CN116748498B - Casting molding shakeout device for main body support of stainless steel connector - Google Patents

Abstract

The invention relates to the technical field of casting molding shakeout of a main body support of a stainless steel connector, in particular to a casting molding shakeout device of the main body support of the stainless steel connector, which comprises a shakeout frame, a cleaning mechanism and a recovery mechanism, wherein in the cleaning mechanism designed by the invention, a rotating plate drives the stainless steel connector support to rotate through a supporting round rod in the rotating process, and then the stainless steel connector support simultaneously moves rightwards in the rotating process, so that the stainless steel connector support and the cleaning plate are in contact with each other, and the cleaning plate can clean molding sand on the surface of the stainless steel connector support, thereby guaranteeing the shakeout effect of the surface of the stainless steel connector support; in the recovery mechanism designed by the invention, the recovery pipe is matched with the existing dust collection equipment through the transition pipe, so that the diffused shakeout inside the shakeout frame can be adsorbed, the air pollution caused by scattering of molding sand into the air is avoided, and meanwhile, the waste of molding sand is reduced.

Description

Casting molding shakeout device for main body support of stainless steel connector

Technical Field

The invention relates to the technical field of casting molding shakeout of a main body support of a stainless steel connector, in particular to a casting molding shakeout device of the main body support of the stainless steel connector.

Background

The stainless steel joint is one of the most widely used fittings in point support glass engineering, and is a member for assembling one glass block in a curtain wall into a whole through a plurality of joints at the corners of the glass and transmitting the load born by the glass to a wall structure.

The stainless steel connector is usually obtained in a casting forming mode, molding sand possibly adheres to the surface of the formed stainless steel connector, and the adhered molding sand can influence the subsequent use of the stainless steel connector, so that the molding sand on the surface of the stainless steel connector needs to be removed before the stainless steel connector leaves a factory.

The Chinese patent application with publication number of CN113182507A discloses a shakeout device for processing high-efficiency metal castings: this high-efficient knockout device for metal casting processing drives bars bed and unloading cavity through vibrating motor work and takes place to make the grid together vibrate, thereby can drive through the grid vibration and hold by splint and hold fixed metal casting together and take place the vibration, thereby can make metal casting and molding sand separation, and fix metal casting through fixed establishment, avoid the position of metal casting to appear moving, after the foundry goods separation, be convenient for take off the foundry goods from fixed establishment.

The patent application can be used in the process of shakeout of the stainless steel spider main body support, and has the characteristics of simple and convenient operation, convenient collection and the like, but has the following defects: 1. the above-mentioned patent application carries out the shakeout to the metal foundry goods through the mode of vibration only and handles, and some more firm molding sand of adhesion on metal foundry goods surface probably fail to shake off, and then lead to the metal foundry goods surface still to remain there is molding sand to influence the shakeout effect on metal foundry goods surface.

Above-mentioned patent application is collected the knockout on metalwork surface and is handled through bars bed and unloading cavity cooperation mutually only, because the knockout shakes some tiny dust of its inside in-process and probably permeate around the device, and then influences the pollution of environment, can cause the waste of molding sand simultaneously, influences the subsequent recycle of molding sand.

Disclosure of Invention

The invention aims to provide a casting molding shakeout device for a main body support of a stainless steel connector, wherein a rotating plate drives the stainless steel connector support to rotate through a supporting round rod, and the stainless steel connector support is matched with a cleaning plate in the rotating process of the stainless steel connector support so as to sweep out shakeout on the surface of the stainless steel connector support.

The invention is realized by adopting the following technical scheme, and discloses a casting molding shakeout device for a main body bracket of a stainless steel spider.

The cleaning mechanism comprises a moving groove which penetrates through the upper side wall of the sand falling frame, a moving block which slides left and right is arranged in the moving groove in a penetrating mode in a limiting mode, a fixing rod and the fixing block are sequentially arranged at the lower end of the moving block from top to bottom, a rotating plate is arranged on the front end face and the rear end face of the fixing block, a supporting round rod used for placing a stainless steel connector bracket is arranged on one side, far away from the fixing block, of the rotating plate, two groups of cleaning plates which are used for cleaning the stainless steel connector bracket and correspond to the supporting round rod are arranged at the top of the sand falling frame in a penetrating mode, and the cleaning plates are uniformly distributed from front to back.

