CN112452425A - Caking salt autofilter processing packing plant - Google Patents

Abstract

The invention relates to the field of packaging machines, and discloses an automatic screening, processing and packaging device for caked salt, which comprises a main box, wherein a feeding roller cavity with an upward opening is arranged at the lower side of the main box, a packaging and transporting cavity with a forward opening and a left-right through opening is communicated with the upper side of the feeding roller cavity, and a feeding cavity with an upward opening is arranged at the upper side of the packaging and transporting cavity. The utilization rate of the salt is improved, and the production benefit of enterprises is increased.

Description

Caking salt autofilter processing packing plant

Technical Field

The invention relates to the related field of packaging machines, in particular to an automatic screening, processing and packaging device for caked salt.

Background

Salt is used as a seasoning for cooking in people's life, not only plays a key role in seasoning in cooking, but also provides necessary trace elements for life activities of people, salt processing and packaging are always important for people to pay attention to, most of salt processing and packaging in the market currently adopt a flow line production mode, but a machine cannot separate and reprocess salt which is moistened and caked due to environment or weather, caked salt can fall off in a lump when being packaged, salt packaging is not tested, the interior is moist and deteriorated, and a larger lump can even block a discharging port, so that serious conditions occur in packaging.

Disclosure of Invention

The invention aims to provide an automatic caking salt screening, processing and packaging device which can overcome the defects in the prior art, so that the practicability of equipment is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to an automatic caking salt screening, processing and packaging device, which comprises a main body box, wherein a feeding roller cavity with an upward opening is arranged at the lower side of the main body box, a packaging and transporting cavity with a forward opening and a through left and right opening is communicated with the upper side of the feeding roller cavity, a feeding cavity with an upward opening is arranged at the upper side of the packaging and transporting cavity, a discharging cavity is communicated and arranged between the packaging and transporting cavity and the feeding cavity, a discharging limiting cavity is arranged at the right side of the discharging cavity, a discharging plate cavity is communicated and arranged between the discharging cavity and the discharging limiting cavity, a reprocessing discharging cavity is communicated and arranged at the right side of the feeding cavity, a reprocessing cavity is communicated and arranged at the upper side of the reprocessing discharging cavity, a heating resistor positioned at the right side of the feeding cavity is fixedly connected and arranged in the left end wall of the reprocessing cavity, a caking salt falling cavity is communicated and arranged between the reprocessing cavity and the, a screen cavity is communicated and arranged between the feeding cavity and the screening reciprocating cavity, a screening semi-gear cavity is communicated and arranged at the rear side of the screening reciprocating cavity, the right side of the reprocessing cavity is communicated with a pressure plate cavity, the right side of the pressure plate cavity is communicated with a power transmission cavity, the front side of the power transmission cavity is communicated with an eccentric spring cavity positioned on the right side of the pressure plate cavity, the lower side of the power transmission cavity is communicated with a transportation transmission cavity positioned on the rear side of the feeding roller cavity, the lower side of the power transmission cavity is also communicated with a blanking plate rack cavity which is positioned at the upper side of the feeding roller cavity and positioned at the front side of the transportation transmission cavity and communicated with the blanking limit cavity, the right side of the reprocessing cavity is also communicated with a re-screening spring cavity positioned on the lower side of the pressure plate cavity, a crushing screen is connected between the re-screening spring cavity and the reprocessing cavity in a sliding fit manner, and a re-screening spring is fixedly connected between the lower end surface of the crushing screen and the lower end wall of the re-screening spring cavity.

