CN113581844B - Hydraulic ore and mountain stone conveying all-in-one machine and conveying method - Google Patents

Abstract

The invention discloses a hydraulic type mine and mountain stone conveying integrated machine and a conveying method, and relates to the technical field of mine stone equipment. In this application, all-in-one is carried to fluid pressure type ore mountain stone includes: the organism sets up on the plane, and the organism includes: the conveying frame is arranged on a plane, and an inclined block is arranged at the left side end of the conveying frame; the processing frame is arranged on the right side of the conveying frame; the placing plate is arranged between the conveying frame and the processing frame; the supporting block is arranged above the processing frame; the discharge plates are arranged on the front side and the rear side of the supporting block; the protection plate is arranged inside the supporting block; the transfer device is arranged above the conveying frame; the clamping device is arranged on the left side of the transfer device; the fragment device is arranged on the right side of the supporting block. The stone rolling machine is used for solving the problems that in the prior art, large stones need to be carried by a large amount of manpower during stone rolling to cause manual damage, and meanwhile, the large stones cannot be completely crushed by directly rolling the stones to cause the stones to splash and be clamped in the stone rolling machine.

Description

Hydraulic mine and mountain stone conveying all-in-one machine and conveying method

Technical Field

The invention relates to the technical field of mine stone equipment, in particular to a hydraulic mine stone conveying all-in-one machine and a conveying method.

Background

Modern mining machinery is developing towards large-scale, continuous, automatic and machine-assembling, so that on one hand, the production efficiency is greatly improved, and on the other hand, huge challenges are brought to the management of the equipment.

The mining machinery mainly carries out operations such as conveying or crushing on large stones, coal blocks and the like, and the conventional stone rolling machine generally adopts a frame, a support, a descending block, a cushion seat, a metal crawler belt for conveying the stones, a motor and other parts, and utilizes potential energy of the ascending descending block to break stones.

Wherein, the middle part of the support post is provided with an insertion hole, and a bolt is arranged in the insertion hole; the upper part of the descending block is connected with a steel wire rope, the other end of the steel wire rope is connected with a ferrule, and the ferrule is sleeved on the bolt; the jack is a jack which is communicated from left to right, a boss is arranged at the right part of the plug pin, a pressure spring is arranged between the boss and the right side of the support, meanwhile, the left end of the plug pin is bent downwards or upwards to form a flat hook, a cam mechanism is fixed at the left side of the support, and a cam of the cam mechanism is matched with the flat hook.

The stone rolling machine that has now need artifically to put into the stone rolling machine with the stone when crushing the stone, but still can carry to the manual work of small-size stone, just needs a large amount of manual works to carry when meetting large-scale stone, and efficiency is extremely low, causes artifical damage easily. Meanwhile, when the stone rolling machine is used for crushing stones, the whole large stones are not suitable for directly rolling stones, and small stone differentiation is needed to improve the stone rolling efficiency.

Disclosure of Invention

The invention aims to provide a hydraulic type mine and mountain stone conveying all-in-one machine, which is used for solving the problems that large stones need to be carried by a large amount of manpower during stone rolling to cause manual damage in the prior art, and the stones cannot be completely crushed by directly rolling the large stones to cause the stones to splash and be clamped in a stone rolling machine.

In order to achieve the above purpose, the embodiments of the present application adopt the following technical solutions: an all-in-one is carried to fluid pressure type ore deposit hillstone includes: the organism, this organism setting is on the plane, and this organism includes: the conveying frame is arranged on a plane, the left side end of the conveying frame is provided with an inclined block, and the inclined block and the conveying frame form a triangle; the processing frame is arranged on the right side of the conveying frame, and a space is reserved between the processing frame and the conveying frame; the placing plate is arranged between the conveying frame and the processing frame and connects the conveying frame and the processing frame; the supporting block is arranged above the processing frame and is fixedly connected with the processing frame; the discharge plates are arranged on the front side and the rear side of the supporting block, the two discharge plates are fixedly connected with the supporting block, and the discharge plates are arranged in an inclined shape; the protection plate is arranged inside the supporting block and movably connected with the supporting block, and the protection plate is in a [ -shape; the transfer device is arranged above the conveying frame and is fixedly connected with the conveying frame; the clamping device is arranged on the left side of the transfer device, is movably connected with the transfer device and moves repeatedly along the extension direction of the transfer device; the fragment device is arranged on the right side of the supporting block and is fixedly connected with the supporting block.

