CN112095417A - Electromechanical device for paving bricks on sidewalk - Google Patents

Abstract

The invention discloses electromechanical equipment for paving bricks on a sidewalk, which comprises an equipment shell, wherein a conversion cavity is arranged in the equipment shell, a driven chain wheel shaft and a driving chain wheel shaft are rotatably connected to the inner wall of the lower side of the conversion cavity, the driving chain wheel shaft is positioned on the front side of the driven chain wheel shaft, the upper end of the driven chain wheel shaft is fixedly connected with a driven chain wheel, and the driving chain wheel shaft is fixedly connected with a driving chain wheel; the invention realizes the orderly matching of the tile paving and the brick ramming through the rotatable poking rod, improves the working efficiency, ensures that all the floor tiles are positioned on the same horizontal plane, and ensures that the walking passerby can walk more safely; the temporary storage cavity ensures that the volume of the concrete required by each tile is the same, and further ensures that the amount of the concrete under each tile is the same; the floor tiles are tamped by the tamping blocks, and the stress of each floor tile is ensured to be the same, so that the floor tile plane is smoother.

Description

Electromechanical device for paving bricks on sidewalk

Technical Field

The invention relates to the relevant field of electromechanical equipment, in particular to electromechanical equipment for paving tiles on a sidewalk.

Background

The floor tiles on the sidewalks are manually laid by workers, so that the condition that the road surface of the manually laid road is uneven can be caused, when pedestrians walk on the sidewalks, the pedestrians can be knocked by carelessness, and the safety of the pedestrians is further damaged; due to the fact that the weight of the floor tiles is too large, the same stress degree of each floor tile cannot be guaranteed during laying, and the floor tiles can potentially threaten the body of a worker due to the influence of a working environment in the carrying process of the worker.

The electromechanical device for paving tiles on a sidewalk, which is disclosed by the invention, can solve the problems.

Disclosure of Invention

In order to solve the problems, the electromechanical equipment for paving the bricks on the sidewalk is designed in the embodiment, and comprises an equipment shell, wherein a conversion cavity is arranged in the equipment shell, a driven sprocket shaft and a driving sprocket shaft are rotationally connected to the inner wall of the lower side of the conversion cavity, the driving sprocket shaft is positioned on the front side of the driven sprocket shaft, the upper end of the driven sprocket shaft is fixedly connected with a driven sprocket, the driving sprocket shaft is fixedly connected with a driving sprocket, the driving sprocket is connected with the driven sprocket through a synchronous chain, and the upper end of the synchronous chain is fixedly connected with a poking rod; a guide shaft and a guide rod are fixedly connected between the front inner side and the rear inner side of the conversion cavity, the guide shaft and the guide rod are symmetrically arranged on the left and right sides of the driving sprocket shaft, a sliding guide sleeve is arranged on the guide rod in a sliding mode, a pulling spring is fixedly connected between the front end face of the sliding guide sleeve and the front inner wall of the conversion cavity on the guide rod, a linkage block is fixedly connected to the left end face of the sliding guide sleeve, the shifting rod can shift the linkage block to move, a material pushing sliding plate is arranged on the guide shaft in a sliding mode, a reset spring is fixedly connected between the rear end face of the material pushing sliding plate and the rear inner wall of the conversion cavity on the guide shaft, a linkage handle is fixedly connected to the left end face of the material pushing sliding plate, and the; a fixed rod is fixedly connected to the inner wall of the rear side of the conversion cavity, the fixed rod is located on the rear side of the driven chain wheel, a transmission shaft is connected to the fixed rod in a vertically penetrating mode, a grooved wheel is fixedly connected to the upper end of the transmission shaft, a vertically penetrating shifting groove is formed in the grooved wheel, the shifting rod can be matched with the shifting groove to shift the grooved wheel to rotate, a connection bevel gear is fixedly connected to the lower end of the transmission shaft, a wheel power shaft is rotatably connected to the inner wall of the rear side of the conversion cavity, a power bevel gear is fixedly connected to the front end face of the wheel power shaft, and the power; a sliding plate cavity with a rightward opening is formed in the inner wall of the left side of the conversion cavity, and the material pushing sliding plate extends leftwards into the sliding plate cavity and is in sliding fit with the upper inner side wall and the lower inner side wall of the sliding plate cavity; a power motor is fixedly connected to the inner wall of the front side of the conversion cavity, a worm is in power connection with the rear end face of the power motor, a driving bevel gear is fixedly connected to the worm, a driven bevel gear is fixedly connected to the driving chain wheel shaft and located on the upper side of the driving chain wheel, and the driven bevel gear is meshed with the driving bevel gear; the power motor is started, the worm drives the driving bevel gear to rotate, the driven bevel gear drives the driving chain wheel shaft to rotate, the driving chain wheel drives the synchronous chain to rotate, the poke rod is driven to move, the linkage handle drives the material pushing sliding plate to slide, the grooved pulley drives the transmission shaft to rotate, the linkage block drives the sliding guide sleeve to slide, and the transmission shaft drives the power bevel gear to rotate through the linkage bevel gear while rotating so as to drive the wheel power shaft to rotate.