On the basis of the technical scheme, an eccentric driving rotating shaft extending forwards is arranged on the rear end wall of the power transmission cavity in a rotating fit connection mode, a motor fixedly connected with the eccentric driving rotating shaft is arranged in the rear end wall of the power transmission cavity in a fixed connection mode, a power driving wheel is arranged on the eccentric driving rotating shaft in a fixed connection mode, an eccentric driving gear located on the front side of the power driving wheel is further fixedly connected on the eccentric driving rotating shaft, a blanking half gear shaft located on the lower side of the eccentric driving rotating shaft and extending forwards is arranged on the rear end wall of the power transmission cavity in a rotating fit connection mode, a blanking driven gear meshed with the power driving wheel is fixedly connected on the blanking half gear shaft, a blanking half gear is further fixedly connected at the tail end of the front side of the blanking half gear shaft, and a transportation half gear located between the blanking half gear and the blanking driven gear is further fixedly connected on, it is equipped with and extends forward and be located still to normal running fit connection in the power transmission chamber rear end wall the screening initiative pivot of eccentric initiative pivot upside, the terminal fixed connection of screening initiative pivot front side is equipped with the screening driving gear.

On the basis of the technical scheme, the feeding cavity is internally provided with a blanking screen which extends backwards to penetrate through the screen cavity into the screening reciprocating cavity and is connected with the screen cavity in a sliding fit manner, the tail end of the rear side of the blanking screen is fixedly connected with a screening reset rack which is positioned in the screening reciprocating cavity and is connected with the screening reciprocating cavity in a sliding fit manner, the lower end surface of the screening reset rack and the lower end wall of the screening reciprocating cavity are fixedly connected with a screening reset spring, the right end wall of the screening half gear cavity is internally provided with a screening driven rotating shaft which extends leftwards into the screening half gear cavity and rightwards into the power transmission cavity in a rotating fit manner, the tail end of the left side of the screening driven rotating shaft is fixedly connected with a screening half gear which is positioned in the screening half gear cavity and can be partially meshed with the screening reset rack, screening driven shaft right side end still fixed connection be equipped with be located the power transmission intracavity and with screening driving gear engaged's screening driven gear.

On the basis of the technical scheme, the end wall end internal rotation fit connection of clamp plate chamber front end is equipped with the eccentric gear pivot of backward extension, the terminal fixed connection of eccentric gear pivot rear side is equipped with eccentric gear, the eccentric round pin that changes that is equipped with of fixed connection on the eccentric gear, the terminal normal running fit connection of eccentric round pin rear side is equipped with the initiative connecting rod, the terminal normal running fit connection in initiative connecting rod left side is equipped with driven connecting rod, the terminal normal running fit connection in driven connecting rod left side is equipped with the connecting rod hinged-support, the terminal fixed connection in connecting rod hinged-support left side is equipped with the clamp plate. The utility model discloses a grinding sieve, including eccentric spring chamber, fixed connection, eccentric control slider, fixed connection, power transmission intracavity and eccentric driving gear, the connection of eccentric spring intracavity sliding fit is equipped with eccentric control slider, before the eccentric control slider terminal surface with fixed connection is equipped with the eccentric control spring between the end wall before the eccentric spring chamber, before the eccentric control slider terminal surface still with fixed connection is equipped with the stay cord between the upper end surface of grinding sieve, eccentric control slider rear end face normal running fit is connected and is equipped with to extend to backward the power transmission intracavity and with the eccentric control pivot that eccentric spring chamber sliding fit connects, the terminal fixed connection of eccentric control pivot rear side be equipped with can with eccentric gear with the eccentric driving gear.

On the basis of the technical scheme, the sliding fit connection in the blanking limit cavity is provided with a left extending part and a left extending part, the blanking plate cavity extends to the blanking cavity and extends to the blanking cavity right, the blanking plate is arranged in the blanking cavity and extends to the lower side of the blanking plate rack cavity, the fixed connection on the blanking plate is provided with a blanking cavity limiting block which is arranged in the blanking limit cavity and connected with the blanking limit cavity in a sliding fit manner, the right end face of the blanking cavity limiting block is fixedly connected between the walls of the blanking limit cavity right end face and a blanking reset spring, and the part of the rack in the blanking plate extends to the lower side of the blanking plate rack cavity right and can be meshed with the blanking.

