CN112501995B - Landscape garden pavement paving machine - Google Patents

Abstract

The invention provides a landscape garden pavement paving machine which comprises a rack, a feeding unit and an execution unit, wherein the left view of the rack is of a concave structure, the middle part of the lower end of the rack is provided with a linkage hole, the feeding unit is arranged on the inner wall of the left side of the middle part of the lower end of the rack, and the execution unit is arranged on the inner wall of the linkage hole of the inner wall of the lower end of the rack; the invention can solve the problem that the general garden pavement can be paved by adopting a manual operation mode when being paved, and workers are easy to be tired when being paved for a long time; the workman will carry out when laying and get material, lay and strike a plurality of actions, and the manual work is laid and need lay one by one, consequently consumes the recruitment cost, lays inefficiency, extravagant laying man-hour scheduling problem.

Description

Landscape garden pavement paving machine

Technical Field

The invention relates to the technical field of landscape gardens, in particular to a landscape garden pavement paving machine.

Background

The importance of garden pavement to whole gardens is just as important as people's venation, link the tie of each scenic spot and sight spot, among the landscape engineering, the road is laid and is under construction for landscape engineering's important component, there is direct influence to the construction quality of whole landscape engineering, consequently when laying garden pavement, generally select the hexagonal brick for use, every concatenation department of hexagonal brick can hold 3 interior angles just, can realize not keeping the space, the perfect close laying of non-overlapping, and the hexagonal brick is different with ordinary four corner brick, belong to the deformed brick, so can give people a new sensation of an ear to a garden pavement laid by it.

However, the following problems exist when the road surface is paved on landscape gardens at present: when general garden pavements are paved, manual operation is adopted for paving, and workers are easy to fatigue after long-time paving; the workman will carry out when laying and get the material, lay and strike a plurality of actions, and the manual work is laid and need lay one by one, consequently consumes the recruitment cost, lays inefficiency, extravagant laying man-hour.

Disclosure of Invention

The technical problem to be solved

The landscape garden pavement paving machine provided by the invention can solve the problems pointed out in the background technology.

Two technical schemes

In order to achieve the above purpose, the invention adopts the following technical scheme that the landscape garden pavement paving machine comprises a rack, a feeding unit and an execution unit, wherein the left view of the rack is of a concave structure, the middle part of the lower end of the rack is provided with a linkage hole, the feeding unit is arranged on the inner wall of the left side of the middle part of the lower end of the rack, the execution unit is arranged on the inner wall of the linkage hole of the inner wall of the lower end of the rack, and the landscape garden pavement paving machine comprises:

the frame is including laying shell, driving motor, transmission shaft and removal roller, wherein: lay shell left view and be the spill structure, and lay shell lower extreme middle part and seted up the linkage hole, lay and seted up the linkage groove on the shell right-hand member inside wall, the connecting hole has been seted up along laying shell middle part right side front and back symmetry, and the transmission groove has been seted up along laying shell middle part right side connecting hole outside, lay the inside motor groove of having seted up of shell middle part right side lower extreme, transmission shaft bilateral symmetry is through the bearing setting on laying shell front and back end inner wall, and be connected through the belt drive between the transmission shaft, wherein, there is driving motor left side transmission shaft rear end through splined connection, and driving motor passes through the motor cabinet setting and on laying the shell outer wall, the symmetrical cover is established on the transmission shaft outer wall around the removal roller passes through the flange structure.

The feed unit includes two-way motor, pivot, driving sprocket, execution sprocket, drive chain, limiting plate, backup pad and interlocking round pin, wherein: two-way motor sets up in the motor inslot, there is the pivot along two-way motor longitudinal symmetry through splined connection, overlap through flange structure on the outer wall of the pivot other end and be equipped with drive sprocket, and drive sprocket slides and sets up in the drive groove, it sets up on the inner wall of drive groove upside to slide the execution sprocket through the universal driving shaft, drive sprocket and execution sprocket are connected through drive chain, the limiting plate setting is on laying shell middle part right side inner wall, set up the vertical spout with linkage groove matched with on the limiting plate right-hand member outer wall, the backup pad left end slides and sets up in vertical spout, the backup pad right-hand member slides and sets up in the linkage groove, linkage round pin longitudinal symmetry sets up on the backup pad outer wall, and linkage round pin sliding connection is in the connecting hole, the linkage round pin other end articulates on drive chain right side middle part outer wall.

