CN215202638U - Small-size component automated production all-in-one - Google Patents

Abstract

The utility model provides a small-sized component automatic production integrated machine, which relates to the technical field of building material manufacturing, and comprises a vibration feeding bed, wherein a forming material box is placed on the vibration feeding bed, a horizontal material conveying track is arranged above the vibration feeding bed, a first material conveying box is arranged on the horizontal material conveying track, and a first material discharging hole is formed in the first material conveying box; the utility model can effectively avoid the phenomena of segregation, bleeding and the like in the process of directly unloading the traditional concrete from the transport vehicle to the prefabricated box, the prefabricated part vibrates compactly on the roller shaft, and avoids the phenomena of uneven manual vibration, vibration leakage and lack of vibration; the manual operation is liberated, the labor intensity of operators is reduced, the production efficiency and the production quality of small prefabricated parts can be effectively improved, the operators can operate the small prefabricated parts through simple operation training, high-quality products are produced, and the quality problems and the defects of engineering products caused by human factors are avoided.

Description

Small-size component automated production all-in-one

Technical Field

The utility model belongs to the technical field of the building material manufacture technique and specifically relates to a small-size component automated production all-in-one is related to.

Background

In the field of road and bridge construction, small prefabricated parts such as kerbs, ditch covers, prefabricated table caps and the like are often needed, and generally, the parts are formed by pouring concrete and the like in a mold box, but due to the nature of the concrete and the technical means of the pouring process, the poured prefabricated parts may not be completely filled inside, and cavities such as honeycomb surfaces remained due to air bubbles exist inside, so that the quality of the whole prefabricated part is reduced.

In order to solve the above problems, in general, a pouring operator needs to transport the concrete in the concrete car to the forming material box by shoveling the concrete, and then, when the concrete is still in a fluid state, the inner air bubbles float and escape by shaking or vibrating the die material box, thereby improving the quality of the prefabricated member.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a small-size component automated production all-in-one, this small-size component automated production all-in-one can carry out concrete vibration shaping to the shaping magazine simultaneously at the removal in-process through the vibration material conveying bed, simultaneously through horizontal material transporting track and draw the material loading track to one side, establish the concrete transfer route to the shaping magazine by the concrete car.

The utility model provides a small-size component automated production all-in-one, including vibration pay-off bed, the shaping magazine has been placed on the vibration pay-off bed, the top of vibration pay-off bed is equipped with horizontal fortune material track, be equipped with first fortune workbin on the horizontal fortune material track, first discharge gate has been seted up on the first fortune workbin.

Furthermore, a plurality of vibration feeding units are arranged on the vibration feeding bed, the vibration feeding units are connected with a driving device, and the molding material boxes are placed on the vibration feeding units.

Furthermore, the vibration feeding unit is a roll shaft, the driving device is a first motor, the roll shafts are arranged on the at least two side supports, and at least one end of each roll shaft is connected with the first motor.

Further, two the side support level sets up and is parallel to each other, and is a plurality of the roller level sets up and perpendicular to the side support, be fixed with the bearing on the side support, the both ends of roller are fixed in the bearing, a plurality of the one end that the roller is located the homonymy with first motor is connected.

Further, a first moving chassis is arranged between the first material conveying box and the horizontal material conveying rail, a rotating shaft and a second motor are arranged on the first moving chassis, two ends of the rotating shaft are connected with the horizontal material conveying rail through rollers, and an output shaft of the second motor is connected with the rotating shaft.

Further, be connected with small-size agitating unit on the first discharge gate, small-size agitating unit's one end is equipped with the third motor, the second discharge gate has been seted up to small-size agitating unit's bottom, the shaping magazine is located the below of second discharge gate.

Furthermore, one side of the vibration feeding bed is provided with an oblique-pulling feeding support, an oblique-pulling feeding track is arranged on the oblique-pulling feeding support, and a second material conveying box is arranged on the oblique-pulling feeding track.

Furthermore, a second moving chassis is arranged between the second material conveying box and the oblique-pulling feeding rail, and the second moving chassis moves on the oblique-pulling feeding rail through rollers.

Furthermore, a turnover mechanism is arranged between the second material conveying box and the second movable chassis, and a turnover limiting stop lever is arranged on the oblique-pulling feeding support.