On the basis of the technical scheme, two transportation roller rotating shafts which are bilaterally symmetrical by taking the reprocessing cavity as the center are connected and arranged in the feeding roller cavity in a rotating matching way, the transport roller rotating shaft is also fixedly connected with a package transport roller, a package transport belt is arranged between the left package transport roller and the right package transport roller in a power fit connection manner, the transport roller rotating shaft on the right side extends backwards to penetrate through the feeding roller cavity and the transport transmission cavity to the rear end wall of the transport transmission cavity, the transport driven gear positioned in the transport transmission cavity is fixedly connected to the transport roller rotating shaft on the right side, the front end wall and the rear end wall of the transportation transmission cavity are rotationally and cooperatively connected with a transportation transmission rotating shaft which is positioned between the blanking half gear shaft and the transporting roller rotating shaft on the right side, the transportation transmission shaft is fixedly connected with a transportation transmission gear which is positioned in the transportation transmission cavity and is meshed with the transportation driven gear and the transportation half gear at the same time.

The invention has the beneficial effects that: the automatic screening and separating device is adopted, salt can be screened by the elastic screen mesh through intermittent meshing of the rack and the half gear and matching with the spring, and the caked salt is separated independently.

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 diagram of the overall structure of the automatic caking salt screening, processing and packaging device of the invention.

Fig. 2 is a schematic sectional view of a-a in fig. 1.

FIG. 3 is a schematic cross-sectional view of B-B in FIG. 1.

Fig. 4 is a schematic sectional structure view of C-C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, 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 automatic caking salt screening, processing and packaging device disclosed in the attached figures 1-5 comprises a main box 10, wherein a feeding roller cavity 41 with an upward opening is arranged at the lower side of the main box 10, a packaging and transporting cavity 11 with a forward opening and a through left-right opening is communicated with the upper side of the feeding roller cavity 41, a feeding cavity 14 with an upward opening is arranged at the upper side of the packaging and transporting cavity 11, a discharging cavity 42 is communicated between the packaging and transporting cavity 11 and the feeding cavity 14, a discharging limiting cavity 45 is arranged at the right side of the discharging cavity 42, a discharging plate cavity 65 is communicated between the discharging cavity 42 and the discharging limiting cavity 45, a reprocessing discharging cavity 13 is communicated with the right side of the feeding cavity 14, a reprocessing cavity 17 is communicated with the upper side of the reprocessing discharging cavity 13, a heating resistor 69 positioned at the right side of the feeding cavity 14 is fixedly connected in the left end wall of the reprocessing cavity 17, a caking salt falling cavity 16 is communicated between the reprocessing cavity 17 and the right end wall at the upper side, a screening reciprocating cavity 59 is arranged at the rear side of the feeding cavity 14, a screening cavity 58 is communicated between the feeding cavity 14 and the screening reciprocating cavity 59, a screening half gear cavity 62 is communicated at the rear side of the screening reciprocating cavity 59, a pressing plate cavity 53 is communicated at the right side of the reprocessing cavity 17, a power transmission cavity 33 is communicated at the right side of the pressing plate cavity 53, an eccentric spring cavity 30 positioned at the right side of the pressing plate cavity 53 is communicated at the front side of the power transmission cavity 33, a conveying transmission cavity 50 positioned at the rear side of the feeding roller cavity 41 is communicated at the lower side of the power transmission cavity 33, a blanking plate rack cavity 64 positioned at the upper side of the feeding roller cavity 41 and positioned at the front side of the conveying transmission cavity 50 and communicated with the blanking limiting cavity 45 is communicated at the lower side of the feeding roller cavity 41, and a re-screening spring cavity 20 positioned at the lower side of the pressing plate cavity 53 is communicated at the right side of the reprocessing cavity 17, a crushing screen 18 is arranged between the re-screening spring cavity 20 and the re-screening cavity 17 in a sliding fit connection mode, and a re-screening spring 21 is fixedly connected between the lower end face of the crushing screen 18 and the lower end wall of the re-screening spring cavity 20.