In above-mentioned technical scheme, thereby this application is through clamping device, the transfer device, thereby the fragment device carries out the automatic handling to large-scale mine stone and reduces artifical handling cost, the problem that artifical damage can take place in the artifical handling process has been reduced simultaneously, can guarantee the stability of stone when carrying through clamping device, can not make the stone break away from the attack that causes the transfer device, carry high handling efficiency, can place automatically behind large-scale stone transport simultaneously and carry out the fragment below and carry out the convenient follow-up processing of fragment processing with large-scale stone and decompose into middle-size and small-size stone.

Further, in an embodiment of the present invention, the transfer device is provided with two sets of the transfer devices, the two sets of the transfer devices are disposed oppositely, and a space is left between the transfer devices, the transfer device includes: the transfer plate is arranged above the conveying frame and fixedly connected with the conveying frame; the rotating swing rod is arranged on the surface of one side of the transfer plate and is movably connected with the transfer plate; the transfer motor is arranged on the surface of the placing plate and fixedly connected with the placing plate; the rotating plate is arranged at the rotating end of the transfer motor, one end of the rotating plate is fixedly connected with the transfer motor, and the other end of the rotating plate is connected with the rotating swing rod; the adjusting block is arranged inside the rotating swing rod and is movably connected with the rotating swing rod.

Further, in the embodiment of the present invention, a through hole is formed on the surface of the rotating swing rod, the adjusting block slides in the through hole of the rotating swing rod, and the other end of the rotating plate is connected to the rotating swing rod through the adjusting block.

Further, in the embodiment of the present invention, the transfer plate is provided with a transfer rail on the surface thereof, and the transfer rail is provided with a V-shaped elongated circular groove through hole.

Further, in an embodiment of the present invention, the clamping device is provided with two sets, the clamping device includes: the rotating support plate is arranged on the left side of the transfer device, and one end of the rotating support plate is connected with the transfer plate of the transfer device; the clamping plate is arranged on the left side of the rotating support plate and is fixedly connected with the rotating support plate; the clamping motor is arranged above the rotating support plate and is fixedly connected with the side surface of the clamping plate; the matching plate is arranged inside the clamping plate, the matching plate is positioned below the clamping motor, one end surface of the matching plate is connected with one end of the clamping motor, and the matching plate moves up and down along the extending direction of the clamping plate; the fixed base is arranged on the surface of the matching plate, is opposite to the clamping motor, and is provided with a groove in the middle, and the groove of the fixed base is matched with the moving end of the clamping motor; the connecting block is arranged on the upper surface of the fixed base and is movably connected with the fixed base; the clamping plate is arranged on one side of the connecting block, and one end of the clamping plate is movably connected with one end of the connecting block; the air block is arranged at the bottom of the clamping plate and fixedly connected with the clamping plate; a penetrating needle disposed within the interior of the air block.

Further, in the embodiment of the present invention, the clamping plate is provided in an L-shape, the mating plate is provided inside the long side of the clamping plate, the air block is provided above the short side of the clamping plate, and one end surface of the air block is flush with the long side surface of the clamping plate;

one end of the rotating support plate is provided with a rotating shaft.

Further, in the embodiment of the present invention, the moving end of the clamping motor is fastened inside by the clamping plate, and the clamping motor is fixedly connected to the mating plate by the bolt after the clamping plate is fastened inside the moving end of the clamping motor.

Further, in an embodiment of the invention, the crumb device includes: the mounting plate is arranged on the side surface of the supporting block and fixedly connected with the supporting block; the controller is arranged on the right side surface of the mounting plate and is fixedly connected with the mounting plate; the positioning motor is arranged below the controller and is connected with the controller in a matching way; the mounting block is arranged on the left side of the controller and is connected with the controller in a matching way; the crushing knife is arranged inside the mounting block and is fixedly connected with the mounting block; the positioning plate is arranged between the controller and the positioning motor, and the telescopic end of the positioning motor is fixedly connected with the positioning plate.

