CN211074066U - Dislocation driving mechanism of bricklaying antique equipment - Google Patents

Abstract

The utility model relates to a dislocation driving mechanism of bricklaying antique equipment, which is used for driving antique assemblies A, B to be dislocated left and right, the dislocation driving mechanism comprises a motor mounting seat, a double-shaft motor, an eccentric mounting seat, a push rod and a fixing seat, and the eccentric mounting seats are fixedly arranged at the tail ends of two output shafts of the double-shaft motor; one fixed seat is fixedly arranged on one side of the assembly A, the other fixed seat is fixedly arranged on the other side of the assembly B, one end of one push rod is hinged to the fixed seat on the assembly A, the other end of the push rod is hinged to the eccentric mounting seat close to the assembly A, one end of the other push rod is hinged to the fixed seat on the assembly B, the other end of the other push rod is hinged to the eccentric mounting seat close to the assembly B, and the phase difference between the hinged ends of the two push rods and the eccentric. The utility model discloses only need to drive assembly A, B anisotropic translation through a biax motor to adjust the dislocation volume between the assembly A, B and make different old effect of doing, remove about assembly A, B in addition more lightly and only on the left right direction rectilinear movement.

Description

Dislocation driving mechanism of bricklaying antique equipment

Technical Field

The utility model belongs to the technical field of the processing equipment of laying bricks, concretely relates to dislocation actuating mechanism of equipment of making old is done to laying bricks.

Background

The bricklaying antique-making equipment is mainly used for carrying out secondary processing on the surface of a brick body which is well maintained as a finished product, and generally comprises a set of antique-making assembly or two antique-making assemblies which are independently controlled by respective driving mechanisms.

SUMMERY OF THE UTILITY MODEL

In view of prior art's not enough, the utility model aims to solve the technical problem that a dislocation actuating mechanism of equipment is made old to brickwork is provided, it can be according to making old effect adjustment two sets and making old about between the assembly dislocation volume and adjust efficiently.

In order to solve the technical problem, the utility model discloses a technical scheme is:

the dislocation driving mechanism of the bricklaying antique equipment is used for driving the antique assembly A and the antique assembly B to be dislocated left and right, and comprises a motor mounting seat of a motor mounting plate, a double-shaft motor, two eccentric mounting seats, two push rods and two fixing seats, wherein two ends of the motor mounting seat of the motor mounting plate are fixedly arranged on a synchronous plate between the antique assembly A and the antique assembly B respectively, the double-shaft motor is fixedly arranged in the middle of the motor mounting seat of the motor mounting plate, and the tail ends of two output shafts of the double-shaft motor are fixedly provided with the eccentric mounting seats respectively; one fixing seat is fixedly arranged on one side of the antique finishing assembly A, the other fixing seat is fixedly arranged on the other side of the antique finishing assembly B, one end of one push rod is hinged to the fixing seat on the antique finishing assembly A, the other end of the push rod is hinged to the eccentric mounting seat close to the antique finishing assembly A, one end of the other push rod is hinged to the fixing seat on the antique finishing assembly B, the other end of the other push rod is hinged to the eccentric mounting seat close to the antique finishing assembly B, and the phase difference between the hinged ends of the two push rods and the eccentric mounting seat.

Preferably, the eccentric amount of the two eccentric mounting seats is the same.

Preferably, each eccentric mounting seat is provided with a limiting sliding groove, and the other end of the push rod is fixedly mounted in the limiting sliding groove.

Preferably, the antique finishing assembly A and the antique finishing assembly B both comprise antique finishing inner frames, the top of the antique finishing inner frame of the antique finishing assembly A and the top of the antique finishing inner frame of the antique finishing assembly B are matched with corresponding guide beams through first rollers, the left side and the right side of each guide beam are connected through a synchronization plate, and two ends of the motor mounting seat are fixedly mounted on the synchronization plate between the antique finishing assembly A and the antique finishing assembly B respectively; the inner frame comprises outer side plates positioned at the front end and the rear end and inner side plates respectively positioned within the outer side plates, wherein a plurality of buffer blocks are clamped between the outer side plates and the inner side plates, and the outer side plates are fixedly connected with the inner side plates.