In addition, in an embodiment, the rear end wall of the power transmission cavity 33 is rotatably connected with an eccentric driving rotating shaft 36 extending forwards in a matching manner, the rear end wall of the power transmission cavity 33 is fixedly connected with a motor 40 fixedly connected with the eccentric driving rotating shaft 36, the eccentric driving rotating shaft 36 is fixedly connected with a power driving wheel 39, the eccentric driving rotating shaft 36 is further fixedly connected with an eccentric driving gear 35 positioned at the front side of the power driving wheel 39, the rear end wall of the power transmission cavity 33 is rotatably connected with a blanking half gear shaft 56 positioned at the lower side of the eccentric driving rotating shaft 36 and extending forwards, the blanking half gear shaft 56 is fixedly connected with a blanking driven gear 57 engaged with the power driving wheel 39, the tail end of the front side of the blanking half gear shaft 56 is further fixedly connected with a blanking half gear 55, the blanking half gear shaft 56 is further fixedly connected with a blanking half gear 55 positioned at the blanking half gear 55 and the blanking driven gear 57 The rear end wall of the power transmission cavity 33 is provided with a screening driving rotating shaft 54 which extends forwards and is positioned on the upper side of the eccentric driving rotating shaft 36 in a rotating matching manner, and the tail end of the front side of the screening driving rotating shaft 54 is fixedly connected with a screening driving gear 67.

In addition, in one embodiment, the feeding cavity 14 is provided with a blanking screen 15 which extends through the screen cavity 58 to the screening reciprocating cavity 59 in a sliding fit manner and is connected with the screen cavity 58 in a sliding fit manner, the rear end of the blanking screen 15 is fixedly connected with a screening reset rack 61 which is positioned in the screening reciprocating cavity 59 and is connected with the screening reciprocating cavity 59 in a sliding fit manner, a screening reset spring 60 is fixedly connected between the lower end surface of the screening reset rack 61 and the lower end wall of the screening reciprocating cavity 59, the right end wall of the screening half gear cavity 62 is provided with a screening driven rotating shaft 38 which extends leftwards to the screening half gear cavity 62 and rightwards to the power transmission cavity 33 in a rotating fit manner, the left end of the screening driven rotating shaft 38 is fixedly connected with a screening half gear 63 which is positioned in the screening half gear cavity 62 and can be partially meshed with the screening reset rack 61, screening driven shaft 38 right side end is still fixed connection be equipped with be located in power transmission chamber 33 and with screening driven gear 37 of screening driving gear 67 meshing.

In addition, in one embodiment, the front end wall of the pressing plate cavity 53 is connected with an eccentric gear rotating shaft 25 which extends backwards in a rotating fit mode, the rear end of the eccentric gear rotating shaft 25 is fixedly connected with an eccentric gear 26, the eccentric gear 26 is eccentrically connected with an eccentric rotating pin 66, the rear end of the eccentric rotating pin 66 is connected with a driving connecting rod 24 in a rotating fit mode, the left end of the driving connecting rod 24 is connected with a driven connecting rod 23 in a rotating fit mode, the left end of the driven connecting rod 23 is connected with a connecting rod hinged support 27 in a rotating fit mode, and the left end of the connecting rod hinged support 27 is fixedly connected with a pressing plate 22. The eccentric spring cavity 30 is internally provided with an eccentric control slide block 31 in sliding fit connection, an eccentric control spring 29 is fixedly connected between the front end face of the eccentric control slide block 31 and the front end wall of the eccentric spring cavity 30, a pull rope 28 is fixedly connected between the front end face of the eccentric control slide block 31 and the upper end face of the grinding screen 18, an eccentric control rotating shaft 32 which extends backwards into the power transmission cavity 33 and is connected with the eccentric spring cavity 30 in sliding fit connection is connected with the rear end face of the eccentric control rotating shaft 31 in rotating fit connection, and an eccentric control gear 34 which can be simultaneously meshed with the eccentric gear 26 and the eccentric driving gear 35 is fixedly connected with the rear end of the eccentric control rotating shaft 32.