Further, in the embodiment of the present invention, the mounting block is angularly swung by the controller; the crushing cutter is a percussion drill bit.

Further, in the embodiment of the present invention, the positioning motor controls the distance between the controller, the mounting block, the crushing knife and the stone block.

The embodiment of the invention also discloses a conveying method of the hydraulic mine stone conveying all-in-one machine, which comprises the following steps:

placing a stone block on the left side of the clamping device, wherein the stone block is positioned on the surface of the short side of the clamping plate, then pushing the matching plate to be downwards attached to the upper surface of the stone block through the clamping motor, fixedly clamping the stone block through the matching plate and the clamping plate, simultaneously starting the air block after the clamping of the stone block is finished, pushing the penetrating needle inside through the air block, and driving the penetrating needle into the stone block to form double-layer fixation with the clamping plate and the matching plate;

after the stone blocks are clamped, the transfer motor is started, the rotating plate rotates to drive the adjusting block to slide in the rotating swing rod, so that the rotating swing rod rotates in a fan shape, the rotating swing rod rotates to drive the rotating supporting plate to rotate, so that the integral clamping device and the stone blocks are lifted and rotated, after the clamping device and the stone blocks rotate to the other direction, the clamping device releases the fixation on the stone blocks, the penetrating needles are withdrawn at the same time, and the stone blocks fall to the upper surface of the supporting block;

after the stone falls to the upper surface of supporting shoe, the guard plate rises through jacking device and surrounds the stone, then the fragment device carries out the breakage to the stone and divide into middle-size and small-size rubble with the stone, and the stone decomposes the back of accomplishing, and the swing board rises through elevator motor control lift axle and carries out the rotation to one side, and the middle-size and small-size rubble on the rotatory in-process surface of swing board is to going out the flitch sliding charge, unloads.

The invention has the beneficial effects that: firstly, the hydraulic type mine and mountain stone conveying all-in-one machine carries out automatic conveying on large mine stones, manual conveying is not needed, the problem that manual damage is easily caused when the weight of the large stones is too high in the manual conveying process is solved, meanwhile, the large stones are inconvenient to roll effectively in the stone rolling process, automatic large stone conveying is carried out through the clamping device, the transfer device and the fragment device, meanwhile, the large stones can be automatically placed below the fragment device after conveying to decompose the large stones into small and medium-sized fragments, after the small and medium-sized fragments are formed, automatic stone conveying can be carried out through the discharging device, the small and medium-sized stones are placed below the fragment device to be deposited to cause blocking, the discharging device can carry out discharging in two opposite directions, and the phenomenon that discharging efficiency is influenced by too much stones discharged in the discharging direction due to discharging in the same direction can be reduced.

Drawings

The present application is further described below with reference to the drawings and examples.

Fig. 1 is a front view of a hydraulic mine and mountain stone conveying integrated machine according to an embodiment of the invention.

Fig. 2 is a top view of a hydraulic mine and mountain stone conveying integrated machine according to an embodiment of the invention.

Fig. 3 is a perspective view of a hydraulic mine and mountain stone conveying integrated machine according to an embodiment of the invention.

Fig. 4 is a schematic view of a clamping device of the hydraulic mine and mountain stone conveying integrated machine according to the embodiment of the invention.

Fig. 5 is another schematic view of the clamping device of the hydraulic mine and mountain stone conveying integrated machine according to the embodiment of the invention.

Fig. 6 is a schematic view of the combination of a clamping device and a transfer device of the hydraulic ore and mountain stone conveying integrated machine according to the embodiment of the invention.

Fig. 7 is a schematic diagram of the clamping device of the hydraulic ore and mountain stone conveying all-in-one machine of the embodiment of the invention moving under the driving of the transfer device.

Fig. 8 is a schematic motion diagram of a discharging device of a hydraulic type mine and mountain stone conveying all-in-one machine according to the embodiment of the invention.

FIG. 9 is a schematic view of the interior of a discharging device of a hydraulic type mine and mountain stone conveying all-in-one machine in motion according to the embodiment of the invention.