Beneficially, a floor tile cavity and a concrete cavity are arranged in the equipment shell, the floor tile cavity and the concrete cavity are located on the left side of the conversion cavity and located on the front side of the concrete cavity, the floor tile cavity and the concrete cavity both extend upwards to the upper side of the equipment shell and extend downwards to be communicated with the sliding plate cavity, a linkage shaft is rotatably connected to the inner wall of the left side of the conversion cavity, the linkage shaft extends leftwards into the concrete cavity, a rotating cylinder is fixedly connected to one end of the linkage shaft in the concrete cavity, a temporary storage cavity is arranged in the rotating cylinder, a feeding hole is communicated between the inner wall of the upper side of the temporary storage cavity and the outer circular surface of the rotating cylinder, the feeding hole can be communicated with the concrete cavity, a worm wheel is fixedly connected to the right end of the linkage shaft, and the worm wheel is meshed with the worm; the worm rotates, and then drives the universal driving shaft through the worm wheel and rotates, and then drives rotatory cylinder and rotates, and then makes the open-ended orientation of feed port change.

Beneficially, a fixed block is fixedly connected to the inner wall of the rear side of the conversion cavity, a placement cavity which is through from top to bottom and is provided with a forward opening is arranged in the fixed block, a fixed shaft is rotatably connected between the left inner wall and the right inner wall of the placement cavity, and a transmission rope pulley is fixedly connected to the fixed shaft; a support rod is fixedly connected to the inner wall of the upper side of the conversion cavity, the left end face of the support rod is rotatably connected with a rotating shaft, a connection rope wheel is fixedly connected to the left end of the rotating shaft, a tamping block is arranged on the lower side of the connection rope wheel in the conversion cavity, the tamping block is located on the right side of the guide rod, the upper end of the tamping block is fixedly connected with a connection rope, and the free end of the connection rope extends upwards through the outer circle profile surface of the connection rope wheel and downwards through the outer circle profile surface of the transmission rope wheel and is fixedly connected to the rear end face of the sliding guide sleeve from the lower; the sliding guide sleeve slides, and then drives the ramming block to move through the connecting rope.

Advantageously, a wheel shaft is rotatably connected to the front end face of the equipment housing, a driven wheel is fixedly connected to the front end of the wheel shaft, the wheel power shaft extends backwards to the rear side of the equipment housing, a driving wheel is fixedly connected to the rear end of the wheel power shaft, and the driving wheel and the driven wheel are symmetrical front and back with respect to the equipment housing; a wheel support is fixedly connected to the lower end face of the equipment shell, a placing hole with a downward opening and a left-right through hole is formed in the wheel support, a guide wheel shaft is rotatably connected between the front inner side wall and the rear inner side wall of the placing hole, and a guide wheel is fixedly connected to the guide wheel shaft; the wheel power shaft rotates to further drive the driving wheel to rotate, and further the driven wheel and the guide wheel drive the equipment shell to move.

Beneficially, the inner wall of the lower side of the conversion cavity is communicated with a ramming block sliding hole with a downward opening, and the ramming block sliding hole is located right below the ramming block; the inner wall of the lower side of the sliding plate cavity is communicated with a discharge hole with a downward opening, and the discharge hole is located under the concrete cavity.

The invention has the beneficial effects that: the invention realizes the orderly matching of the tile paving and the brick ramming through the rotatable poking rod, improves the working efficiency, ensures that all the floor tiles are positioned on the same horizontal plane, and ensures that the walking passerby can walk more safely; the temporary storage cavity ensures that the volume of the concrete required by each tile is the same, and further ensures that the amount of the concrete under each tile is the same; the floor tiles are tamped by the tamping blocks, and the stress of each floor tile is ensured to be the same, so that the floor tile plane is smoother.