In addition, in an embodiment, the blanking limiting cavity 45 is connected with the rack blanking plate 12 which extends through the blanking plate cavity 65 to the blanking cavity 42 leftwards and extends to the blanking rack cavity 64 rightwards at the same time in a sliding fit manner, the rack blanking plate 12 is fixedly connected with the blanking cavity limiting block 43 which is located in the blanking limiting cavity 45 and is connected with the blanking limiting cavity 45 in a sliding fit manner, the blanking reset spring 44 is fixedly connected between the right end face of the blanking cavity limiting block 43 and the right end wall of the blanking limiting cavity 45, and the inner tooth part of the rack blanking plate 12 which extends to the blanking rack cavity 64 rightwards can be meshed with the blanking half gear 55.

In addition, in one embodiment, the feeding roller cavity 41 is provided with two transportation roller rotating shafts 47 which are bilaterally symmetrical with the reprocessing cavity 17 as the center in a rotationally matched manner, the transportation roller rotating shafts 47 are further fixedly connected with a packaging transportation roller 48, a packaging transportation belt 49 is arranged between the left packaging transportation roller 48 and the right packaging transportation roller 48 in a power fit manner, the transportation roller rotating shaft 47 on the right side extends backwards to penetrate through the feeding roller cavity 41 and the transportation transmission cavity 50 to the rear end wall of the transportation transmission cavity 50, the transportation driven gear 51 positioned in the transportation transmission cavity 50 is fixedly connected with the right transportation roller rotating shaft 47, the transportation transmission rotating shaft 70 is arranged between the blanking half gear shaft 56 and the transportation roller rotating shaft 47 on the front end wall and the rear end wall of the transportation transmission cavity 50 in a rotationally matched manner, and the transportation driven gear 51 and the transportation half gear are fixedly connected with the transportation transmission rotating shaft 70 Gear 68 simultaneously engages transport drive gear 52.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1 to 5, when the apparatus of the present invention is in an initial state, the re-screening spring 21 is in an incomplete compression state, the screening return spring 60 is in an incomplete compression state, the eccentric control spring 29 is in a natural state, the eccentric control gear 34 is not engaged with the eccentric gear 26 and the eccentric driving gear 35, the blanking return spring 44 is in a natural state, the heating resistor 69 is in an unpowered state, the left end surface of the blanking plate 12 with rack is abutted against the left end wall of the blanking chamber 42, the transportation half gear 68 is engaged with the transportation transmission gear 52, and the blanking half gear 55 is not engaged with the rack part of the blanking plate 12 with rack;

sequence of mechanical actions of the whole device:

when the machine starts to work, the motor 40 and the heating resistor 69 are started, the motor 40 works to drive the eccentric driving rotating shaft 36 to rotate, the eccentric driving rotating shaft 36 rotates to drive the power driving wheel 39 and the eccentric driving gear 35 to rotate, the power driving wheel 39 rotates to drive the blanking driven gear 57 and the screening driving gear 67 to rotate, the blanking driven gear 57 rotates to drive the transportation half gear 68 to rotate through the blanking half gear shaft 56, the transportation half gear 68 rotates to drive the transportation driving rotating shaft 70 and the transportation driven gear 51 to rotate through the transportation driving gear 52, the transportation driven gear 51 rotates to drive the right packaging transportation roller 48 to rotate through the right transportation roller rotating shaft 47, the right packaging transportation roller 48 rotates to drive the left transportation roller rotating shaft 47 and the left packaging transportation roller 48 to rotate through the packaging transportation belt 49, and the function of transporting the packaging bags to be filled to the position right, when the packaging bag to be filled is conveyed to the position right below the blanking cavity 42, the half-tooth part of the transportation half-gear 68 is disengaged from the transportation transmission gear 52, so that the transportation roller rotating shaft 47 and the packaging transportation roller 48 stop rotating, the packaging transportation belt 49 stops moving, and the packaging bag to be filled is made to stand still right below the blanking cavity 42 to wait for blanking.