Fig. 10 is a schematic view of the working process of the hydraulic mine and mountain stone conveying integrated machine according to the embodiment of the invention.

10. Machine body 101, conveying frame 102, and processing frame

103. Placing plate 104, discharging plate 105 and supporting block

106. Protective plate

20. Clamping device 201, clamping plate 202 and clamping motor

203. Matching plate 204, rotary supporting plate 205 and fixed base

206. Connecting block 207, clamping plate 208 and bolt

209. Air block 2010, piercing needle

30. Transfer device 301, transfer plate 3011, and transfer rail

302. Rotating swing rod 303, transfer motor 304 and rotating plate

305. Regulating block

40. Crumb device 401, controller 402, mounting plate

403. Positioning motor 404, mounting block 405 and crushing knife

406. Position adjusting plate

50. Discharging device 501, swinging plate 5011 and rotating shaft

502. Lifting motor 503, lifting shaft 504 and bottom plate

60. Stone block 70, jacking device 701, jacking motor

702. Jacking plate

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clear and fully described, embodiments of the present invention will be further described in detail below with reference to the accompanying drawings. It is to be understood that the specific embodiments described herein are merely illustrative of some embodiments of the invention and are not limiting of the invention, and that all other embodiments obtained by those of ordinary skill in the art without the exercise of inventive faculty are within the scope of the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "inner", "outer", "top", "bottom", "side", "vertical", "horizontal", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "a," "an," "first," "second," "third," "fourth," "fifth," and "sixth" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; 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 meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

For the purposes of simplicity and explanation, the principles of the embodiments are described by referring mainly to examples. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the embodiments. It will be apparent, however, to one of ordinary skill in the art that the embodiments may be practiced without limitation to these specific details. In some instances, well-known methods and structures have not been described in detail so as not to unnecessarily obscure the embodiments. In addition, all embodiments may be used in combination with each other.

The first embodiment is as follows:

as shown in fig. 1, 2 and 3, the embodiment discloses a hydraulic type mine and mountain stone conveying all-in-one machine, which comprises: body 10, body 10 sets up on the plane, and body 10 includes: the conveying frame 101 is arranged on a plane, an inclined block is arranged at the left end of the conveying frame 101, and the inclined block and the conveying frame 101 form a triangle; the processing frame 102 is arranged on the right side of the conveying frame 101, and a space is reserved between the processing frame 102 and the conveying frame 101; a placement plate 103, the placement plate 103 being disposed between the conveyance rack 101 and the processing rack 102, the placement plate 103 connecting the conveyance rack 101 and the processing rack 102; the supporting block 105, the supporting block 105 is set up above the processing frame 102, the supporting block 105 is fixedly connected with processing frame 102; the discharging plates 104 are arranged on the front side and the rear side of the supporting block 105, the two discharging plates 104 are arranged, the discharging plates 104 are fixedly connected with the supporting block 105, and the discharging plates 104 are arranged in an inclined shape; the protection plate 106 is arranged inside the supporting block 105, the protection plate 106 is movably connected with the supporting block 105, and the protection plate 106 is in a [ -shape; the transfer device 30 is arranged above the conveying frame 101, and the transfer device 30 is fixedly connected with the conveying frame 101; the clamping device 20 is arranged on the left side of the transfer device 30, the clamping device 20 is movably connected with the transfer device 30, and the clamping device 20 moves repeatedly along the extending direction of the transfer device 30; the fragment device 40 is arranged on the right side of the supporting block 105, and the fragment device 40 is fixedly connected with the supporting block 105.

As shown in fig. 3, 6 and 7, the transfer devices 30 are provided in two sets, the two sets of transfer devices 30 are disposed opposite to each other, and a space is left between the transfer devices 30, and the transfer device 30 includes: the transfer plate 301, the transfer plate 301 is arranged above the conveying frame 101, and the transfer plate 301 is fixedly connected with the conveying frame 101; a rotating swing rod 302, wherein the rotating swing rod 302 is arranged on one side surface of the transfer plate 301, and the rotating swing rod 302 is movably connected with the transfer plate 301; a transfer motor 303, the transfer motor 303 is arranged on the surface of the placing plate 103, and the transfer motor 303 is fixedly connected with the placing plate 103; a rotating plate 304, wherein the rotating plate 304 is arranged at the rotating end of the transfer motor 303, one end of the rotating plate 304 is fixedly connected with the transfer motor 303, and the other end of the rotating plate 304 is connected with the rotating swing rod 302; the adjusting block 305 is arranged inside the rotating swing rod 302, and the adjusting block 305 is movably connected with the rotating swing rod 302.