The recovery mechanism comprises a plurality of recovery pipes which are uniformly arranged on the front inner wall and the rear inner wall of the shakeout frame from top to bottom, wherein recovery holes which are communicated with the inside of the recovery pipes are formed in the side walls of the recovery pipes, and a plurality of transition pipes which are communicated with the recovery pipes are arranged on the front side wall and the rear side wall of the shakeout frame in a penetrating manner.

Optionally, the fixed block around the terminal surface all install the connecting rod, the pivoted plate passes through the bearing and installs the one end that keeps away from the fixed block at the connecting rod, installs the teeth of a cogwheel on the pivoted plate periphery, the inside rack board one that meshes with the teeth of a cogwheel that is provided with of shakeout frame, rack board one upper end is fixed at the inside up end of shakeout frame through bilateral symmetry's connection arch.

Optionally, the cleaning board slide and set up at knockout frame top up end, the gangboard that can reset automatically is installed jointly to the gangboard up end with group cleaning, but the pivot corresponding with the gangboard is installed in rotation of knockout frame up end, gear one and cam are installed in proper order from bottom to top to the pivot periphery, and the cam offsets with the gangboard of homonymy and leans on, rack board two with homonymy gear one engaged with is installed to the movable block right-hand member face.

Optionally, the lower terminal surface in the shakeout frame be provided with two sets of jet plates corresponding with the scavenging plate, the jet orifices that evenly distributed just link up with its inside are seted up to jet plate left and right sides, install the intake pipe rather than link up mutually jointly between the jet plate of same group, the lower terminal surface in the shakeout frame runs through and has seted up a plurality of blanking grooves.

Optionally, the shakeout frame below be provided with the ascending collection frame of opening, both sides are provided with the joint arch around the collection frame upper end face, and two joint archs spacing slip respectively set up both sides around the shakeout frame, both sides run through around the collection frame be provided with homonymy transition pipe matched with collect the connecting tube.

Optionally, the movable block inside seted up about the rolling groove that link up, the inside rotation of rolling groove is provided with bilateral symmetry's rolling axle, installs intermeshing's gear two on two rolling axles, all installs on two rolling axles and shelter from cloth, the one end that the rolling axle was kept away from to left shelter from cloth is fixed at the left side wall of movable groove, the one end that the rolling axle was kept away from to right side shelter from cloth is fixed at the right side wall of movable groove.

Optionally, the supporting round rod is provided with threads on the circumferential surface, and a limit bolt for limiting the stainless steel connector bracket is arranged on the supporting round rod in a threaded connection mode.

Optionally, a sealing cloth for sealing the opening of the shakeout frame is arranged inside the left end face of the top of the shakeout frame.

Compared with the prior art, the casting molding shakeout device for the main body support of the stainless steel spider has the beneficial effects that: 1. in the cleaning mechanism designed by the invention, the stainless steel connector bracket is driven to rotate by the supporting round rod in the rotating process of the rotating plate, and then the stainless steel connector bracket moves rightwards in the rotating process, so that the stainless steel connector bracket and the cleaning plate are in contact with each other, the cleaning plate can clean molding sand on the surface of the stainless steel connector bracket, and the shakeout effect of the surface of the stainless steel connector bracket is ensured.

2. In the recovery mechanism designed by the invention, the recovery pipe is matched with the existing dust collection equipment through the transition pipe, so that the diffused shakeout inside the shakeout frame can be adsorbed, the air pollution caused by scattering of molding sand into the air is avoided, and meanwhile, the waste of molding sand is reduced.

3. The second rack plate is driven to move right in the rightward moving process of the moving block, the rotating shaft is driven to rotate by the gear in the rightward moving process of the second rack plate, the cleaning plate is driven to reciprocate left and right by the mutual cooperation of the cam and the linkage plate in the rotating process of the rotating shaft, the cleaning plate and the stainless steel connector support are rubbed with each other in the reciprocating process of the cleaning plate, and therefore the cleaning effect of the cleaning plate on the stainless steel connector support in the reciprocating process is improved.

Drawings

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In order that those skilled in the art will better understand the present invention, the following description will be given in detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of a three-dimensional installation structure between a stainless steel connector main body support casting molding shakeout device and a stainless steel connector support according to an embodiment of the present invention.