Drawings

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

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

FIG. 1 is a schematic view of the overall architecture of an electromechanical device for paving tiles on a sidewalk according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic diagram of B-B of FIG. 1;

FIG. 4 is a schematic diagram of the structure of C-C in FIG. 1;

fig. 5 is a schematic diagram of the structure of D-D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1 to 5, for the sake of convenience of description, the following orientations are now defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The electromechanical equipment for paving bricks on a sidewalk comprises an equipment shell 11, wherein a conversion cavity 12 is arranged in the equipment shell 11, the inner wall of the lower side of the conversion cavity 12 is connected with a driven chain wheel shaft 13 and a driving chain wheel shaft 43 in a rotating mode, the driving chain wheel shaft 43 is positioned on the front side of the driven chain wheel shaft 13, the upper end of the driven chain wheel shaft 13 is fixedly connected with a driven chain wheel 15, the driving chain wheel shaft 43 is fixedly connected with a driving chain wheel 44, the driving chain wheel 44 is connected with the driven chain wheel 15 through a synchronous chain 16, and the upper end of the synchronous chain 16 is fixedly connected with a poking rod 28; a guide shaft 32 and a guide rod 19 are fixedly connected between the front inner side and the rear inner side of the conversion cavity 12, the guide shaft 32 and the guide rod 19 are symmetrically arranged on the left and right of the driving sprocket shaft 43, a sliding guide sleeve 18 is slidably arranged on the guide rod 19, a pulling spring 42 is fixedly connected between the front end surface of the sliding guide sleeve 18 and the front inner wall of the conversion cavity 12 on the guide rod 19, a linkage block 25 is fixedly connected on the left end surface of the sliding guide sleeve 18, the poking rod 28 can poke the linkage block 25 to move, a material pushing sliding plate 38 is slidably arranged on the guide shaft 32, a reset spring 53 is fixedly connected between the rear end surface of the material pushing sliding plate 38 and the rear inner wall of the conversion cavity 12 on the guide shaft 32, a linkage handle 39 is fixedly connected on the left end surface of the material pushing sliding plate 38, and the poking rod 28 can poke the; a fixed rod 63 is fixedly connected to the inner wall of the rear side of the conversion cavity 12, the fixed rod 63 is located at the rear side of the driven sprocket 15, the fixed rod 63 is connected with a transmission shaft 64 in a vertically penetrating manner, a grooved pulley 66 is fixedly connected to the upper end of the transmission shaft 64, a vertically penetrating toggle groove 65 is formed in the grooved pulley 66, the toggle rod 28 can be matched with the toggle groove 65 to toggle the grooved pulley 66 to rotate, a linking bevel gear 62 is fixedly connected to the lower end of the transmission shaft 64, a wheel power shaft 50 is rotatably connected to the inner wall of the rear side of the conversion cavity 12, a power bevel gear 61 is fixedly connected to the front end face of the wheel power shaft 50, and the power bevel gear 61; a sliding plate cavity 36 with a right opening is formed in the inner wall of the left side of the conversion cavity 12, and the pushing sliding plate 38 extends leftwards into the sliding plate cavity 36 and is in sliding fit with the upper inner side wall and the lower inner side wall of the sliding plate cavity 36; a power motor 54 is fixedly connected to the inner wall of the front side of the conversion cavity 12, a worm 26 is dynamically connected to the rear end face of the power motor 54, a drive bevel gear 55 is fixedly connected to the worm 26, a driven bevel gear 56 is fixedly connected to the drive sprocket shaft 43, the driven bevel gear 56 is located on the upper side of the drive sprocket 44, and the driven bevel gear 56 is meshed with the drive bevel gear 55; the power motor 54 is started, the worm 26 drives the driving bevel gear 55 to rotate, the driven bevel gear 56 drives the driving sprocket shaft 43 to rotate, the driving sprocket 44 drives the synchronous chain 16 to rotate, the poke rod 28 to move, the linkage handle 39 drives the pushing sliding plate 38 to slide, the grooved wheel 66 drives the transmission shaft 64 to rotate, the linkage block 25 drives the sliding guide sleeve 18 to slide, and the transmission shaft 64 drives the power bevel gear 61 to rotate by engaging with the bevel gear 62 while rotating, so that the wheel power shaft 50 is driven to rotate.