A through hole is formed in the surface of the rotating swing rod 302, the adjusting block 305 slides in the through hole of the rotating swing rod 302, and the other end of the rotating plate 304 is connected with the rotating swing rod 302 through the adjusting block 305.

The transfer plate 301 has a transfer track 3011 on its surface, and the rotary track is provided with a V-shaped through hole having a long circular groove. Realize the automatic handling switching-over of large-scale stone 60 through transfer device 30, do not need the manual work to carry stone 60, improve handling efficiency to reduce artifical transport and cause injured probability.

As shown in fig. 3, 4 and 5, the holding device 20 is provided with two sets, and the holding device 20 includes: a rotary support plate 204, the rotary support plate 204 is arranged at the left side of the transfer device 30, and one end of the rotary support plate 204 is connected with the transfer plate 301 of the transfer device 30; the clamping plate 201 is arranged on the left side of the rotating support plate 204, and the clamping plate 201 is fixedly connected with the rotating support plate 204; the clamping motor 202, the clamping motor 202 is arranged above the rotating support plate 204, and the clamping motor 202 is fixedly connected with the side surface of the clamping plate 201; the matching plate 203, the matching plate 203 is arranged inside the clamping plate 201, the matching plate 203 is positioned below the clamping motor 202, one end surface of the matching plate 203 is connected with one end of the clamping motor 202, and the matching plate 203 moves up and down along the extending direction of the clamping plate 201; the fixed base 205, the fixed base 205 is set up on the surface of the mating plate 203, the fixed base 205 is opposite to holding the electrical machinery 202, leave the groove in the middle of the fixed base 205, the groove of the fixed base 205 matches with moving end to hold electrical machinery 202; the connecting block 206 is arranged on the upper surface of the fixed base 205, and the connecting block 206 is movably connected with the fixed base 205; the clamping plate 207 is arranged on one side of the connecting block 206, and one end of the clamping plate 207 is movably connected with one end of the connecting block 206; the gas block 209 is arranged at the bottom of the clamping plate 201, and the gas block 209 is fixedly connected with the clamping plate 201; a penetrating needle 2010, the penetrating needle 2010 disposed within the interior of the gas block 209.

The clamping plate 201 is L-shaped, the matching plate 203 is arranged inside the long side of the clamping plate 201, the air block 209 is arranged above the short side of the clamping plate 201, and one end surface of the air block 209 is flush with the long side surface of the clamping plate 201;

one end of the rotation support plate 204 is provided with a rotation shaft 5011.

The moving end of the clamping motor 202 is fastened inside by a clamping plate 207 and fixed, and the clamping motor 202 and the matching plate 203 are fixedly connected by bolts 208 after the clamping plate 207 is fastened inside the moving end of the clamping motor 202. Thereby carry out complete fixed centre gripping to large-scale stone 60 through clamping device 20 and prevent to break away from thereby taking place to drop at the surface of transfer device 30 and damaging transfer device 30 at the in-process of the rotatory switching-over of stone 60, fix the bottom of large-scale stone 60 through penetrating needle 2010 simultaneously, cooperate with grip block 201 and carry out dual protection, further guarantee the stability of stone 60 at the rotatory switching-over in-process.

As shown in FIG. 3, the fragment device 40 includes: the mounting plate 402 is arranged on the side surface of the supporting block 105, and the mounting plate 402 is fixedly connected with the supporting block 105; the controller 401 is arranged on the right side surface of the mounting plate 402, and the controller 401 is fixedly connected with the mounting plate 402; the positioning motor 403, the positioning motor 403 is arranged below the controller 401, and the positioning motor 403 is connected with the controller 401 in a matching manner; the mounting block 404 is arranged on the left side of the controller 401, and the mounting block 404 is connected with the controller 401 in a matched mode; the crushing knife 405 is arranged inside the mounting block 404, and the crushing knife 405 is fixedly connected with the mounting block 404; the positioning plate 406 is arranged between the controller 401 and the positioning motor 403, and the telescopic end of the positioning motor 403 is fixedly connected with the positioning plate 406.