The screening driving gear 67 rotates to drive the screening driving rotating shaft 54 and the screening driven gear 37 to rotate, the screening driven gear 37 rotates to drive the screening half gear 63 positioned in the screening half gear cavity 62 to rotate through the screening driven rotating shaft 38, the screening half gear 63 rotates to drive the screening reset rack 61 meshed with the screening half gear to overcome the elasticity of the screening reset spring 60 to slide downwards along the screening reciprocating cavity 59, the screening reset rack 61 slides downwards to drive the blanking screen 15 to slide downwards along the screen cavity 58, when the screening half gear 63 rotates to be disengaged with the screening reset rack 61, the screening reset rack 61 slides upwards along the screening reciprocating cavity 59 due to the elasticity resilience of the screening reset spring 60, so that the screening reset rack 61 drives the blanking screen 15 to reciprocate up and down in a vertical plane through the screening half gear 63 repeatedly meshed with the screening reset rack 61, and salt poured into the feeding cavity 14 can be screened, normal salt is allowed to fall through the mesh holes of the blanking screen 15 to the lower side of the feed chamber 14, and salt agglomerated due to environmental factors such as moisture is shaken on the grinding screen 18 which falls into the reprocessing chamber 17 through the agglomerated salt falling chamber 16, and the agglomerated salt cannot pass through the grinding screen 18 due to its large volume, and the heat-generating resistor 69 is energized to generate heat to evaporate moisture in the wetted salt.

When the caked salt falls on the grinding screen 18, the weight of the caked salt overcomes the elastic force of the re-screening spring 21 and the eccentric control spring 29 to enable the grinding screen 18 to slide downwards along the re-screening spring cavity 20, the grinding screen 18 slides downwards to drive the eccentric control rotating shaft 32 and the eccentric control sliding block 31 to slide forwards along the eccentric spring cavity 30 through the pull rope 28, the eccentric control sliding block 31 slides forwards to drive the eccentric control gear 34 to slide forwards, at the moment, the eccentric control gear 34 is simultaneously meshed with the eccentric gear 26 and the eccentric driving gear 35, the eccentric driving gear 35 rotates to drive the eccentric gear 26 to rotate through the eccentric control gear 34, the eccentric gear 26 rotates to drive the driven connecting rod 23 and the driving connecting rod 24 to reciprocate in the vertical plane through the eccentric rotating pin 66, the reciprocating motion of the driven connecting rod 23 and the driving connecting rod 24 drives the pressing plate 22 to slide along the pressing plate cavity 53 through, the pressing plate 22 is made to reciprocate in the horizontal plane, so that the caked salt falling on the grinding screen 18 can be extruded to be granular and can fall into the reprocessing discharging cavity 13 through the screen holes of the grinding screen 18, and then fall into the feeding cavity 14, and at the moment, the discharging half gear shaft 56 rotates to drive the discharging half gear 55 to rotate until the half tooth part of the discharging half gear 55 is just meshed with the rack part of the toothed rack discharging plate 12.

The blanking driven gear 57 rotates to drive the blanking half gear 55 to rotate through the blanking half gear shaft 56, the blanking half gear 55 rotates to drive the lower plate 12 with a rack meshed with the blanking half gear to slide rightwards along the blanking plate rack cavity 64 and the blanking plate cavity 65 against the elasticity of the blanking reset spring 44, the lower plate 12 with the rack slides rightwards to drive the blanking cavity limiting block 43 to slide rightwards along the blanking limiting cavity 45, the left end surface of the lower plate 12 with the rack is separated from the left end wall of the blanking cavity 42, the salt processed through screening and grinding falls into a salt packaging bag in the packaging and transporting cavity 11 and right below the blanking cavity 42 through the blanking cavity 42, when a proper amount of salt falls into the packaging bag, the half-tooth part of the blanking half gear 55 is disengaged from the rack part of the lower plate 12 with the rack, the blanking cavity limiting block 43 drives the lower plate 12 with the rack to slide leftwards under the elasticity of the blanking reset spring, the left end face of the blanking plate 12 with the rack is abutted against the left end wall of the blanking cavity 42 again, the blanking cavity 42 is closed and salt does not fall off any more, at the moment, the half-tooth part of the transportation half-gear 68 is just meshed with the transportation transmission gear 52 again, the packaging transportation roller and the transportation roller rotating shaft 47 are rotated, the packaging transportation belt 49 is driven to move rightwards, and the packaged salt enters the next working procedure.