Furthermore, the top end of the oblique-pulling feeding rail is higher than the horizontal conveying rail, a winch is arranged on the oblique-pulling feeding support, a fourth motor is arranged on the winch, and the winch is connected with the second conveying box through a rope.

The technical scheme of the utility model through placing the shaping magazine on the vibration pay-off bed, can realize the shaping magazine when moving, vibrate simultaneously to the concrete in it, eliminate the bubble cavity of inside, make the mortar distribute more evenly, get rid of modes such as traditional artifical pouring, vibration, the effectual phenomenon such as segregation, bleeding that has avoided traditional concrete to directly unload to prefabricated box in-process from the transport vechicle, the prefab vibrates closely on the vibration pay-off bed, avoided artifical vibration inhomogeneous, leak vibration, lack the phenomenon of vibrating; in addition, the horizontal material conveying rail and the first material conveying box are arranged above the vibrating material conveying bed, so that the concrete vehicle can inject concrete into the forming material box through the first material conveying box, the concrete is not required to be manually shoveled and conveyed by constructors, manual operation is liberated, the labor intensity of operators is reduced, the production efficiency and the production quality of small prefabricated parts can be effectively improved, the workers can operate through simple operation training, high-quality products are produced, and quality problems and defects of engineering products caused by human factors are avoided.

Drawings

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

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

fig. 2 is a schematic view of embodiment 1 of the present invention;

fig. 3 is a schematic view of embodiment 2 of the present invention;

fig. 4 is a schematic view of embodiment 3 of the present invention;

fig. 5 is a schematic view of another perspective of fig. 1 according to the present invention;

fig. 6 is a schematic view of another perspective of fig. 1 according to the present invention;

fig. 7 is a schematic view of another perspective of fig. 1 according to the present invention;

description of reference numerals:

1-vibration feeding bed, 2-roller shaft, 201-side support, 3-first motor, 4-forming material box, 5-horizontal material conveying track, 6-first material conveying box, 601-first material outlet, 7-small stirring device, 701-second material outlet, 8-third motor, 9-first moving chassis, 10-roller, 11-second motor, 12-diagonal material conveying support, 13-diagonal material conveying track, 14-second material conveying box, 15-second moving chassis, 16-turnover limiting stop lever, 17-winch, 18-fourth motor and 19-rope.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" 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, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise. Furthermore, the terms "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

As shown in fig. 2, fig. 1, and fig. 5-7:

the utility model provides a small-size component automated production all-in-one, including vibration pay-off bed 1, placed shaping magazine 4 on the vibration pay-off bed 1, the top of vibration pay-off bed 1 is equipped with horizontal fortune material track 5, is equipped with first fortune material case 6 on the horizontal fortune material track 5, has seted up first discharge gate 601 on the first fortune material case 6.

Specifically, the vibration feeding bed 1 is a mechanical conveying device which moves forwards and slightly vibrates a conveying object placed on the vibration feeding bed; the molding material boxes 4 are mold material boxes for casting prefabricated parts and are arranged on the vibrating material conveying bed 1 in a row, the horizontal material conveying rail 5 comprises two guide rails, the first material conveying box 6 can move along the horizontal material conveying rail 5, the first material conveying box 6 is funnel-shaped, concrete enters from an inlet at the upper end and is discharged from a first material outlet 601 at the lower end, when the first material conveying box 6 moves along the horizontal material conveying rail 5, the concrete falling from the first material outlet 601 enters a plurality of molding material boxes 4 below and gradually moves on the vibrating material conveying bed 1 along with the molding material boxes 4, a forklift can be arranged in the advancing direction of the molding material boxes 4, and when the molding material boxes 4 move to the forefront, the molding material boxes enter a collecting device of the forklift and are conveyed to the airing position by the forklift; it should be noted that a plurality of vibrating material feeding beds 1 may be arranged side by side, that is, after the first material conveying box 6 passes through the range of the vibrating material feeding bed 1A, the material feeding bed enters the vibrating material feeding bed 1B instead of stopping, when the first material conveying box 6 fills the forming material box 4 on the next (or several) vibrating material feeding bed 1, the forklift transfers the forming material box 4 on the vibrating material feeding bed 1A away and puts a new forming material box 4 on the forming material feeding bed, and after the first material conveying box 6 finishes filling the vibrating material feeding bed 1B and returns to the vibrating material feeding bed 1A, the steps are continuously carried out on the vibrating material feeding bed 1B, even if the first material conveying box 6 is kept running all the time, and the production efficiency is improved.