Preferably, the fixing seat is fixedly arranged on the inner side plate.

Preferably, the left and right synchronizing plates are horizontally provided with guide beams respectively inside the front and rear ends of the two antique inner frames, the inner side plates are provided with first rollers in rolling fit with the top surfaces of the guide beams, the left and right ends of the antique inner frames are also horizontally provided with limit beams respectively, the limit beams are perpendicular to the guide beams, and the front and rear ends of the limit beams are provided with second rollers in rolling fit with the side surfaces of the guide beams respectively.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model discloses a dislocation actuating mechanism includes the biax motor, eccentric mount pad, push rod and fixing base, the fixing base is adorned in one side of making old assembly A, B admittedly, one end of push rod articulates in the fixing base and the other end articulates on the eccentric mount pad of biax motor output shaft end, and the phase difference of the hinged end with eccentric mount pad of two push rods is 180 degrees apart, only need to drive through a biax motor like this and make old assembly A and make old assembly B incorgruous translation to realize adjusting the dislocation volume between the assembly A, B of making old, and then make different old effects on same bricklaying surface;

2. since the old-made assemblies A, B are respectively matched with the top surface of the guide beam in a rolling way through the first roller and the side surface of the guide beam in a rolling way through the second roller, the old-made assemblies A, B can move left and right more conveniently and can only move linearly in the left and right direction without changing the front-back horizontal posture and the up-down relative position of each old-made assembly.

3. The utility model discloses arrange around the conveyer and do old assembly A and do old assembly B, and do old assembly A, B and can be according to the height about the brick height is adjusted by lift actuating mechanism to can be according to doing old left and right sides position and controlling the dislocation by the adjustment of dislocation actuating mechanism on the surface of laying bricks, also can cooperate the conveyer to make various effects of doing old on the surface of laying bricks simultaneously, consequently adopt the utility model discloses it can make the old effect of the old of difference and be applicable to the surface of laying bricks of multiple specification and do old processing to lay bricks equipment of doing old.

Drawings

Fig. 1 is the utility model discloses the old equipment structure sketch map is done to bricklaying.

Fig. 2 is a schematic diagram of the structure of the old-making host of the present invention.

Fig. 3 is a partially enlarged view B shown in fig. 2.

Fig. 4 is a partially enlarged view of C shown in fig. 2.

Fig. 5 is a partial enlarged view D shown in fig. 2.

Fig. 6 is an enlarged view of a portion a shown in fig. 1.

Fig. 7 is a schematic structural view of the dislocation driving mechanism of the present invention.

Fig. 8 is a schematic structural view of the antique finishing assembly a or antique finishing assembly B of the present invention.

Fig. 9 is a partial enlarged view of P shown in fig. 8.

Fig. 10 is an internal structural diagram of the antique finishing assembly of the present invention.

Fig. 11 is a front view of fig. 10.

Fig. 12 is a partial view of the pull-up position of the working mechanism of the present invention.

Fig. 13 is a schematic view of the installation of the working mechanism and the rotary base of the present invention.

Fig. 14 is a schematic view of the structure of the rotary seat of the present invention.

Fig. 15 is a top view of the lifting driving mechanism of the present invention.

Fig. 16 is a schematic structural view of the lifting driving mechanism of the present invention.

Fig. 17 is a partial enlarged view of E shown in fig. 16.

Fig. 18 is a partial enlarged view of F shown in fig. 16.

The labels in the figure are: 1000. making an old host; 2000. a conveyor; 100. an old assembly A; 200. an old assembly B; 300. a synchronization board; 400. a lifting drive mechanism; 500. a dislocation drive mechanism; 600. making an old external frame; 700. a pinch roller mechanism;

11. making an old internal frame; 12. an old motor is made; 13. a drive shaft; 14. an eccentric link; 15. a working mechanism; 16. a synchronous belt; 17. a rotating base; 19. pressing a plate; 190. a middle plate; 111. a guide beam; 112. a first roller; 113. a limiting beam; 114. a second roller; 115. an outer panel; 116. an inner side plate; 117. a buffer block; 151. a square tube bracket; 152. a chiseling impact head; 171. a buffer limit block; 172. rotating the rocker; 173. a fixing plate; 174. an elastic strip-seat bearing; 181. a limiting rod; 182. a limiting head; 183. a pull rod; 184. lifting the plate;