The invention has the beneficial effects that: the automatic screening and separating device is adopted, salt can be screened by the elastic screen mesh through intermittent meshing of the rack and the half gear and matching with the spring, and the caked salt is separated independently.

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 (6)

1. The utility model provides a caking salt autofilter processing packing plant, includes main part case, its characterized in that: the lower side of the main box is provided with a feeding roller cavity with an upward opening, the upper side of the feeding roller cavity is communicated with a packaging and transporting cavity with a forward opening and a through left and right opening, the upper side of the packaging and transporting cavity is provided with a feeding cavity with an upward opening, a blanking cavity is communicated between the packaging and transporting cavity and the feeding cavity, the right side of the blanking cavity is provided with a blanking limiting cavity, a blanking plate cavity is communicated between the blanking cavity and the blanking limiting cavity, the right side of the feeding cavity is communicated with a reprocessing blanking cavity, the upper side of the reprocessing blanking cavity is communicated with a reprocessing cavity, the inner side of the reprocessing cavity left end wall is fixedly connected with a heating resistor positioned on the right side of the feeding cavity, a caking salt falling cavity is communicated between the reprocessing cavity and the upper right end wall of the feeding cavity, the rear side of the feeding cavity is provided with a screening reciprocating cavity, and a screening mesh cavity is communicated between the, the back side of the screening reciprocating cavity is communicated with a screening half gear cavity, the right side of the reprocessing cavity is communicated with a pressure plate cavity, the right side of the pressure plate cavity is communicated with a power transmission cavity, the front side of the power transmission cavity is communicated with an eccentric spring cavity positioned on the right side of the pressure plate cavity, the lower side of the power transmission cavity is communicated with a transportation transmission cavity positioned at the rear side of the feeding roller cavity, the lower side of the power transmission cavity is also communicated with a blanking plate rack cavity positioned at the upper side of the feeding roller cavity and positioned at the front side of the transportation transmission cavity and communicated with the blanking limiting cavity, the right side of the reprocessing cavity is also communicated with a re-screening spring cavity positioned on the lower side of the pressure plate cavity, a crushing screen is connected between the re-screening spring cavity and the reprocessing cavity in a sliding fit manner, and a re-screening spring is fixedly connected between the lower end surface of the crushing screen and the lower end wall of the re-screening spring cavity.

2. The automatic caking salt screening, processing and packaging device according to claim 1, wherein: the rear end wall of the power transmission cavity is internally and fixedly connected with a motor fixedly connected with the eccentric driving rotating shaft, the eccentric driving rotating shaft is fixedly connected with a power driving wheel, the eccentric driving rotating shaft is also fixedly connected with an eccentric driving gear positioned at the front side of the power driving wheel, the rear end wall of the power transmission cavity is internally and fixedly connected with a blanking half gear shaft which is positioned at the lower side of the eccentric driving rotating shaft and extends forwards, the blanking half gear shaft is fixedly connected with a blanking driven gear engaged with the power driving wheel, the tail end of the front side of the blanking half gear shaft is also fixedly connected with a blanking half gear, and the blanking half gear shaft is also fixedly connected with a transportation half gear positioned between the blanking half gear and the blanking driven gear, it is equipped with and extends forward and be located still to normal running fit connection in the power transmission chamber rear end wall the screening initiative pivot of eccentric initiative pivot upside, the terminal fixed connection of screening initiative pivot front side is equipped with the screening driving gear.

