener, so that the third moving block 708 is connected to the base 602, and it is understood that in other embodiments, the third connecting hole 710 is disposed along the vertical direction, and a plurality of positions capable of docking the connection position are disposed on the track, so that the distance between the second beak-breaking assembly 702 and the beak of poultry can be adjusted by adjusting the connection position of the docking position 711. It will be appreciated that in other embodiments, the second beak assembly 702 may be movable along the third track 709 to adjust the position of the laser light emitted from the second beak assembly 702.

Combining the above embodiments with the first moving block 603 and the second moving block 604 embodiments may result in an embodiment in which the positions of the first beak breaking assembly 701 and the second beak breaking assembly 702 may be adjusted simultaneously.

It will be appreciated that in other embodiments, when the bird 102 may be beak-broken by the first and second beak assemblies 701 and 702, the first and second beak assemblies 701 and 702 may both perform beak-breaking operations on at least a portion of the beak 103, and both may perform beak-breaking operations on all of the beaks 103 of the bird 102, e.g., the first beak assembly 701 may perform beak-breaking operations on the upper left beak 703, the second beak assembly may perform beak-breaking operations on the lower left beak 704, the upper right beak 703, the lower right beak 704, etc.

The application also discloses an injection beak-breaking integrated machine, which specifically comprises an injection assembly 901, a clamping assembly 903 and the beak-breaking assembly 101 in any of the above embodiments. In the application, the clamping component 903 is used for clamping the neck and the head of the bird 102, so as to ensure the position of the bird 102; the injection assembly 901 is used for injecting vaccine into the rear neck 906 of the bird 102, the injection assembly 901 comprises a pump body 1401, a needle 902 and a transfusion tube, the pump body 1401 and the needle 902 are connected through the transfusion tube, and the pump body 1401 can input the vaccine into the bird 102 through the needle 902; the beak breaking assembly 101 is used for performing beak breaking operation on the bird 102, two operations of vaccine injection and beak breaking can be performed on the bird 102 through the device, specifically, an operator places the head and neck of the bird 102 on the clamping assembly 903, the clamping assembly 903 clamps the head and neck of the bird 102, then the injection assembly 901 and the beak breaking assembly 101 perform injection operation and injection operation respectively, after the operation is performed, the clamping assembly 903 is reset, and the bird 102 is separated from the beak breaking integrated machine for injection, so that the operation is completed. The equipment not only saves the operation time, but also saves the labor cost required by operation (two operations, only one operation by an operator is required). In another embodiment of the present application, as shown in fig. 10 to 11, the integrated injection beak-breaking machine further includes a displacement assembly 904, where the displacement assembly 904 includes a displacement driving member 905, and the clamping assembly 903 is located on an output end of the displacement driving member 905, so that the clamping assembly 903 and the bird 102 located on the clamping assembly 903 can be driven to perform a translational motion by the displacement driving member 905, for example, can drive the bird 102 to perform a translational motion in a vertical direction.

Specifically, as shown in fig. 11 to 15, the clamping structure 903 includes a neck positioning groove 1106, where the neck positioning groove 1106 is used for accommodating the front side of the neck of the poultry, and positioning the left and right sides of the neck of the poultry through the side walls, that is, when the operator places the head and neck of the poultry on the clamping structure 903, the neck positioning groove 1106 can accommodate and position the front side and the left and right sides of the neck of the poultry.

Injection subassembly 901 includes syringe needle 902 and injection support 1302, and syringe needle 902 passes through injection support 1302 and is connected with integrative casing 1101, is equipped with recess 1107 on the one side towards neck constant head tank 1106 on the one end that injection support 1302 is close to clamp structure 903, and recess 1107 is used for squeezing the rear side neck of poultry, cooperates neck constant head tank 1106, and together fixes a position and extrudees the neck of poultry, and because recess 1107 is the concave structure, in the completion to neck location, the skin of the neck of poultry can get into recess 1107 in, and syringe needle 902 can stretch into in recess 1107 to the skin tissue that lies in recess 1107 carries out the injection operation. From the foregoing, it will be appreciated that the skin of the bird that enters the recess 1107, so this configuration is more conducive to subcutaneous injection.

The using process of the structure is as follows: the operator places the birds on the gripping structure 903 during this operation, places the front side necks of the birds in the neck positioning slots 1106, and then the displacement drive 905 is operated, and when the birds are moved to the injection station, the necks of the birds are positioned in the neck positioning slots 1106 and the grooves 1107, and the needles 902 of the injection assembly 901 are extended into the grooves 1107 so that the needles 902 are driven to be inserted into the necks, facilitating the injection operation.

In the above process, the neck positioning groove 1106 and the groove 1107 are arranged in a straight line with basically the same angle, so that the neck of the poultry is ensured to be in a straight line state as far as possible, the injection effect of the vaccine is ensured, and the situation that the injection is not in place or the poultry is injured is avoided.