The mounting block 404 is angularly swung by the controller 401; crushing knives 405 are percussion drill bits. Positioning motor 403 controls the spacing between controller 401, mounting block 404, crushing blade 405 and stone block 60. Large stone blocks 60 are decomposed into small and medium-sized stone blocks 60 through the fragment device 40, so that subsequent processing is facilitated, the splashing phenomenon of the stone blocks 60 generated in the decomposition process of the stone blocks 60 is reduced through the protection plate 106 in the decomposition process, personnel injuries are prevented, and damage to machines after the stone blocks 60 are splashed is also reduced. The splash-proof stone block 60 is prevented from jamming inside the machine.

Clamping device 20 is passed through in this application, transfer device 30, thereby fragment device 40 carries out automatic handling to large-scale mine stone 60 and reduces artifical handling cost, the problem that artifical damage can take place in the artifical handling process has been reduced simultaneously, can guarantee the stability of stone 60 when carrying through clamping device 20, can not make stone 60 break away from the attack that causes transfer device 30, improve handling efficiency, can place automatically after large-scale stone 60 carries simultaneously and carry out the fragment processing and carry out the convenient subsequent processing of fragment processing with large-scale stone 60 decomposition into middle-size and small-size stone 60 below fragment device 40.

Example two:

as in the first embodiment, as shown in fig. 8 and 9, the apparatus further includes a discharging device 50, the discharging device 50 is disposed inside the supporting block 105, the discharging device 50 is movably connected to the supporting block 105, the discharging device 50 includes: the swing plate 501 is arranged inside the supporting block 105, the upper surface of the swing plate 501 is flush with the upper surface of the supporting block 105, rotating shafts 5011 are arranged on the left side and the right side of the swing plate 501, the rotating shafts 5011 are movably connected with the supporting block 105, the rotating shafts 5011 rotate around the circle center inside the supporting block 105 when the swing plate 501 swings left and right, the rotating shaft 5011 on the other side is separated from the inside of the supporting block 105 when the rotating shaft 5011 on one side of the swing plate 501 rotates, and the stone block 60 on the upper surface of the supporting block 105 moves out towards the discharge plate 104; a base plate 504, the base plate 504 being disposed on the X-shaped mounting plate surface of the processing rack 102; the lifting motor 502 is arranged below the swinging plate 501, one end of the lifting motor 502 is movably connected with the bottom plate 504, and one end of the lifting motor 502 rotates around the center of the bottom plate 504; and an elevation shaft 503, the elevation shaft 503 being disposed inside the elevation motor 502, one end of the elevation shaft 503 being movably connected to a lower surface of the swing plate 501, the swing plate 501 simultaneously swinging left and right when the elevation shaft 503 moves along an extending direction of the elevation motor 502. Jacking device 70, jacking device 70 set up in discharging device 50's below, and jacking device 70 is connected with discharging device 50 cooperation, and jacking device 70 includes: the jacking motor 701, the jacking motor 701 is set up below the supporting shoe 105, the jacking motor 701 is fixedly connected with processing frame 102; the jacking plate 702 is arranged inside the supporting block 105, the jacking plate 702 is movably connected with the supporting block 105, the jacking plate 702 is positioned below the protection plate 106, the upper surface of the jacking plate 702 is attached to the lower surface of the protection plate 106, and the jacking plate 702 controls the protection plate 106 to lift when moving upwards. One end of the rotating swing link 302 is movably connected with the rotating shaft 5011 of the rotating support plate 204. Through discharging device 50 and jacking device 70 that set up, carry out automatic ejection of compact after large-scale stone 60 decomposes into middle-size and small-size stone 60, do not need the manual work to carry, also do not need the manual work to push out middle-size and small-size stone 60 through the device, thereby improve the whole smoothness nature of device, also avoided the manual work to cause middle-size and small-size stone 60 to stay in the processing of the follow-up large-size stone 60 of below influence of garrulous piece device 40 when can not in time push out middle-size and small-size stone 60, and, carry out the ejection of compact respectively of both sides with middle-size and small-size stone 60 through discharging device 50, thereby prevent to cause the jam of middle-size and small-size stone 60 to ejection of compact conveying line only at the prescription to the ejection of compact, thereby improve discharging efficiency.