The execution unit includes location cylinder, connecting rod, promotion cylinder, execution feeler lever, execution cylinder, bearing board, two-way cylinder, snatchs the pole and strikes the subassembly, wherein: location cylinder sets up on laying shell lower extreme middle part left side inner wall, location cylinder telescopic link end articulates there is the connecting rod, the connecting rod middle part is equipped with spacing post through the bearing housing, spacing post setting is on laying shell upside middle part front and back end inner wall, the promotion cylinder sets up on connecting rod middle part right side outer wall, the connecting rod right-hand member articulates there is the execution feeler lever, it is connected with the execution cylinder to execute the feeler lever lower extreme, execution cylinder telescopic link end-to-end connection has the bearing board, the fixed slot has evenly been seted up from the front to the back along bearing board inside, the lateral sliding hole has been seted up along fixed slot lower extreme bilateral symmetry, the two-way cylinder sets up in the fixed slot, two-way cylinder telescopic link end all is connected with the grabbing pole, and snatch pole sliding connection in the lateral sliding hole, the subassembly slides and sets up downtheholely in the linkage.

As a preferred technical solution of the present invention, the knocking assembly includes a transmission crankshaft and a knocking rod, wherein: the transmission crankshaft is arranged on the inner walls of the front end and the rear end of the laid shell through bearings, the rear end of the transmission crankshaft is connected with the transmission shaft on the right side through belt transmission, the upper side of the middle of the knocking rod is connected to the outer wall of the middle of the transmission crankshaft through the bearings, and the knocking rod is arranged in the linkage hole in a sliding mode.

According to the preferable technical scheme, the support plate is provided with guide blocks for guiding in a bilateral symmetry mode, the left guide block is connected in the longitudinal sliding groove in a sliding mode, the right guide block is arranged in the linkage groove in a sliding mode, and the support plate is provided with fixing clamping grooves for placing hexagonal bricks in a left-right staggered mode from front to back.

As a preferred technical scheme of the invention, the grabbing rod is a Z-shaped structural rod which is convenient for grabbing the hexagonal brick.

As a preferable technical solution of the present invention, the striking rod is a T-shaped structural rod for increasing a striking area.

As a preferred technical scheme of the invention, the fixing grooves are structural grooves which are matched with the fixing clamping grooves and are staggered from front to back.

Three beneficial effects

1. The invention greatly improves the paving of landscape garden pavements, and can solve the problems that the general landscape garden pavements can be paved by adopting a manual operation mode, and workers are easy to be tired when the landscape garden pavements are paved for a long time; the workman will carry out when laying and get material, lay and strike a plurality of actions, and the manual work is laid and need lay one by one, consequently consumes the recruitment cost, lays inefficiency, extravagant laying man-hour scheduling problem.

2. The hexagonal bricks can be placed in sequence and can be laid movably; the hexagonal bricks in the device can be conveyed upwards, so that the working hours required by laying are reduced; the hexagonal brick column can be synchronously paved, and the hexagonal bricks paved on the ground can be knocked, so that the labor cost is reduced, and the unnecessary workload is reduced.

3. The hexagonal brick feeding device is provided with the feeding unit, so that hexagonal bricks placed in the hexagonal brick feeding device can be conveyed upwards, the material taking of the execution unit is facilitated, and the laying working hours are reduced.

4. The hexagonal bricks in the device can be taken out in an aligned mode and laid synchronously by matching with the feeding unit, and after the laying is finished, the hexagonal bricks laid on the ground can be subjected to reciprocating type knocking treatment by the execution unit, so that the hexagonal bricks are prevented from being raised or dislocated, the hexagonal bricks laid are ensured to meet the requirements, and the laying efficiency is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a front sectional view of the present invention.

Fig. 3 is a sectional view taken along line a-a of fig. 2 of the present invention.

Fig. 4 is a sectional view taken along line B-B of fig. 2 of the present invention.

FIG. 5 is a cross-sectional view taken along line C-C of FIG. 2 of the present invention.