As another embodiment, the poultry vaccine injection machine further includes an extrusion 1108, the extrusion 1108 is connected to the injection bracket 1302, the extrusion 1108 is connected to an end of the injection bracket 1302 adjacent to the clamping structure 903, and when the clamping structure 903 moves to the injection position, the extrusion 1108 gradually contacts the poultry and applies a force away from the injection assembly 901 to the poultry, so that the body (the lower part of the neck) of the poultry moves away from the groove 1107, thereby achieving the purpose of straightening the neck of the poultry, and further facilitating the subsequent injection operation.

As one example, the extrusion 1108 is an elastic member having a degree of stiffness that is effective to minimize damage to the poultry while accomplishing the extrusion of the poultry body (below the neck).

As shown in fig. 17, the needle 902 may be rotated relative to the body housing 1101 (with a position maintaining member, such as a supporting rod, between them to support them at a distance such that the injection assembly 901 does not abut against the body housing 1101, facilitating the movement of the subsequent holding assembly 903 such that the bird 102 and the injection assembly 901 abut), the needle 902 is located above the holding assembly 903, and when the holding assembly 903 holds the bird 102 and moves in the vertical direction, the back neck 906 of the bird 102 abuts against the holding assembly 903 until the holding assembly 903 moves to the operating position, the injection assembly 901 performs the injection operation, the needle 902 pierces the back neck 906 of the bird 102, and then performs the liquid input through the pump body 1401 to complete the injection operation, and at the same time, the beak 103 of the bird 102 is located at the beak breaking position, and the beak breaking assembly 101 performs the beak breaking operation, thereby completing the two operations by the apparatus.

In another embodiment of the present application, as shown in fig. 16 to 18, the injection beak-breaking integrated machine further comprises a metering assembly 1402 and an injection bottle 1403, wherein the metering assembly 1402 is used for ensuring each injection amount, and the injection bottle 1403 is used for preserving the vaccine. As shown in fig. 16-18, metering assembly 1402 includes an initial level sensor 1404, an end level sensor 1405, and a hollow metering bottle 1406, metering bottle 1406 including a metering inlet 1602 and a metering outlet 1603, metering inlet 1602 being connected to injection bottle 1403 for providing vaccine, metering outlet 1603 being connected to pump body 1401 for delivering vaccine to needle 902 for injection. The measuring bottle 1406 is hollow and internally provided with the identifying member 1601, the cross section of the identifying member 1601 is larger than the areas of the measuring inlet 1602 and the measuring outlet 1603, so that the identifying member 1601 cannot be separated from the measuring bottle 1406 through the measuring inlet 1602 and the measuring outlet 1603, the initial liquid level sensor 1404 and the final liquid level sensor 1405 are arranged on the outer side of the measuring bottle 1406, the initial liquid level sensor 1404 and the final liquid level sensor 1405 are respectively arranged on the upper side and the lower side (vertical direction) of the measuring bottle 1406 and between the measuring inlet 1602 and the measuring outlet 1603, the initial liquid level sensor 1404 is arranged adjacent to the measuring inlet 1602, the final liquid level sensor 1405 is arranged adjacent to the measuring outlet 1603, and the initial liquid level sensor 1404 and the final liquid level sensor 1405 are used for identifying the identifying member 1601. When the injection assembly 901 performs an injection operation, the injection bottle 1403 and the metering bottle 1406 both have liquid, and when the pump body 1401 works and provides vaccine to the direction of the needle 902, the metering outlet 1603 generates suction force due to the pump body 1401, so that the liquid in the metering bottle 1406 and the identification member 1601 both move to the metering outlet 1603, the liquid enters the pump body 1401 through the infusion tube, the identification member 1601 always moves to the direction of the metering outlet 1603 until the end point liquid level sensor 1405 identifies that the identification member 1601 moves to the corresponding position, the pump body 1401 does not work any more, at this time, the identification member 1601 moves vertically downwards until the initial liquid level sensor 1404 identifies that the identification member 1601 starts working again, and the pump body 1401 generates adsorption force to the liquid and the identification member 1601, and performs the next working cycle. The structure can ensure that the quantity of vaccine injected each time is kept in a relatively stable volume, and the sufficient quantity of the vaccine is ensured.

In another embodiment of the present application, a weighing assembly is further included, and the weighing assembly is used to meter the weight of the injection bottle 1403, so as to ensure that the liquid in the metering bottle 1406 is sufficient, and ensure stable and continuous operation of the integrated machine.

The foregoing description of the preferred embodiments of the present application is not intended to be limiting, but is intended to cover any and all modifications, equivalents, and alternatives falling within the spirit and principles of the present application.

Claims (11)

1. A beak breaking assembly for breaking a beak of a bird, comprising:

a laser generator;

a first guide comprising a first guide surface and a second guide comprising a second guide surface, the first guide surface and the second guide surface being disposed at an angle, the first guide surface being configured to redirect laser light emitted via the laser generator, the second guide surface being configured to receive the laser light directed via the first guide surface and direct the laser light onto at least a portion of a beak of a bird;

a driving section; the driving part comprises a first driving part and a second driving part, the first driving part comprises a first output part, the first output part is used for being connected with the first guide part to drive the first guide surface to rotate, and/or the second driving part comprises a second output part, and the second output part is used for being connected with the second guide part to drive the second guide surface to rotate.