Fig. 2 is a partial enlarged view at a of fig. 1 provided by an embodiment of the present invention.

Fig. 3 is a schematic perspective view of fig. 1 according to an embodiment of the present invention.

Fig. 4 is a schematic view of a three-dimensional installation structure among a stainless steel connector bracket, a supporting round rod and a moving block according to an embodiment of the invention.

Fig. 5 is a schematic view of a three-dimensional installation structure among a fixed rod, a supporting round rod and a moving block according to an embodiment of the present invention.

Fig. 6 is a schematic view of a three-dimensional installation structure among a cleaning plate, a linkage plate and a rotating shaft according to an embodiment of the present invention.

Fig. 7 is a schematic view of a three-dimensional installation structure among a linkage plate, a rotating shaft and a cam according to an embodiment of the invention.

Fig. 8 is a left side view of fig. 1 provided by an embodiment of the present invention.

Fig. 9 is a partial enlarged view at B of fig. 8 provided by an embodiment of the present invention.

Fig. 10 is a schematic view of a three-dimensional installation structure between a sand dropping frame and an air injection plate according to an embodiment of the present invention.

Fig. 11 is a schematic diagram of an internal structure of a moving block according to an embodiment of the present invention.

Fig. 12 is a schematic perspective view of a stainless steel connector bracket according to an embodiment of the present invention.

Icon: 1. a sand dropping frame; 11. a moving groove; 12. sealing cloth; 13. an air jet plate; 14. a gas injection hole; 15. an air inlet pipe; 16. a material dropping groove; 2. a cleaning mechanism; 21. a moving block; 211. a winding groove; 212. a winding shaft; 213. a second gear; 214. a shielding cloth; 22. a fixed rod; 23. a fixed block; 231. a connecting rod; 232. gear teeth; 233. rack plate I; 24. a rotating plate; 25. supporting the round rod; 251. a limit bolt; 26. a cleaning plate; 261. a linkage plate; 262. a rotating shaft; 263. a first gear; 264. a cam; 265. rack plate II; 266. a reset spring lever; 3. a recovery mechanism; 31. a recovery pipe; 32. a recovery hole; 33. a transition pipe; 34. a collection frame; 35. collecting connecting pipes; 4. stainless steel spider support.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. The present invention may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the invention, whereby the invention is not limited to the specific embodiments disclosed below.

Referring to fig. 1, a casting molding shakeout device for a main body support of a stainless steel connector comprises a shakeout frame 1 with a left opening, wherein a cleaning mechanism 2 and a recovery mechanism 3 are arranged on the shakeout frame 1.

Referring to fig. 3 to 5, the cleaning mechanism 2 includes a moving slot 11 penetrating through the upper sidewall of the sand drop frame 1, wherein a moving block 21 sliding left and right is disposed in the moving slot 11 in a penetrating and limiting manner, a fixing rod 22 and a fixing block 23 are sequentially mounted at the lower end of the moving block 21 from top to bottom, a rotating plate 24 is disposed on the front and rear end surfaces of the fixing block 23, a supporting round rod 25 for placing the stainless steel connector bracket 4 is mounted on one side of the rotating plate 24 away from the fixing block 23, two groups of cleaning plates 26 for cleaning the stainless steel connector bracket 4 and corresponding to the supporting round rod 25 are disposed on the top of the sand drop frame 1 in a penetrating manner, and each group of cleaning plates 26 are uniformly distributed from front to back.

Referring to fig. 5, the circumferential surface of the supporting round rod 25 is provided with threads, and the supporting round rod 25 is provided with a limit bolt 251 for limiting the stainless steel connector bracket 4 in a threaded connection manner.

Referring to fig. 12, in specific operation, the limit bolt 251 is taken down from the supporting round rod 25, the stainless steel connector supports 4 are screwed on the supporting round rod 25 one by one, the threads can be matched with the stainless steel connector supports 4 to ensure that the stainless steel connector supports 4 cannot slide back and forth on the supporting round rod 25, the limit bolt 251 is reset, the limit bolt 251 can carry out secondary limit treatment on the stainless steel connector supports 4, and the stability of the stainless steel connector supports 4 on the supporting round rod 25 in the subsequent rotation process is ensured.