The vibration feeding bed 1 is provided with a plurality of vibration feeding units, the vibration feeding units are connected with a driving device, and the molding material boxes 4 are placed on the vibration feeding units.

Specifically, for example, the vibration feeding unit is a conveyor belt, the driving device is a motor, and a vibration table is disposed below the conveyor belt to realize vibration movement, or the vibration feeding unit is a long rod-shaped cam, the driving device is a cylinder, and the continuous rotation of the long rod-shaped cam is driven by a link mechanism to realize vibration movement, and other modes of vibration transmission can be realized.

The vibration feeding unit is a roller shaft 2, the driving device is a first motor 3, the plurality of roller shafts 2 are arranged on the at least two side supports 201, and at least one end of each roller shaft 2 is connected with the first motor 3.

Specifically, a more detailed scheme is provided, the roll shaft 2 can be a hollow or solid rod, or can be formed by sleeving an outer cylinder outside a long shaft, it should be understood that the outer edge of the cross section of the roll shaft 2 is not limited to a smooth circle, in order to further enhance the vibration effect, the outer edge of the cross section of the roll shaft 2 can be a polygon, the number of the sides of the polygon can be set according to the vibration amplitude required by the forming material box 4, in a manner similar to a circle cutting method, the vibration amplitude can be smaller by continuously increasing the number of the sides of the polygon, and certainly, as the tops of two adjacent roll shafts 2 have inevitable gaps, the roll shaft 2 with the circular cross section can vibrate the forming material box 4; the side supports 201 are supports for supporting or fixing two ends of the roll shaft 2, and provide a certain height for the roll shaft 2, meanwhile, in order to make the roll shaft 2 rotate more smoothly, bearings can be arranged on the side supports 201 to fix the roll shaft 2, and when the number of the side supports 201 is more than two, namely, along the length scheme of the roll shaft 2, a plurality of side supports 201 are arranged to provide support for the middle part of the roll shaft 2, so as to prevent the roll shaft 2 from being broken; the first motor 3 can realize the mechanized rotation of the roll shafts 2, so that labor is saved, specifically, one end of each roll shaft 2, which is positioned on the same side support 201, is connected with the first motor 3, so that only one first motor 3 is needed, and only one end of each roll shaft 2 is connected with one end of each roll shaft 2 through a belt or a chain, or one first motor 3 is respectively arranged near each of the two side supports 201, so that any one end or two ends of each roll shaft 2 are all connected with the first motor 3, but at least one end of each roll shaft 2 is connected with the first motor 3, so that the rotating effectiveness of the roll shaft is ensured;

two side support 201 horizontal settings and parallel to each other, a plurality of 2 horizontal settings of roller and perpendicular to side support 201 are fixed with the bearing on the side support 201, and the both ends of roller 2 are fixed in the bearing, and the one end that a plurality of roller 2 are located the homonymy is connected with first motor 3.

Specifically, each roll shaft 2 is made to be equal in length, the side supports 201 at the two ends of each roll shaft 2 are parallel, when the side supports 201 are horizontally arranged, the movable panel formed by all the roll shafts 2 is also horizontal, the forming material box 4 moves forwards at a constant speed by vibration with the same amplitude, so that all quality parameters of the formed prefabricated member are basically uniform, and all the prefabricated members can reach the qualified standard by adjustment; the side bracket 201 can be I-shaped steel or U-shaped steel, so that the bearing is fixed in the groove, the advantage is that the condition that the splashed concrete enters the bearing to cause poor operation is avoided, two ends of the roll shaft 2 are inserted into the bearing to rotate, one end of the roll shaft extends out of the bearing to be connected with the first motor 3, thus only one first motor 3 is needed, all the roll shafts 2 can be driven to rotate, and the connection mode is various, as long as the first motor 3 can successfully drive the roll shafts 2 to rotate, for example, a fluted disc is arranged at the end part of the roll shaft 2 extending out of the bearing and is connected with a rotating shaft of the first motor 3 through a chain, or the fluted disc is replaced by a belt pulley and is connected with the rotating shaft of the first motor 3 through the belt pulley, or the fluted disc is replaced by a gear, the transmission direction is changed by arranging one or two intermediate gears between two adjacent gears, so that the gears are connected through a gear set.