Example three:

as shown in fig. 10, finally, a method for conveying a hydraulic mining stone conveying integrated machine is provided, which comprises the following steps:

placing stone block 60 on the left side of clamping device 20, positioning stone block 60 on the short side surface of clamping plate 201, then pushing matching plate 203 to fit the upper surface of stone block 60 downwards through clamping motor 202, fixing and clamping stone block 60 through matching plate 203 and clamping plate 201, starting air block 209 after clamping stone block 60 is completed, pushing penetrating needle 2010 inside through air block 209, and driving penetrating needle 2010 into the interior of stone block 60 to form double-layer fixation with clamping plate 201 and matching plate 203;

after the stone block 60 is clamped, the transfer motor 303 is started, the rotating plate 304 rotates to drive the adjusting block 305 to slide in the rotating swing rod 302, so that the rotating swing rod 302 rotates in a fan shape, the rotating support plate 204 is driven to rotate through the rotation of the rotating swing rod 302, so that the whole clamping device 20 and the stone block 60 are lifted and rotated, after the clamping device 20 and the stone block 60 rotate to the other direction, the clamping device 20 releases the fixation of the stone block 60 and the penetrating needle 2010 is retracted, and the stone block 60 falls to the upper surface of the support block 105;

after the stone blocks 60 fall to the upper surface of the supporting block 105, the protection plate 106 is lifted through the jacking device 70 to surround the stone blocks 60, then the fragment device 40 crushes the stone blocks 60 to divide the stone blocks 60 into small and medium-sized broken stones, after the stone blocks 60 are decomposed, the swinging plate 501 controls the lifting shaft 503 to ascend through the lifting motor 502 to rotate towards one side, and the small and medium-sized broken stones on the surface slide towards the discharging plate 104 in the rotating process of the swinging plate 501 to be discharged.

The hydraulic type mine stone conveying all-in-one machine automatically conveys large mine stones 60, manual conveying is not needed, the problem that manual damage easily occurs when the weight of the large stones 60 is too high in the manual conveying process is solved, meanwhile, the large stones 60 are inconvenient to roll effectively in the stone rolling process, automatic conveying of the large stones 60 is achieved through the clamping device 20, the transfer device 30 and the fragment device 40, meanwhile, the large stones 60 can be automatically placed below the fragment device 40 to decompose into small and medium fragments after conveying, after the small and medium fragments are formed, automatic conveying of the stones 60 can be achieved through the discharging device 50, the small and medium stones 60 can be placed below the fragment device 40 to be blocked, the discharging device 50 can conduct discharging in opposite directions, and the problem that discharging efficiency is affected by too much stones in the discharging direction due to discharging in the same direction can be reduced.

Although the illustrative embodiments of the present application have been described above to enable those skilled in the art to understand the present application, the present application is not limited to the scope of the embodiments, and various modifications within the spirit and scope of the present application defined and determined by the appended claims will be apparent to those skilled in the art from this disclosure.

Claims (6)

1. An all-in-one is carried to fluid pressure type ore deposit hillstone includes:

the organism, the organism sets up on the plane, the organism includes:

the conveying frame is arranged on a plane, an inclined block is arranged at the left side end of the conveying frame, and the inclined block and the conveying frame form a triangle;

the processing frame is arranged on the right side of the conveying frame, and a space is reserved between the processing frame and the conveying frame;

the placing plate is arranged between the conveying frame and the processing frame and connects the conveying frame and the processing frame;

the supporting block is arranged above the processing frame and is fixedly connected with the processing frame;

the discharge plates are arranged on the front side and the rear side of the supporting block, the two discharge plates are fixedly connected with the supporting block, and the discharge plates are arranged in an inclined shape;

the protection plate is arranged inside the supporting block, is movably connected with the supporting block and is in a [ -shape;