Wherein the cleaning plate 26 is internally provided with a brush, when the stainless steel connector bracket 4 is placed and limited, the moving block 21 is pulled to move from left to right by the existing driving force (a person pulls or an existing driving cylinder), the moving block 21 is mutually matched with the fixed block 23 through the fixed rod 22 to drive the rotating plate 24 to move rightwards in the moving process, and the rotating plate 24 drives the stainless steel connector bracket 4 to move rightwards through the supporting round rod 25 in the rightwards moving process.

Referring to fig. 2, a sealing cloth 12 for sealing an opening of the sealing cloth is arranged in the left end face of the top of the shakeout frame 1, when the stainless steel connector bracket 4 completely moves into the shakeout frame 1, the sealing cloth 12 is pulled downwards at this time so that the sealing cloth 12 is clamped at the bottom of the shakeout frame 1, and then the opening of the shakeout frame 1 can be blocked by the sealing cloth 12, so that sand is prevented from being scattered from the shakeout frame 1 in the continuous shakeout process.

Referring to fig. 4 and 5, the front and rear end surfaces of the fixed block 23 are respectively provided with a connecting rod 231, the rotating plate 24 is mounted at one end of the connecting rod 231 far away from the fixed block 23 through a bearing, the circumferential surface of the rotating plate 24 is provided with gear teeth 232, a first rack plate 233 meshed with the gear teeth 232 is arranged in the shakeout frame 1, and the upper end of the first rack plate 233 is fixed at the upper end surface of the inner part of the shakeout frame 1 through connecting protrusions which are symmetrical left and right.

The rotating plate 24 is mutually meshed with the first rack plate 233 through the gear teeth 232 in the left-right moving process, the rotating plate 24 drives the supporting round rod 25 to synchronously rotate, at the moment, the stainless steel connector support 4 is driven to synchronously rotate through the supporting round rod 25 in the right moving process, when the stainless steel connector support 4 moves to the inside of the cleaning plate 26, the rotating stainless steel connector support 4 is mutually contacted with the hairbrush, and the cleaning plate 26 can sweep molding sand on the surface of the stainless steel connector support 4 through the hairbrush, so that the shakeout effect of the surface of the stainless steel connector support 4 is guaranteed.

Referring to fig. 6, 7 and 9, the cleaning plates 26 are slidably disposed on the top upper end surface of the sand-dropping frame 1, the upper end surfaces of the same group of cleaning plates 26 are jointly provided with a linkage plate 261 capable of automatically resetting, the upper end surface of the sand-dropping frame 1 is rotatably provided with a rotating shaft 262 corresponding to the linkage plate 261, the circumferential surface of the rotating shaft 262 is sequentially provided with a first gear 263 and a cam 264 from bottom to top, the cam 264 abuts against the linkage plate 261 on the same side, and the right end surface of the moving block 21 is provided with a second rack plate 265 meshed with the first gear 263 on the same side.

The upper end face of the top of the sand falling frame 1 is provided with a fixing protrusion corresponding to the linkage plate 261, a reset spring rod 266 is commonly arranged between the fixing protrusion and the corresponding linkage plate 261, the rack plate II 265 is driven to move rightwards in the rightward moving process of the moving block 21, the rotating shaft 262 is driven to rotate by the gear II 263 in the rightward moving process of the rack plate II, the cleaning plate 26 is driven to reciprocate leftwards and rightwards by the mutual matching of the cam 264 and the linkage plate 261 in the rotating process of the rotating shaft 262, the brush is driven to rub against the stainless steel connector support 4 in the reciprocating process of the cleaning plate 26, and further the cleaning effect of the cleaning plate 26 on the stainless steel connector support 4 in the reciprocating process is further improved, and the reset spring rod 266 plays a reset role on the linkage plate 261 in the leftward and rightward reciprocating process of the cam 264 driving the linkage plate 261.

Referring to fig. 8 and 10, two groups of air injection plates 13 corresponding to the cleaning plates 26 are disposed on the inner lower end surface of the sand-falling frame 1, air injection holes 14 which are uniformly distributed and communicated with the inner parts of the air injection plates 13 are disposed on the left and right sides of the air injection plates 13, air inlet pipes 15 communicated with the air injection plates 13 are commonly mounted between the air injection plates 13 of the same group, and a plurality of material-falling grooves 16 are disposed on the inner lower end surface of the sand-falling frame 1.