Fig. 6 is a schematic perspective view of the drive sprocket, drive chain and support plate of the present invention.

FIG. 7 is a top cross-sectional view of the support plate and linkage pin of the present invention.

Fig. 8 is a partial enlarged view of the invention at D of fig. 2.

Fig. 9 is a cross-sectional view taken along line E-E of fig. 2 of the present invention.

Figure 10 is a top cross-sectional view of the support plate of the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 10, landscape garden road paving machine, including frame 1, feeding unit 2 and execution unit 3, 1 left side view of frame is the spill structure, and 1 lower extreme middle part of frame has seted up linkage hole 111, and feeding unit 2 sets up on 1 lower extreme middle part of frame left side inner wall, and execution unit 3 sets up on 1 lower extreme inner wall linkage hole 111 department inner wall of frame, wherein:

the machine frame 1 comprises a laying shell 11, a driving motor 12, a transmission shaft 13 and a moving roller 14, wherein: the left view of the laying shell 11 is of a concave structure, the middle part of the lower end of the laying shell 11 is provided with a linkage hole 111, the inner side wall of the right end of the laying shell 11 is provided with a linkage groove 112, connection holes 113 are symmetrically formed in the front and back directions along the right side of the middle part of the laying shell 11, a transmission groove 114 is formed in the outer side of the connection hole 113 in the middle part of the laying shell 11, a motor groove 115 is formed in the inner part of the lower end of the right side of the middle part of the laying shell 11, the transmission shafts 13 are symmetrically arranged on the inner walls of the front and back ends of the laying shell 11 through bearings and are connected through belt transmission, wherein the rear end of the left transmission shaft 13 is connected with a driving motor 12 through a spline, the driving motor 12 is arranged on the outer wall of the laying shell 11 through a motor base, and the movable roller 14 is symmetrically sleeved on the outer wall of the transmission shaft 13 in the front and back direction through a flange structure; when the concrete work is carried out, the driving motor 12 is turned on, the driving motor 12 drives the moving roller 14 to rotate through the transmission shaft 13, and therefore the effect of moving and paving is achieved.

The feeding unit 2 comprises a bidirectional motor 21, a rotating shaft 22, a transmission chain wheel 23, an execution chain wheel 24, a transmission chain 25, a limiting plate 26, a supporting plate 27 and a linkage pin 28, wherein: the bidirectional motor 21 is arranged in the motor groove 115, a rotating shaft 22 is symmetrically connected with the front and the back of the bidirectional motor 21 through splines, a transmission chain wheel 23 is sleeved on the outer wall of the other end of the rotating shaft 22 through a flange structure, the transmission chain wheel 23 is arranged in the transmission groove 114 in a sliding manner, the execution chain wheel 24 is arranged on the inner wall of the upper side of the transmission groove 114 in a sliding manner through a linkage shaft 241, the transmission chain wheel 23 is connected with the execution chain wheel 24 through a transmission chain 25, the limiting plate 26 is arranged on the inner wall of the right side of the middle part of the laying shell 11, a longitudinal sliding groove 261 matched with the linkage groove 112 is arranged on the outer wall of the right end of the limiting plate 26, the left end of the supporting plate 27 is arranged in the longitudinal sliding groove 261 in a sliding manner, the supporting plate 27 is symmetrically provided with guide blocks 271 used for guiding in a bilateral manner, and the left guide block 271 is slidably connected in the longitudinal sliding slot 261, the right guide block 271 is slidably disposed in the linking slot 112, the supporting plate 27 is provided with fixing clamping grooves 272 for placing the hexagonal bricks in a left-right staggered manner from front to back; the right end of the supporting plate 27 is slidably arranged in the linkage groove 112, the linkage pins 28 are symmetrically arranged on the outer wall of the supporting plate 27 in a front-back manner, the linkage pins 28 are slidably connected in the connecting holes 113, and the other ends of the linkage pins 28 are hinged on the outer wall of the middle part of the right side of the transmission chain 25.