Beneficially, a floor tile cavity 67 and a concrete cavity 31 are arranged in the equipment housing 11, the floor tile cavity 67 and the concrete cavity 31 are both located at the left side of the conversion cavity 12, the floor tile cavity 67 is located at the front side of the concrete cavity 31, the floor tile cavity 67 and the concrete cavity 31 both extend upwards to the upper side of the equipment housing 11 and extend downwards to communicate with the sliding board cavity 36, a linkage shaft 30 is rotatably connected to the inner wall of the left side of the conversion cavity 12, the linkage shaft 30 extends leftwards to the inside of the concrete cavity 31, a rotating cylinder 34 is fixedly connected to one end of the linkage shaft 30 in the concrete cavity 31, a temporary storage cavity 35 is arranged in the rotating cylinder 34, a feeding hole 33 is communicated between the inner wall of the upper side of the temporary storage cavity 35 and the outer circumferential surface of the rotating cylinder 34, the feeding hole 33 can be communicated with the concrete cavity 31, and a worm wheel 27 is fixedly connected to the right end of the linkage shaft 30, the worm wheel 27 is meshed with the worm 26; the worm 26 rotates to drive the linkage shaft 30 to rotate through the worm wheel 27, and further drive the rotary cylinder 34 to rotate, so that the opening direction of the feeding hole 33 changes.

Beneficially, a fixed block 49 is fixedly connected to the inner wall of the rear side of the conversion cavity 12, a placing cavity 48 which is through from top to bottom and has a forward opening is arranged in the fixed block 49, a fixed shaft 46 is rotatably connected between the left inner side wall and the right inner side wall of the placing cavity 48, and a transmission rope pulley 47 is fixedly connected to the fixed shaft 46; a support rod 22 is fixedly connected to the inner wall of the upper side of the conversion cavity 12, the left end face of the support rod 22 is rotatably connected with a rotating shaft 23, the left end of the rotating shaft 23 is fixedly connected with a connecting rope wheel 24, a tamping block 20 is arranged on the lower side of the connecting rope wheel 24 in the conversion cavity 12, the tamping block 20 is positioned on the right side of the guide rod 19, the upper end of the tamping block 20 is fixedly connected with a connecting rope 21, the free end of the connecting rope 21 extends upwards through the outer circle profile surface of the connecting rope wheel 24 and downwards through the outer circle profile surface of the transmission rope wheel 47, and the outer circle profile surface of the transmission rope wheel 47 is fixedly connected to the rear end; the sliding guide sleeve 18 slides, and then the tamping block 20 is driven to move through the connecting rope 21.

Beneficially, a wheel shaft 41 is rotatably connected to the front end surface of the equipment housing 11, a driven wheel 40 is fixedly connected to the front end of the wheel shaft 41, the wheel power shaft 50 extends backwards to the rear side of the equipment housing 11, a driving wheel 14 is fixedly connected to the rear end of the wheel power shaft 50, and the driving wheel 14 and the driven wheel 40 are symmetrical front and back with respect to the equipment housing 11; a wheel bracket 57 is fixedly connected to the lower end face of the equipment housing 11, a placing hole 60 with a downward opening and a through left and right is formed in the wheel bracket 57, a guide wheel shaft 59 is rotatably connected between the front inner side wall and the rear inner side wall of the placing hole 60, and a guide wheel 58 is fixedly connected to the guide wheel shaft 59; the wheel power shaft 50 rotates to drive the driving wheel 14 to rotate, and the driven wheel 40 and the guide wheel 58 drive the equipment housing 11 to move.

Beneficially, the inner wall of the lower side of the conversion cavity 12 is communicated with a ramming block sliding hole 17 with a downward opening, and the ramming block sliding hole 17 is positioned right below the ramming block 20; the inner wall of the lower side of the sliding plate cavity 36 is provided with a discharge hole 37 with a downward opening in a communicating mode, and the discharge hole 37 is located under the concrete cavity 31.

The use steps of an electromechanical device for paving tiles on a sidewalk according to the present invention are described in detail below with reference to fig. 1 to 5: initially, the pusher sled 38 is at the front limit position and in front of the floor tile cavity 67, the slide guide 18 is at the rear position on the guide bar 19 under the elastic force of the pulling spring 42, the opening of the feeding hole 33 faces upward, and the tap lever 28 is at the foremost position.