The air inlet pipe 15 is connected with an existing air pump (not shown in the figure), the air pump is started to pump air into the air inlet pipe 15 in the process of carrying out shakeout treatment on molding sand on the surface of the stainless steel connector support 4 by mutually matching the cleaning plate 26 and the hairbrush, the air is sprayed out from the air spraying holes 14 after passing through the air spraying plate 13, and the sprayed air can carry out secondary cleaning treatment on residual molding sand on the surface of the stainless steel connector support 4, so that the molding sand removing effect on the surface of the stainless steel connector support 4 is better.

The recovery mechanism 3 comprises a plurality of recovery pipes 31 which are uniformly arranged on the front and rear inner walls of the sand falling frame 1 from top to bottom, wherein the side walls of the recovery pipes 31 are provided with recovery holes 32 communicated with the inside of the recovery pipes, and the front and rear side walls of the sand falling frame 1 are provided with a plurality of transition pipes 33 communicated with the recovery pipes 31 in a penetrating manner.

Referring to fig. 1, a collecting frame 34 with an upward opening is provided below the shakeout frame 1, two clamping protrusions are provided on front and rear sides of an upper end surface of the collecting frame 34, the two clamping protrusions are respectively disposed on front and rear sides of the shakeout frame 1 in a limiting sliding manner, and collecting connecting pipes 35 matched with the same-side transition pipes 33 are arranged on front and rear sides of the collecting frame 34 in a penetrating manner.

In a specific operation, the collecting connecting pipes 35 are all provided with dust collectors (not shown in the figure), rubber hoses (not shown in the figure) are commonly arranged between the transition pipes 33 on the same side, and then the lower ends of the rubber hoses are connected with dust collecting openings of the dust collectors on the same side.

The granular molding sand after sweeping and blowing falls into the collecting frame 34 through the blanking groove 16, and when the device is specifically operated, the dust collector is started to mutually cooperate with the transition pipe 33 through the rubber hose so that pressure difference is generated inside and outside the recovery hole 32, and then the powdery molding sand which is in the sweeping and blowing process and is diffused in the air is adsorbed into the collecting frame 34 through the recovery hole 32, the recovery pipe 31, the transition pipe 33 and the rubber hose, so that the pollution of the air caused by scattering of the molding sand into the air is avoided, and meanwhile, the recycling treatment can be carried out on the molding sand, so that the waste of the molding sand is reduced.

When the sand in the collection frame 34 is filled, the rubber hose is removed, and the collection frame 34 is drawn out to the left from below the blanking frame, so that the sand in the collection frame 34 is uniformly collected.

When the moving block 21 moves to the rightmost side of the shakeout frame 1, the moving block 21 is reset at the moment and continues to move leftwards to the initial position, and after the moving block 21 is reset, the sealing cloth 12 is opened to take the stainless steel spider support 4 off the supporting round rod 25.

Referring to fig. 11, a winding groove 211 is formed in the moving block 21, the winding groove 211 is provided with a winding shaft 212 which is symmetrical left and right, two winding shafts 212 are provided with two gears 213 which are meshed with each other, two winding shafts 212 are provided with shielding cloth 214, one end of the left shielding cloth 214, which is far away from the winding shaft 212, is fixed on the left side wall of the moving groove 11, and one end of the right shielding cloth 214, which is far away from the winding shaft 212, is fixed on the right side wall of the moving groove 11.

When the moving block 21 moves from left to right, the left shielding cloth 214 is loosened from the left winding shaft 212, the left shielding cloth 214 drives the left winding shaft 212 to rotate in the loosening process, the right winding shaft 212 is driven to rotate by the mutual meshing of the gears 213 in the rotating process of the left winding shaft 212, and the right winding shaft 212 can wind the right shielding cloth 214; when the moving block 21 moves from right to left, the right shielding cloth 214 is loosened from the right winding shaft 212, the right shielding cloth 214 is driven to rotate by the right winding shaft 212 in the loosening process, the left winding shaft 212 is driven to rotate by the mutual meshing of the gears two 213 in the rotating process of the right winding shaft 212, and then the left winding shaft 212 can wind the left shielding cloth 214.