During specific work, the hexagonal brick is placed in fixed slot 272, opens two-way motor 21, and two-way motor 21 drives drive sprocket 23 through pivot 22 and rotates, and drive sprocket 23 cooperates execution sprocket 24 to drive chain 25 and carry out circumferential motion to cooperation connecting hole 113 drives linkage pin 28 and carries out upward movement, and linkage pin 28 drives backup pad 27 upward movement, thereby upwards carries the hexagonal brick, so that execution unit 3 snatchs.

The execution unit 3 comprises a positioning cylinder 31, a connecting rod 32, a pushing cylinder 33, an execution contact rod 34, an execution cylinder 35, a bearing plate 36, a bidirectional cylinder 37, a grabbing rod 38 and a knocking component 39, wherein: the positioning cylinder 31 is arranged on the inner wall of the left side of the middle part of the lower end of the laying shell 11, the tail end of a telescopic rod of the positioning cylinder 31 is hinged with a connecting rod 32, the middle part of the connecting rod 32 is sleeved with a limiting column 321 through a bearing, the limiting column 321 is arranged on the inner walls of the front and rear ends of the middle part of the upper side of the laying shell 11, the pushing cylinder 33 is arranged on the outer wall of the right side of the middle part of the connecting rod 32, the right end of the connecting rod 32 is hinged with an execution contact rod 34, the lower end of the execution contact rod 34 is connected with an execution cylinder 35, the tail end of a telescopic rod of the execution cylinder 35 is connected with a bearing plate 36, fixing grooves 361 are uniformly formed in the bearing plate 36 from front to back, transverse sliding holes 362 are symmetrically formed in the left and right direction along the lower end of the fixing grooves 361, the bidirectional cylinder 37 is arranged in the fixing grooves 361 matched with the fixing clamping grooves 272 in a staggered mode from front to back; the tail ends of the telescopic rods of the bidirectional cylinders 37 are connected with grabbing rods 38, the grabbing rods 38 are connected in the transverse sliding holes 362 in a sliding mode, and the grabbing rods 38 are Z-shaped structural rods facilitating grabbing of the hexagonal bricks; the knocking component 39 is arranged in the linkage hole 111 in a sliding mode; the rapping assembly 39 comprises a drive crankshaft 391 and a rapping rod 392, wherein: the transmission crankshaft 391 is arranged on the inner walls of the front end and the rear end of the laying shell 11 through bearings, the rear end of the transmission crankshaft 391 is connected with the transmission shaft 13 on the right side through belt transmission, the upper side of the middle part of the knocking rod 392 is connected to the outer wall of the middle part of the transmission crankshaft 391 through bearings, the knocking rod 392 is arranged in the linkage hole 111 in a sliding mode, and the knocking rod 392 is a T-shaped structure rod used for increasing knocking area.

During specific work, the positioning cylinder 31 is opened, and the positioning cylinder 31 is matched with the limiting column 321 to drive the connecting rod 32 to rotate anticlockwise; the pushing cylinder 33 is opened, and the pushing cylinder 33 drives the execution contact rod 34 to move leftwards; opening the execution cylinder 35, and driving the bearing plate 36 to move upwards by the execution cylinder 35, so that the bearing plate 36 moves to the upper right side of the laying shell 11 to grab the hexagonal bricks; at the moment, the execution cylinder 35 pushes the supporting plate 36 to move downwards, when the grabbing rod 38 abuts against the hexagonal brick, the bidirectional cylinder 37 is opened, the bidirectional cylinder 37 drives the grabbing rod 38 to move inwards, and therefore the grabbing rod 38 grabs the hexagonal brick in the fixing clamping groove 272; at the moment, the execution cylinder 35 drives the bearing plate 36 to move upwards to the upper part of the right side, the pushing cylinder 33 drives the execution contact rod 34 to move rightwards, the positioning cylinder 31 cooperates with the limiting post 321 to drive the connecting rod 32 to rotate clockwise, so that the hexagonal brick is moved to the laying position, and the bidirectional cylinder 37 drives the grabbing rod 38 to move outwards, so that the hexagonal brick is placed at the laying position; at this time, the driving crankshaft 391 drives the knocking rod 392 to reciprocate up and down under the action of the driving shaft 13, so as to knock the hexagonal brick laid on the ground, thereby preventing the hexagonal brick from being warped or dislocated.