Be equipped with first removal chassis 9 between first fortune workbin 6 and the horizontal fortune material track 5, be equipped with pivot and second motor 11 on the first removal chassis 9, the both ends of pivot are passed through gyro wheel 10 and are connected with horizontal fortune material track 5, and the output shaft and the pivot of second motor 11 are connected.

Specifically, the moving mode of the first material transporting box 6 on the horizontal material transporting track 5 is realized by a first moving chassis 9, the first moving chassis 9 is a square flat frame body, a rotating shaft is inserted in the first moving chassis 9 or at the bottom end of the first moving chassis, the rotating shaft extends out of the first moving chassis 9 in a direction perpendicular to the length direction of the horizontal material transporting track 5, rollers 10 are sleeved at two ends of the extending rotating shaft, the rollers 10 are arranged on the first material transporting track (as long as the rollers 10 can roll and advance on the track, for example, the horizontal material transporting track 5 is composed of two i-shaped steels, a groove is perpendicular to a vertical plane, the rollers 10 can be arranged in the groove), the rollers 10 are non-rotatably connected with the rotating shaft, that is, when the rotating shaft rotates, the rollers 10 can be driven to roll, so as to drive the moving frame and further drive the first material transporting box 6 to move, and the rotating shaft rotates through a second motor 11, the second motor 11 may be disposed at the bottom end or the side end of the first moving chassis 9 (it is sufficient not to affect the first material box 6), and it should be understood here that the rotating shaft should be distributed at the front end or the rear end of the first moving chassis 9 as a driving shaft, and the other end adopts a form of a fixed shaft plus a roller 10 as a driven shaft, for example, the second motor 11 drives the rotating shaft at the front end to rotate, and then drives the roller 10 at the front end to rotate as a driving wheel, and the combination of the fixed shaft at the rear end and the roller 10 is only driven, of course, the front end and the rear end can be connected to the second motor 11, and then the first moving chassis 9 is driven in a dual-drive manner.

The concrete use of this embodiment 1 does, the concrete car pours the concrete into to first fortune workbin 6, second motor 11 drives first fortune workbin 6 and removes on horizontal fortune material track 5, pour the concrete into shaping magazine 4, make first motor 3 drive roller 2 rotate, then shaping magazine 4 moves forward and vibrates on roller 2, finally get into fork truck's collection device, eliminate bubble and cavity in the concrete at this in-process, each quality parameter of the prefab of shaping like this is basic unified, improve the quality of prefab.

Example 2

As shown in fig. 3, fig. 1, and fig. 5-7:

this example 2 is an improved scheme based on the example 1.

The first discharging port 601 is connected with a small stirring device 7, one end of the small stirring device 7 is provided with a third motor 8, the bottom of the small stirring device 7 is provided with a second discharging port 701, and the molding material box 4 is positioned below the second discharging port 701.

Specifically, small-size agitating unit 7 can carry out the remixing to the concrete that comes out from first discharge gate 601, make the concrete keep the best state before getting into shaping magazine 4, small-size agitating unit 7 specifically is the agitator tank, stir through the inside baffle that sets up the spiral and encircle, transportation process, basic level or be installing in first freight box 6 bottom at slight inclination, small-size agitating unit 7's entry and first discharge gate 601 switch-on, the third motor 8 that one end is connected can drive inside spiral and encircle the baffle and constantly rotate, second discharge gate 701 is seted up to the lower part of one end in addition, discharge the concrete after will stirring from second discharge gate 701 and get into shaping magazine 4.

The concrete use of this embodiment 2 does, and the concrete car pours into the concrete in to first workbin 6, and when first workbin 6 moved on the horizontal migration guide rail, small-size agitating unit 7 stirred the concrete that first discharge gate 601 left, then flowed out from second discharge gate 701 and got into shaping magazine 4, and shaping magazine 4 advances and vibrates on roller 2, finally gets into in the fork truck collection device.

Example 3

As shown in fig. 4, fig. 1, and fig. 5-7:

this example 3 is an improved scheme based on example 1.

One side of the roll shaft 2 is provided with an oblique-pulling feeding support 12, an oblique-pulling feeding track 13 is arranged on the oblique-pulling feeding support 12, and a second material conveying box 14 is arranged on the oblique-pulling feeding track 13.