The shielding cloth 214 can be guaranteed to seal the movable groove 11 all the time through the mutual cooperation of the two steps, powder molding sand scattered inside the sand falling frame 1 is prevented from escaping from the movable groove 11, the environmental sanitation near the device is improved, the shielding cloth 214 can be guaranteed to be always flush with the movable groove 11 by the winding shaft 212, meanwhile, the shielding cloth 214 is prevented from scattering inside the sand falling frame 1, and the phenomenon that the winding between the shielding cloth 214 and the gear teeth 232 affects the rotation effect of the gear teeth 232 to drive the rotating plate 24 is avoided.

The invention comprises the following steps in the casting molding shakeout process of the stainless steel spider main body bracket: the first step: the limit bolts 251 are taken down from the supporting round rods 25, the stainless steel connector brackets 4 are screwed on the supporting round rods 25 one by one, and then the limit bolts 251 are reset.

And a second step of: the moving block 21 is pulled to move from left to right, the rotating plate 24 is driven to move rightwards by the mutual cooperation of the fixed rod 22 and the fixed block 23 in the moving process of the moving block 21, and the stainless steel connector bracket 4 is driven to move rightwards by the supporting round rod 25 in the rightwards moving process of the rotating plate 24.

And a third step of: the rotating plate 24 is mutually meshed with the first rack plate 233 through the gear teeth 232 in the left-to-right moving process, the rotating plate 24 drives the supporting round rod 25 to synchronously rotate, at the moment, the stainless steel connector support 4 is driven to synchronously rotate through the supporting round rod 25 in the right moving process, when the stainless steel connector support 4 moves into the cleaning plate 26, the rotating stainless steel connector support 4 is mutually contacted with the hairbrush, and the cleaning plate 26 can clean molding sand on the surface of the stainless steel connector support 4 through the hairbrush.

Fourth step: the second rack plate 265 is driven to move rightwards in the rightward moving process of the moving block 21, the first gear 263 drives the rotating shaft 262 to rotate in the rightward moving process of the second rack plate 265, the cam 264 and the linkage plate 261 are matched with each other in the rotating process of the rotating shaft 262 to drive the cleaning plate 26 to reciprocate leftwards and rightwards, and the cleaning plate 26 drives the brush to rub against the stainless steel connector support 4 in the reciprocating moving process of the cleaning plate 26.

Fifth step: the air pump is started to pump air into the air inlet pipe 15, the air is sprayed out from the air spraying holes 14 after passing through the air spraying plate 13, and the sprayed air can carry out secondary cleaning treatment on the residual molding sand on the surface of the stainless steel connector bracket 4.

Sixth step: the vacuum cleaner is started, and the rubber hose and the transition pipe 33 are matched with each other, so that pressure difference is generated inside and outside the recovery hole 32, and then powdery molding sand which is cleaned and purged and is diffused in the air is adsorbed into the collection frame 34 through the recovery hole 32, the recovery pipe 31, the transition pipe 33 and the rubber hose.

In the description of the present invention, it should be understood that the azimuth or positional relationships indicated by the azimuth terms such as "front, rear, upper, lower, left, right", "lateral, vertical, horizontal", and "top, bottom", etc., are generally based on the azimuth or positional relationships shown in the drawings, merely to facilitate description of the present invention and simplify the description, and these azimuth terms do not indicate and imply that the apparatus or elements referred to must have a specific azimuth or be constructed and operated in a specific azimuth, and thus should not be construed as limiting the scope of protection of the present invention; the orientation word "inner and outer" refers to inner and outer relative to the contour of the respective component itself.

Furthermore, the terms "first," "second," "first," and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "first", "second", "first", "second" may include at least one such feature, either explicitly or implicitly. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the description of the present invention, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "connected," "mounted," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

The embodiments of the present invention are all preferred embodiments of the present invention, and are not limited in scope by the present invention, so that all equivalent changes according to the structure, shape and principle of the present invention are covered in the scope of the present invention.