During operation

The first step is as follows: the hex tiles are stacked in the fixture slots 272 of the device.

The second step is that: the driving motor 12 is turned on, and the driving motor 12 drives the moving roller 14 to rotate clockwise through the transmission shaft 13, so that the effect of moving and paving is achieved.

The third step: the bidirectional motor 21 is started, the bidirectional motor 21 drives the transmission chain wheel 23 to rotate through the rotating shaft 22, the transmission chain wheel 23 is matched with the execution chain wheel 24 to drive the transmission chain 25 to move circumferentially, the linkage pin 28 is driven to move upwards through the matching connection hole 113, the linkage pin 28 drives the supporting plate 27 to move upwards, and therefore the hexagonal brick is conveyed upwards, and the execution unit 3 can grab the hexagonal brick.

The fourth step: the positioning cylinder 31 is opened, and the positioning cylinder 31 is matched with the limiting column 321 to drive the connecting rod 32 to rotate anticlockwise; the pushing cylinder 33 is opened, and the pushing cylinder 33 drives the execution contact rod 34 to move leftwards; opening the execution cylinder 35, and enabling the execution cylinder 35 to drive the bearing plate 36 to move upwards, so that the bearing plate 36 moves to the upper part of the supporting plate 27 on the right side of the laying shell 11 to grab the hexagonal brick; at the moment, the execution cylinder 35 pushes the supporting plate 36 to move downwards, when the grabbing rod 38 abuts against the hexagonal brick, the bidirectional cylinder 37 is opened, the bidirectional cylinder 37 drives the grabbing rod 38 to move inwards, and therefore the grabbing rod 38 grabs the hexagonal brick in the fixing clamping groove 272; at the moment, the execution cylinder 35 drives the bearing plate 36 to move upwards to the upper part of the right side, the pushing cylinder 33 drives the execution contact rod 34 to move rightwards, the positioning cylinder 31 cooperates with the limiting post 321 to drive the connecting rod 32 to rotate clockwise, so that the hexagonal brick is moved to the laying position, and the bidirectional cylinder 37 drives the grabbing rod 38 to move outwards, so that the hexagonal brick is placed at the laying position; at this time, the driving crankshaft 391 drives the knocking rod 392 to reciprocate up and down under the action of the driving shaft 13, so as to knock the hexagonal brick laid on the ground, thereby preventing the hexagonal brick from being warped or dislocated.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. The utility model provides a landscape architecture road surface lays machinery, includes frame (1), feed unit (2) and execution unit (3), its characterized in that: frame (1) left side view is the spill structure, and frame (1) lower extreme middle part has seted up linkage hole (111), and feeding unit (2) set up on frame (1) lower extreme middle part left side inner wall, and execution unit (3) set up on frame (1) lower extreme inner wall linkage hole (111) department inner wall, wherein:

frame (1) is including laying shell (11), driving motor (12), transmission shaft (13) and removing roller (14), wherein: the left view of the laying shell (11) is of a concave structure, the middle part of the lower end of the laying shell (11) is provided with a linkage hole (111), the inner side wall of the right end of the laying shell (11) is provided with a linkage groove (112), connecting holes (113) are symmetrically arranged along the front and back of the right side of the middle part of the laying shell (11), a transmission groove (114) is arranged along the outer side of a connecting hole (113) at the right side of the middle part of the laying shell (11), a motor groove (115) is arranged inside the lower end at the right side of the middle part of the laying shell (11), the transmission shafts (13) are arranged on the inner walls at the front end and the rear end of the laying shell (11) in a bilateral symmetry way and are connected through belt transmission, wherein, the rear end of the left transmission shaft (13) is connected with a driving motor (12) through a spline, the driving motor (12) is arranged on the outer wall of the laying shell (11) through a motor base, and the movable roller (14) is symmetrically sleeved on the outer wall of the transmission shaft (13) in a front-back mode through a flange structure;