3. The automatic caking salt screening, processing and packaging device according to claim 1, wherein: feeding intracavity sliding fit connects to be equipped with and extends backward run through the screen cloth chamber extremely screen cloth chamber reciprocal intracavity and with the unloading screen cloth that screen cloth chamber sliding fit connects, the terminal fixed connection in unloading screen cloth rear side is equipped with and is located screening reciprocal intracavity and with the screening rack that resets that screening reciprocal chamber sliding fit connects, screening reset rack down the terminal surface with fixed connection is equipped with screening reset spring under the screening reciprocal chamber between the end wall, screening half gear chamber right side end wall internal rotation cooperation is connected and is equipped with and extends to left screening half gear intracavity and extend to right screening driven rotating shaft in the power transmission intracavity, screening driven rotating shaft left end fixed connection is equipped with and is located screening half gear intracavity and can with screening reset rack part mesh's screening half gear, screening driven rotating shaft right side end still fixed connection be equipped with and is located power transmission intracavity and with screening driving gear meshes the gear mesh portion's screening half gear And (4) a combined screening driven gear.

4. The automatic caking salt screening, processing and packaging device according to claim 1, wherein: the eccentric gear pivot that the end normal running fit connection of pressure plate chamber front end was equipped with backward extension, the terminal fixed connection of eccentric gear pivot rear side is equipped with eccentric gear, the eccentric of fixed connection is equipped with eccentric commentaries on classics round pin on the eccentric gear, the terminal normal running fit connection of eccentric commentaries on classics round pin rear side is equipped with the initiative connecting rod, the terminal normal running fit connection in initiative connecting rod left side is equipped with driven connecting rod, the terminal normal running fit connection in driven connecting rod left side is equipped with connecting rod hinged-support, the terminal fixed connection in connecting rod hinged-support left side is equipped with the clamp plate, eccentric spring intracavity normal running fit connection is equipped with the eccentric control slider, eccentric control slider front end face with fixed connection is equipped with the eccentric control spring between the eccentric spring chamber front end wall, before the eccentric control slider terminal surface still with fixed connection is equipped with the stay cord between the grinding screen up terminal surface, eccentric control slider rear end face normal The eccentric control pivot that eccentric spring chamber sliding fit connected, the terminal fixed connection of eccentric control pivot rear side be equipped with can with eccentric gear with the eccentric driving gear meshing's eccentric control gear simultaneously.

5. The automatic caking salt screening, processing and packaging device according to claim 1, wherein: the spacing intracavity sliding fit of unloading connects and is equipped with and extends to extend left and run through the unloading board chamber extremely the unloading intracavity and extend right simultaneously to the flitch under the area rack of flitch rack intracavity, take rack under on the flitch fixed connection be located the spacing chamber of unloading and with the unloading chamber stopper that the spacing chamber sliding fit of unloading is connected, unloading chamber stopper right-hand member face with fixed connection is equipped with unloading reset spring between the spacing chamber right-hand member wall of unloading, take rack under the flitch extend right to the unloading rack intracavity rack part can with unloading semi-gear engagement.

6. The automatic caking salt screening, processing and packaging device according to claim 1, wherein: two transportation roller rotating shafts which are bilaterally symmetrical by taking the reprocessing cavity as the center are rotationally and cooperatively connected in the feeding roller cavity, the transport roller rotating shaft is also fixedly connected with a package transport roller, a package transport belt is arranged between the left package transport roller and the right package transport roller in a power fit connection manner, the transport roller rotating shaft on the right side extends backwards to penetrate through the feeding roller cavity and the transport transmission cavity to the rear end wall of the transport transmission cavity, the transport driven gear positioned in the transport transmission cavity is fixedly connected to the transport roller rotating shaft on the right side, the front end wall and the rear end wall of the transportation transmission cavity are rotationally and cooperatively connected with a transportation transmission rotating shaft which is positioned between the blanking half gear shaft and the transporting roller rotating shaft on the right side, the transportation transmission shaft is fixedly connected with a transportation transmission gear which is positioned in the transportation transmission cavity and is meshed with the transportation driven gear and the transportation half gear at the same time.

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