Specifically, on one hand, the first material conveying box 6 is arranged above the forming material box 4, concrete in the concrete car can splash onto the roller shaft 2 when being poured, and the operation of the equipment can be influenced after solidification, on the other hand, the first material conveying box 6 has a certain height, and the discharge port of the concrete car cannot reach the height, so that the inclined-pull feeding support 12 is arranged, when the inclined-pull feeding support is used, the first material conveying box 6 is moved to a position closest to the inclined-pull feeding rail 13, the second material conveying box 14 is positioned at the lowest position of the inclined-pull feeding rail 13, the concrete car pours the concrete into the inclined-pull feeding rail 13, the second material conveying box 14 moves upwards along the inclined-pull feeding rail 13, when the inclined-pull feeding support is moved to the position above the first material conveying box 6, the concrete poured downwards (the second material conveying box 14 is turned over or the bottom discharge port is arranged) enters the first material conveying box 6, and then the concrete is moved by the first material conveying box 6 and poured into the forming material box 4; the oblique-pulling loading support 12 is specifically a right-angled triangle support, one right-angled side is horizontally laid on the ground, the other right-angled side is perpendicular to and connected with the horizontal material conveying track 5, namely the top end of the oblique side is close to the roller shaft 2, and the bottom end of the oblique side is far away from the roller shaft 2, and the second material conveying box 14 is in the ascending direction along the oblique-pulling loading track 13 and is also in the direction of continuously approaching the first material conveying box 6; the moving track line of the second material box 14 and the moving track line of the first material box 6 may be in the same plane, or may be in two planes with an included angle, respectively, that is, preferably, the projections of the diagonal feeding rail 13 and the horizontal material conveying rail 5 on the horizontal plane are the same straight line, but other solutions are not excluded as long as the concrete in the second material box 14 can be finally poured into the first material box 6.

A second moving chassis 14 is arranged between the second material conveying box 14 and the oblique-pulling feeding rail 13, and the second moving chassis 14 moves on the oblique-pulling feeding rail 13 through the rollers 10.

Specifically, the second material conveying box 14 moves on the oblique-pulling feeding rail 13 through the second moving chassis 14, the second moving chassis 14 is a square frame formed by four square steels, rollers 10 are arranged at the bottom ends of two sides of the square frame, the second material conveying box 14 is fixed inside the square frame, the movement on the oblique-pulling feeding rail 13 is realized through the rolling of the rollers 10,

a turnover mechanism is arranged between the second material conveying box 14 and the second movable chassis 14, and a turnover limiting stop lever 16 is arranged on the diagonal drawing feeding support 12.

Specifically, one side surface of the second material box 14 is an inclined surface, and the top end surface is horizontal (the included angle between the inclined surface and the top horizontal surface is an acute angle), the second material box 14 is fixed on the second movable bottom plate through the inclined surface, and the top end of the second material box 14 is also horizontal because the second movable bottom plate is necessarily inclined to the horizontal surface; the turnover mechanism is various in selection, such as an air cylinder, a hydraulic rod, turnover by using the self weight of concrete, and the like, the hydraulic rod is taken as an example, a hydraulic pump is fixed on the diagonal-pulling feeding support 12, two hydraulic rods connected with the hydraulic pump are arranged on two sides of the second movable bottom plate and the second conveying box 14, the fixed part and the telescopic part of the hydraulic rod are respectively and fixedly connected with the second movable bottom plate and the second conveying box 14, when the second conveying box 14 is moved to a position, the telescopic part of the hydraulic rod pops out, the top end of the second conveying box 14 turns downwards, the concrete falls down, after the concrete is poured out, the telescopic part is retracted, and the top end of the second conveying box 14 returns to a horizontal position; the tip-stop bar 16 is intended to prevent the second container 14 from being turned too far, but it can also be used to prevent the tip-stop function of the tip-stop mechanism itself from becoming ineffective.

The top end of the oblique-pulling feeding rail 13 is higher than the horizontal conveying rail 5, the oblique-pulling feeding support 12 is provided with a winch 17, the winch 17 is provided with a fourth motor 18, and the winch 17 is connected with the second conveying box 14 through a rope 19.