the feeding unit (2) comprises a bidirectional motor (21), a rotating shaft (22), a transmission chain wheel (23), an execution chain wheel (24), a transmission chain (25), a limiting plate (26), a supporting plate (27) and a linkage pin (28), wherein: the bidirectional motor (21) is arranged in a motor groove (115), a rotating shaft (22) is symmetrically connected with the front and the back of the bidirectional motor (21) through splines, a transmission chain wheel (23) is sleeved on the outer wall of the other end of the rotating shaft (22) through a flange structure, the transmission chain wheel (23) is arranged in a transmission groove (114) in a sliding manner, an execution chain wheel (24) is arranged on the inner wall of the upper side of the transmission groove (114) in a sliding manner through a linkage shaft (241), the transmission chain wheel (23) and the execution chain wheel (24) are connected through a transmission chain (25), a limiting plate (26) is arranged on the inner wall of the right side of the middle part of a laid shell (11), a longitudinal sliding groove (261) matched with a linkage groove (112) is arranged on the outer wall of the right end of the limiting plate (26), the left end of a supporting plate (27) is arranged in the longitudinal sliding groove (261) in a sliding manner, the right end of the supporting plate (27) is arranged in the linkage groove (112) in a sliding manner, the front and back symmetry of the linkage pin (28) is arranged on the outer wall of the supporting plate (27), the linkage pin (28) is connected in the connecting hole (113) in a sliding manner, and the other end of the linkage pin (28) is hinged on the outer wall of the middle part of the right side of the transmission chain (25);

the execution unit (3) comprises a positioning cylinder (31), a connecting rod (32), a pushing cylinder (33), an execution feeler lever (34), an execution cylinder (35), a bearing plate (36), a bidirectional cylinder (37), a grabbing rod (38) and a knocking component (39), wherein: the positioning cylinder (31) is arranged on the inner wall of the left side of the middle part of the lower end of a laying shell (11), the tail end of a telescopic rod of the positioning cylinder (31) is hinged with a connecting rod (32), the middle part of the connecting rod (32) is sleeved with a limiting column (321) through a bearing, the limiting column (321) is arranged on the inner walls of the front end and the rear end of the middle part of the upper side of the laying shell (11), a pushing cylinder (33) is arranged on the outer wall of the right side of the middle part of the connecting rod (32), an execution contact rod (34) is hinged with the right end of the connecting rod (32), the lower end of the execution contact rod (34) is connected with an execution cylinder (35), the tail end of the telescopic rod of the execution cylinder (35) is connected with a bearing plate (36), fixing grooves (361) are uniformly formed in the bearing plate (36) from front to back, transverse sliding holes (362) are symmetrically formed in the left and right of the lower end of the fixing grooves (361), two-way cylinders (37) are arranged in the fixing grooves (361), the tail ends of the telescopic rods of the two-way cylinders (37) are connected with grabbing rods (38), the grabbing rod (38) is connected in the transverse sliding hole (362) in a sliding mode, and the knocking component (39) is arranged in the linkage hole (111) in a sliding mode;

the rapping assembly (39) comprises a drive crankshaft (391) and a rapping rod (392), wherein: the transmission crankshaft (391) is arranged on the inner walls of the front end and the rear end of the laying shell (11) through bearings, the rear end of the transmission crankshaft (391) is connected with the transmission shaft (13) on the right side in a belt transmission mode, the upper side of the middle of the knocking rod (392) is connected to the outer wall of the middle of the transmission crankshaft (391) through the bearings, and the knocking rod (392) is arranged in the linkage hole (111) in a sliding mode.

2. The landscape architecture road paving machine of claim 1, wherein: the left and right symmetry of the supporting plate (27) is provided with guide blocks (271) used for guiding, the left guide block (271) is connected in the longitudinal sliding groove (261) in a sliding mode, the right guide block (271) is arranged in the linkage groove (112) in a sliding mode, and the supporting plate (27) is provided with fixing clamping grooves (272) used for placing the hexagonal bricks in a left-right staggered mode from front to back.

3. The landscape architecture road paving machine of claim 1, wherein: the gripping rod (38) is a Z-shaped structural rod to facilitate gripping of the hex tile.

4. The landscape architecture road paving machine of claim 1, wherein: the striking rod (392) is a T-shaped structural rod for increasing the striking area.

5. The landscape architecture road paving machine of claim 2, wherein: the fixing grooves (361) are structural grooves which are matched with the fixing clamping grooves (272) and are arranged in a left-right staggered mode from front to back.

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