Placing floor tiles required for paving into a floor tile cavity 67, placing concrete into a concrete cavity 31, placing a floor tile in the floor tile cavity 67 at the rear side of a material pushing sliding plate 38 in a sliding plate cavity 36, and enabling the concrete in the concrete cavity 31 to fall into a temporary storage cavity 35 through a feeding hole 33; the power motor 54 is started to drive the worm 26 to rotate, the linkage shaft 30 is driven to rotate through the worm wheel 27, the rotating cylinder 34 is driven to rotate, the opening of the feeding hole 33 faces downwards, the concrete in the temporary storage cavity 35 passes through the discharging hole 37 and falls onto the ground, the worm 26 rotates and simultaneously drives the driving bevel gear 55 to rotate, the driven bevel gear 56 drives the driving sprocket shaft 43 to rotate, the driving sprocket 44 drives the synchronous chain 16 to rotate, the poking rod 28 is driven to rotate, the linkage handle 39 drives the material pushing sliding plate 38 to slide backwards, the floor tiles on the rear side of the material pushing sliding plate 38 are pushed to the upper side of the discharging hole 37 and fall onto the concrete on the ground through the discharging hole 37, when the material pushing sliding plate 38 slides to the rear limit position, the poking rod 28 is separated from the linkage handle 39, and the material pushing plate 38 returns to the initial state under the elastic force of the return spring 53, after the poke rod 28 is separated from the linkage handle 39, the poke grooved wheel 66 is rotated through the matching with the poke groove 65, the drive transmission shaft 64 is driven to drive the connecting bevel gear 62 to rotate, the power bevel gear 61 is driven to drive the wheel power shaft 50 to rotate, the drive wheel 14 is driven to rotate, the device is displaced, the lower end of the discharge hole 37 is aligned to the ground without concrete, the floor tiles which just fall are positioned at the lower side of the ramming block sliding hole 17, the poke rod 28 is separated from the poke groove 65 and then drives the linkage block 25 to move, the sliding guide sleeve 18 is driven to slide forwards, the ramming block 20 is driven to move upwards through the connecting rope 21, when the ramming block 20 moves to the upper limit position, the poke rod 28 is separated from the linkage block 25, the ramming block 20 falls downwards under the action of gravity and drives the sliding guide sleeve 18 to slide through the connecting rope 21, the sliding guide sleeve 18 stretches the, when the ramming mass 20 is abutted against the floor tile on the lower side of the ramming mass sliding hole 17, the floor tile is tamped so that the floor tile becomes stable; when the poke rod 28 rotates to the front limit position, the next floor tile is laid, when the floor tiles in the floor tile cavity 67 and the concrete in the concrete cavity 31 are used up, the power motor 54 is stopped to supplement raw materials, then the next work is continued, and if the floor tiles and the concrete are not used up, the power motor 54 is stopped, so that the equipment is restored to the initial state.

The invention has the beneficial effects that: the invention realizes the orderly matching of the tile paving and the brick ramming through the rotatable poking rod, improves the working efficiency, ensures that all the floor tiles are positioned on the same horizontal plane, and ensures that the walking passerby can walk more safely; the temporary storage cavity ensures that the volume of the concrete required by each tile is the same, and further ensures that the amount of the concrete under each tile is the same; the floor tiles are tamped by the tamping blocks, and the stress of each floor tile is ensured to be the same, so that the floor tile plane is smoother.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. An electromechanical device for paving tiles on a sidewalk, comprising a device housing, characterized in that: a conversion cavity is arranged in the equipment shell, a driven sprocket shaft and a driving sprocket shaft are rotatably connected to the inner wall of the lower side of the conversion cavity, the driving sprocket shaft is positioned at the front side of the driven sprocket shaft, a driven sprocket is fixedly connected to the upper end of the driven sprocket shaft, a driving sprocket is fixedly connected to the driving sprocket shaft, the driving sprocket is connected with the driven sprocket through a synchronous chain, and a poking rod is fixedly connected to the upper end of the synchronous chain; a guide shaft and a guide rod are fixedly connected between the front inner side and the rear inner side of the conversion cavity, the guide shaft and the guide rod are symmetrically arranged on the left and right sides of the driving sprocket shaft, a sliding guide sleeve is arranged on the guide rod in a sliding mode, a pulling spring is fixedly connected between the front end face of the sliding guide sleeve and the front inner wall of the conversion cavity on the guide rod, a linkage block is fixedly connected to the left end face of the sliding guide sleeve, the shifting rod can shift the linkage block to move, a material pushing sliding plate is arranged on the guide shaft in a sliding mode, a reset spring is fixedly connected between the rear end face of the material pushing sliding plate and the rear inner wall of the conversion cavity on the guide shaft, a linkage handle is fixedly connected to the left end face of the material pushing sliding plate, and the; a fixed rod is fixedly connected to the inner wall of the rear side of the conversion cavity, the fixed rod is located on the rear side of the driven chain wheel, a transmission shaft is connected to the fixed rod in a vertically penetrating mode, a grooved wheel is fixedly connected to the upper end of the transmission shaft, a vertically penetrating shifting groove is formed in the grooved wheel, the shifting rod can be matched with the shifting groove to shift the grooved wheel to rotate, a connection bevel gear is fixedly connected to the lower end of the transmission shaft, a wheel power shaft is rotatably connected to the inner wall of the rear side of the conversion cavity, a power bevel gear is fixedly connected to the front end face of the wheel power shaft, and the power; a sliding plate cavity with a rightward opening is formed in the inner wall of the left side of the conversion cavity, and the material pushing sliding plate extends leftwards into the sliding plate cavity and is in sliding fit with the upper inner side wall and the lower inner side wall of the sliding plate cavity; the power motor is fixedly connected to the inner wall of the front side of the conversion cavity, the worm is in power connection with the rear end face of the power motor, a driving bevel gear is fixedly connected to the worm, a driven bevel gear is fixedly connected to the driving chain wheel shaft and located on the upper side of the driving chain wheel, and the driven bevel gear is meshed with the driving bevel gear.