In particular, since the inclined feeding rails 13 have an inclination angle, the driving manner cannot be the same as that of the first moving chassis 9, where we set the winding machine 17 to help the second material conveying box 14 move on the inclined feeding rails 13, and use the fourth motor 18 to provide the driving force, for example, in a manner that the winding machine 17 is fixed on the top end of the inclined feeding bracket 12, the steel cable on the steel cable is directly connected with the second material conveying box 14 or the second movable bottom plate, the second material conveying box 14 is pulled to ascend or descend, and in the other mode, the position of the winch 17 is not required, a fixed pulley is fixed at the top end of the diagonal drawing feeding bracket 12, so that a steel cable of a winch 17 passes through the fixed pulley to be connected with a second material conveying box 14 or a second movable bottom plate, the advantage of this is that the wire is parallel to the second feeding track, i.e. the tension of the hoist 17 does not have to do any useful work in other directions.

The concrete using process of this embodiment 3 is that the concrete truck pours the concrete into the second material transporting box 14, the winch 17 pulls the second material transporting box 14 to ascend along the oblique-pulling feeding rail 13, and after the concrete arrives above the first material transporting box 6, the turnover mechanism pushes the second material transporting box 14 to turn over to pour the concrete into the first material transporting box 6, then the first material transporting box 6 performs the operation of embodiment 1, and the second material transporting box 14 is controlled by the winch 17 to return to the bottom end of the oblique-pulling feeding rail 13.

The utility model discloses an overall scheme is by concrete roll-on-load car material loading, can all kinds of little prefab of full-automatic production, has to draw material loading, the flat rail ejection of compact, vibration forming, magazine roller to push away, fork truck changes the integration operation method that shines, is applicable to the high efficiency production of small-size prefabricated component such as curb, ditch apron, prefabricated stage cap of road bridge, high speed, airport.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. The utility model provides a small-size component automated production all-in-one, its characterized in that, includes vibration pay-off bed, the shaping magazine has been placed on the vibration pay-off bed, the top of vibration pay-off bed is equipped with horizontal fortune material track, be equipped with first fortune material case on the horizontal fortune material track, first discharge gate has been seted up on the first fortune material case.

2. The small-sized component automatic production all-in-one machine as claimed in claim 1, wherein a plurality of vibration feeding units are arranged on the vibration feeding bed, the vibration feeding units are connected with a driving device, and the molding material boxes are placed on the plurality of vibration feeding units.

3. The small-sized component automatic production all-in-one machine as claimed in claim 2, wherein the vibration feeding unit is a roller shaft, the driving device is a first motor, a plurality of roller shafts are arranged on at least two side supports, and at least one end of each roller shaft is connected with the first motor.

4. The small-sized component automatic production all-in-one machine according to claim 3, wherein the two side supports are horizontally arranged and parallel to each other, the plurality of roller shafts are horizontally arranged and perpendicular to the side supports, bearings are fixed on the side supports, two ends of the roller shafts are fixed in the bearings, and one ends of the plurality of roller shafts located on the same side are connected with the first motor.

5. The automatic small component production all-in-one machine as claimed in claim 1, wherein a first moving chassis is arranged between the first material conveying box and the horizontal material conveying rail, a rotating shaft and a second motor are arranged on the first moving chassis, two ends of the rotating shaft are connected with the horizontal material conveying rail through rollers, and an output shaft of the second motor is connected with the rotating shaft.

6. The integrated machine for automatically producing the small components according to claim 1, wherein a small stirring device is connected to the first discharging port, a third motor is arranged at one end of the small stirring device, a second discharging port is formed in the bottom of the small stirring device, and the molding material box is located below the second discharging port.

7. The automatic small-sized component production integrated machine according to claim 1, wherein a diagonal feeding support is arranged on one side of the vibration feeding bed, a diagonal feeding track is arranged on the diagonal feeding support, and a second conveying box is arranged on the diagonal feeding track.

8. The automatic small component production all-in-one machine as claimed in claim 7, wherein a second moving chassis is arranged between the second material conveying box and the oblique-pulling feeding rail, and the second moving chassis moves on the oblique-pulling feeding rail through rollers.

9. The automatic small component production all-in-one machine as claimed in claim 8, wherein a turnover mechanism is arranged between the second conveying box and the second moving chassis, and a turnover limiting stop lever is arranged on the diagonal drawing feeding support.

10. The automatic small-sized component production integrated machine according to claim 7, wherein the top end of the oblique-pulling feeding rail is higher than the horizontal material conveying rail, a winch is arranged on the oblique-pulling feeding support, a fourth motor is arranged on the winch, and the winch is connected with the second material conveying box through a rope.

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