2. A beak breaking assembly according to claim 1, wherein: and a convex lens through which light passing through the second guide surface is directed toward at least a portion of the beak of the bird.

3. A beak breaking assembly according to claim 2, wherein: the novel lens assembly comprises a shell, and is characterized by further comprising a first guide piece, a second guide piece and a convex lens, wherein the first guide piece, the second guide piece and the convex lens are all positioned in the shell, the first guide piece, the second guide piece and the convex lens are all connected with the shell, an outlet is formed in the shell, and the convex lens is arranged on the outlet.

4. A beak breaking assembly according to claim 3, wherein: the shell is provided with an inlet, the emitting port of the laser generator is aligned with the inlet, and the first guide surface is arranged on the laser generation path of the laser generator.

5. A beak breaking assembly according to claim 1, wherein: still include shell and L type support, L type support is used for supporting first guide with the second guide, L type support with the shell is connected, L type support includes first lateral wall and second lateral wall, the one end of first lateral wall with the one end of second lateral wall is connected, first driving piece includes first casing, the second driving piece includes the second casing, first casing with first lateral wall is connected, the second casing with the second lateral wall is connected.

6. A beak breaking assembly according to claim 1, wherein: still include adjustment subassembly, adjustment subassembly includes base and first movable block, the base includes first track, first movable block can be followed first track removes, laser generator, first guide and second guide all can be along first track does the motion of same displacement.

7. The beak assembly of claim 6 wherein the adjustment assembly further comprises a second moving block arranged as follows:

the first moving block is provided with a second track, the second moving block can move along the second track, and the directions of the first track and the second track are inconsistent;

or, be equipped with first connecting hole on the first movable block, be equipped with the second connecting hole on the second movable block, first connecting hole with the second connecting hole is coaxial, makes through the fastener can make the second movable block is optional around first movable block rotates, be equipped with the second track on the second movable block, laser generator first guide with the second guide all can be followed the motion of same displacement is done to the second track, first track with the orbital direction of second is inconsistent.

8. A beak-breaking structure comprising at least a first beak-breaking assembly according to any one of claims 1 to 7 and a second beak-breaking assembly according to any one of claims 1 to 7, wherein the laser emitted via the first beak-breaking assembly is capable of performing a beak-breaking operation on a part of the beak of an animal, and the laser emitted via the second beak-breaking assembly is capable of performing a beak-breaking operation on a part of the beak of an animal.

9. A beak-breaking structure comprising at least a first beak-breaking assembly according to any one of claims 6 to 7 and a second beak-breaking assembly according to any one of claims 6 to 7, the first beak-breaking assembly and the second beak-breaking assembly being located on respective sides of the base, the second assembly being movable relative to the base to adjust the position of the laser light emitted by the second beak-breaking assembly.

10. The utility model provides a broken beak all-in-one of injection which characterized in that: comprising an injection assembly for injecting a vaccine into birds, a clamping assembly and a beak breaking assembly according to any of claims 1-7 for performing a beak breaking operation;

the clamping assembly is used for clamping the head of the bird;

the injection assembly comprises a needle, a pump body and a transfusion tube, wherein the needle is connected with the pump body through the transfusion tube.

11. The injection beak breaking integrated machine according to claim 10, wherein:

the injection device also comprises a displacement assembly and an integrated machine shell, wherein the displacement assembly comprises a displacement driving piece, the clamping assembly is connected to the output end of the displacement driving piece, the output end of the displacement assembly can drive the clamping assembly to do translational motion, the injection assembly is movably connected with the integrated machine shell, the clamping device is characterized in that the needle head of the injection assembly is arranged above the clamping assembly, when the displacement driving piece drives the clamping assembly to move to an operation position, the beak of the animal is positioned at a beak breaking position, the rear neck of the animal is attached to the injection assembly, and the animal is positioned at the injection position;

the metering assembly is arranged between the pump body and the injection bottle, the metering assembly comprises an initial liquid level sensor, a final liquid level sensor and a hollow metering bottle, the metering bottle comprises a recognition piece, a metering inlet and a metering outlet, the recognition piece is positioned in the metering bottle, the cross section of the recognition piece is larger than the area of the metering inlet and the area of the metering outlet, and the initial liquid level sensor and the final liquid level sensor are used for sensing the recognition piece;

the weighing assembly is used for weighing the injection bottle;

the clamping structure comprises a neck positioning groove and an injection bracket, wherein the neck positioning groove is used for accommodating the front side neck of the poultry, the injection bracket is provided with a groove, the groove is used for extruding the rear neck of the poultry, and the needle head can move into the groove and is used for performing injection operation on the poultry;

the clamping assembly is arranged in a way that the displacement driving piece drives the clamping structure and poultry positioned on the clamping structure to move towards the injection assembly, and the injection assembly moves to the groove to squeeze the back neck of the poultry;

the neck positioning groove and the groove are arranged in a straight line with the same angle;

still include the extrusion, the extrusion with injection subassembly is connected, the extrusion is connected the injection support is close to the tip of clamp structure, the extrusion sets up to, the poultry is to the removal in-process of injection position, the extrusion is used for exerting to the poultry neck below the position keep away from the power of recess.