Claims (6)

1. The utility model provides a stainless steel refutes and connects body support casting shaping shakeout device, includes that the opening is shakeout frame (1) left, its characterized in that: the shakeout frame (1) is provided with a cleaning mechanism (2) and a recovery mechanism (3), wherein the cleaning mechanism is a cylinder;

the cleaning mechanism (2) comprises a moving groove (11) which is formed in the upper side wall of the shakeout frame (1) in a penetrating mode, a moving block (21) which slides left and right is arranged in the moving groove (11) in a penetrating and limiting mode, a fixed rod (22) and a fixed block (23) are sequentially arranged at the lower end of the moving block (21) from top to bottom, a rotating plate (24) is arranged on the front end face and the rear end face of the fixed block (23), a supporting round rod (25) for placing the stainless steel spider bracket (4) is arranged on one side, far away from the fixed block (23), of the rotating plate (24), two groups of cleaning plates (26) which are used for cleaning the stainless steel spider bracket (4) and correspond to the supporting round rod (25) are arranged on the top of the shakeout frame (1) in a penetrating mode, and each group of cleaning plates (26) are uniformly distributed from front to back;

the recovery mechanism (3) comprises a plurality of recovery pipes (31) which are uniformly arranged on the front inner wall and the rear inner wall of the shakeout frame (1) from top to bottom, wherein recovery holes (32) communicated with the inside of the recovery pipes are formed in the side walls of the recovery pipes (31), and a plurality of transition pipes (33) communicated with the recovery pipes (31) are arranged on the front side wall and the rear side wall of the shakeout frame (1) in a penetrating manner;

the front end face and the rear end face of the fixed block (23) are both provided with connecting rods (231), a rotating plate (24) is arranged at one end, far away from the fixed block (23), of the connecting rods (231) through bearings, gear teeth (232) are arranged on the circumferential surface of the rotating plate (24), a rack plate I (233) meshed with the gear teeth (232) is arranged inside the shakeout frame (1), and the upper end of the rack plate I (233) is fixed at the upper end face inside the shakeout frame (1) through connecting protrusions which are bilaterally symmetrical;

the cleaning plate (26) is arranged on the upper end face of the top of the shakeout frame (1) in a sliding mode, the linkage plates (261) capable of automatically resetting are mounted on the upper end faces of the same group of cleaning plates (26) together, a rotating shaft (262) corresponding to the linkage plates (261) is rotatably mounted on the upper end face of the shakeout frame (1), a first gear (263) and a cam (264) are sequentially mounted on the circumferential face of the rotating shaft (262) from bottom to top, the cam (264) abuts against the linkage plates (261) on the same side, and a second rack plate (265) meshed with the first gear (263) on the same side is mounted on the right end face of the moving block (21).

2. The stainless steel spider body support cast molding shakeout device of claim 1, wherein: the inner lower end face of the shakeout frame (1) is provided with two groups of air injection plates (13) corresponding to the cleaning plates (26), air injection holes (14) which are uniformly distributed and communicated with the inner parts of the air injection plates (13) are formed in the left side and the right side of the air injection plates (13), air inlet pipes (15) communicated with the air injection plates are commonly arranged between the air injection plates (13) in the same group, and a plurality of blanking grooves (16) are formed in the inner lower end face of the shakeout frame (1) in a penetrating mode.

3. The stainless steel spider body support cast molding shakeout device of claim 1, wherein: the shakeout device is characterized in that a collecting frame (34) with an upward opening is arranged below the shakeout frame (1), clamping bulges are arranged on the front side and the rear side of the upper end face of the collecting frame (34), the two clamping bulges are respectively arranged on the front side and the rear side of the shakeout frame (1) in a limiting sliding mode, and collecting connecting pipes (35) matched with the same-side transition pipes (33) are arranged on the front side and the rear side of the collecting frame (34) in a penetrating mode.

4. The stainless steel spider body support cast molding shakeout device of claim 1, wherein: the winding groove (211) that link up about the movable block (21) inside seted up, winding groove (211) inside rotation is provided with bilateral symmetry's winding axle (212), installs intermeshing's gear two (213) on two winding axles (212), all installs on two winding axles (212) and shelter from cloth (214), the one end that winding axle (212) was kept away from to left shelter from cloth (214) is fixed at the left side wall of movable groove (11), the one end that winding axle (212) was kept away from to right side is fixed at the right side wall of movable groove (11).

5. The stainless steel spider body support cast molding shakeout device of claim 1, wherein: the stainless steel connector is characterized in that threads are formed on the circumferential surface of the supporting round rod (25), and a limit bolt (251) used for limiting the stainless steel connector support (4) is arranged on the supporting round rod (25) in a threaded connection mode.

6. The stainless steel spider body support cast molding shakeout device of claim 1, wherein: the inside sealing cloth (12) for sealing the opening of the left end face of the top of the shakeout frame (1) is arranged.