2. An electromechanical device for paving tiles on a sidewalk according to claim 1, characterized in that: the floor tile cavity and the concrete cavity are arranged in the equipment shell and are located on the left side of the conversion cavity, the floor tile cavity and the concrete cavity are located on the front side of the concrete cavity, the floor tile cavity and the concrete cavity both extend upwards to the upper side of the equipment shell and are communicated with the sliding plate cavity in a downward extending mode, a linkage shaft is connected to the inner wall of the left side of the conversion cavity in a rotating mode, the linkage shaft extends leftwards into the concrete cavity, a rotary cylinder is fixedly connected to one end of the linkage shaft, located in the concrete cavity, of the linkage shaft, a temporary storage cavity is arranged in the rotary cylinder, a feeding hole is formed in the inner wall of the upper side of the temporary storage cavity and communicated with the outer circular surface of the rotary cylinder, the feeding hole can be communicated with the concrete cavity, a worm wheel is fixedly connected to the right end of the linkage shaft, and.

3. An electromechanical device for paving tiles on a sidewalk according to claim 1, characterized in that: a fixed block is fixedly connected to the inner wall of the rear side of the conversion cavity, a placing cavity which is communicated up and down and has a forward opening is arranged in the fixed block, a fixed shaft is rotatably connected between the left inner side wall and the right inner side wall of the placing cavity, and a transmission rope pulley is fixedly connected to the fixed shaft; the rigid coupling has the bracing piece on the conversion chamber upside inner wall, the bracing piece left end face rotates and is connected with the axis of rotation, the axis of rotation left end rigid coupling has the linking rope sheave, the conversion intracavity in linking up the rope sheave downside and being equipped with the rammer block, the rammer block is located the guide bar right side, the rammer block upper end has linked firmly the connection rope, the free end of connecting the rope upwards extends the excircle profile face that links up the rope sheave and extends downwards the transmission rope sheave excircle profile face is followed the downside rigid coupling of transmission rope sheave in on the rear end face of sliding guide sleeve.

4. An electromechanical device for paving tiles on a sidewalk according to claim 1, characterized in that: the front end surface of the equipment shell is rotatably connected with a wheel shaft, the front end of the wheel shaft is fixedly connected with a driven wheel, the wheel power shaft extends to the rear side of the equipment shell, the rear end of the wheel power shaft is fixedly connected with a driving wheel, and the driving wheel and the driven wheel are symmetrical in front and back around the equipment shell; the device comprises a device shell and is characterized in that a wheel support is fixedly connected to the lower end face of the device shell, a placing hole with a downward opening and a through left side and right side is formed in the wheel support, a guide wheel shaft is rotatably connected between the front inner side wall and the rear inner side wall of the placing hole, and a guide wheel is fixedly connected to the guide wheel shaft.

5. An electromechanical device for paving tiles on a sidewalk according to claim 1, characterized in that: the inner wall of the lower side of the conversion cavity is communicated with a ramming block sliding hole with a downward opening, and the ramming block sliding hole is positioned right below the ramming block; the inner wall of the lower side of the sliding plate cavity is communicated with a discharge hole with a downward opening, and the discharge hole is located under the concrete cavity.

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