the transfer device is arranged above the conveying frame and is fixedly connected with the conveying frame;

the clamping device is arranged on the left side of the transfer device, is movably connected with the transfer device and moves repeatedly along the extension direction of the transfer device;

the fragment device is arranged on the right side of the supporting block and is fixedly connected with the supporting block;

the transfer device is provided with two sets ofly, and two sets of the transfer device is relative the setting, leave the interval between the transfer device, the transfer device includes:

the transfer plate is arranged above the conveying frame and is fixedly connected with the conveying frame;

the rotating swing rod is arranged on the surface of one side of the transfer plate and is movably connected with the transfer plate;

the transfer motor is arranged on the surface of the placing plate and fixedly connected with the placing plate;

the rotating plate is arranged at the rotating end of the transfer motor, one end of the rotating plate is fixedly connected with the transfer motor, and the other end of the rotating plate is connected with the rotating swing rod;

the adjusting block is arranged inside the rotating swing rod and is movably connected with the rotating swing rod;

a through hole is formed in the surface of the rotating swing rod, the adjusting block slides in the through hole of the rotating swing rod, and the other end of the rotating plate is connected with the rotating swing rod through the adjusting block;

the surface of the transfer plate is provided with a transfer track which is provided with a V-shaped strip circular groove through hole;

the clamping device is provided with two sets, clamping device includes:

the rotating support plate is arranged on the left side of the transfer device, and one end of the rotating support plate is connected with the transfer plate of the transfer device;

the clamping plate is arranged on the left side of the rotating support plate and is fixedly connected with the rotating support plate;

the clamping motor is arranged above the rotating support plate and is fixedly connected with the side surface of the clamping plate;

the matching plate is arranged inside the clamping plate, the matching plate is positioned below the clamping motor, one end surface of the matching plate is connected with one end of the clamping motor, and the matching plate moves up and down along the extension direction of the clamping plate;

the fixed base is arranged on the surface of the matching plate and is opposite to the clamping motor, a groove is reserved in the middle of the fixed base, and the groove of the fixed base is matched with the moving end of the clamping motor;

the connecting block is arranged on the upper surface of the fixed base and is movably connected with the fixed base;

the clamping plate is arranged on one side of the connecting block, and one end of the clamping plate is movably connected with one end of the connecting block;

the air block is arranged at the bottom of the clamping plate and fixedly connected with the clamping plate;

a penetrating needle disposed inside the air block.

2. The hydraulic ore and mountain stone conveying all-in-one machine as claimed in claim 1, wherein the clamping plate is L-shaped, the matching plate is arranged inside the long side of the clamping plate, the air block is arranged above the short side of the clamping plate, and one end surface of the air block is flush with the long side surface of the clamping plate;

one end of the rotary supporting plate is provided with a rotary shaft.

3. The hydraulic ore and mountain stone conveying all-in-one machine as claimed in claim 2, wherein the moving end of the clamping motor is fixed by the clamping plate being buckled inside, and the clamping motor is fixedly connected with the matching plate by bolts after the clamping plate is buckled inside the moving end of the clamping motor.

4. The hydraulic mine and hill stone conveyor integrated machine according to claim 1, wherein the fragmenting device comprises:

the mounting plate is arranged on the side surface of the supporting block and fixedly connected with the supporting block;

the controller is arranged on the right side surface of the mounting plate and fixedly connected with the mounting plate;

the positioning motor is arranged below the controller and is in matched connection with the controller;

the mounting block is arranged on the left side of the controller and is connected with the controller in a matched manner;

the crushing knife is arranged inside the mounting block and is fixedly connected with the mounting block;

the positioning plate is arranged between the controller and the positioning motor, and the telescopic end of the positioning motor is fixedly connected with the positioning plate.

5. The hydraulic mine and mountain stone conveying all-in-one machine as claimed in claim 4, wherein the mounting block is angularly oscillated by the controller;

the crushing cutter is a percussion bit.

6. The hydraulic mine and hill stone conveying all-in-one machine as claimed in claim 5, wherein the positioning motor controls the distance between the controller, the mounting block, the crushing knife and the stone block.

Images