41. a lifting motor; 42. a lifting assembly; 43. a driven wheel; 44. a first sprocket; 45. a second sprocket; 46. a third sprocket; 47. a fourth sprocket; 48. a transmission chain A; 49. a transmission chain B; 421. a mounting seat; 422. a connecting plate; 423. a lifting screw rod; 424. a safety stop;

51. a motor mounting seat; 52. a double-shaft motor; 53. an eccentric mounting seat; 54. a push rod; 55. a fixed seat; 530. a limiting chute;

71. a pinch roller shaft; 72. adjusting the support; 73. a pinch roller assembly; 721. a guide seat; 722. a movable seat; 723. a damping spring; 724. an adjustment member; 80. a dust suction pipe.

Detailed Description

In order to make the aforementioned and other features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

As shown in fig. 1 to 18, the embodiment provides a bricklaying antique equipment, which includes a antique host 1000 and a conveyor 2000 for conveying workpieces, wherein the antique host 1000 includes an antique outer frame 600 mounted above the conveyor 2000, and an antique assembly a100, an antique assembly B200 and a lifting drive mechanism 400 mounted on the antique outer frame 600, the conveyor 2000 is used for carrying and conveying bricklaying workpieces from front to back, and may be of a conventional conveyor structure, which is not described herein again, and the antique host 1000 is used for roughening and antique the upper surfaces of the bricklaying workpieces on the conveying surface of the conveyor 2000, so as to generate different antique effects and meet market requirements.

In this embodiment, the antique finishing assembly a100 and the antique finishing assembly B200 are arranged in front of and behind the conveying direction of the conveyor 2000, the top of the antique finishing assembly a100 and the top of the antique finishing assembly B200 are respectively matched with the corresponding guide beams 111 through the first rollers 112, the left side and the right side of each guide beam 111 are connected through the synchronizing plate 300, the misalignment driving mechanism 500 is arranged in the center of the synchronizing plate 300 between the antique finishing assembly a100 and the antique finishing assembly B200 to enable the antique finishing assembly a100 and the antique finishing assembly B200 to horizontally move along the respective guide beams 111 in different directions, the lifting driving mechanism 400 is in transmission connection with the synchronizing plate 300 to synchronously drive the antique finishing assembly a100 and the antique finishing assembly B200 to vertically lift, so that the antique finishing assembly a 1000 or the left and right misalignment finishing assembly a100 and the antique finishing assembly B200 can be lifted according to the specifications of different brickwork workpieces, and different antique finishing effects of different specifications can be produced.

In this embodiment, the lifting driving mechanism 400 includes a lifting motor 41, a lifting assembly 42, and an inner frame transmission mechanism for driving and connecting the lifting assembly 42 and the lifting motor 41, the lifting motor 41 is fixedly installed on the top of the antique outer frame 600, a set of lifting assemblies 42 are respectively installed at the front and rear ends of each synchronization board 300, and each lifting assembly 42 is synchronously driven by the lifting motor 41 through the inner frame transmission mechanism.

Wherein: the lifting assembly 42 comprises a mounting base 421, a lifting screw 423, a lifting nut and a connecting plate 422, the mounting base 421 is fixedly mounted on the old outer frame 600, two ends of the lifting screw 423 are axially fixed and circumferentially rotatably arranged on the mounting base 421, the lifting nut is screwed on the lifting screw 423, the connecting plate 422 is fixedly connected with the lifting nut and is connected with the synchronizing plate 300, so that the lifting nut, the connecting plate 422 and the synchronizing plate 300 can be driven to synchronously lift up and down after the lifting screw 423 rotates, the lifting height can be controlled in an automatic sensing mode or a manual mode, the automatic sensing mode can be a photoelectric switch assembly which can be adjusted up and down and is opposite to the left and right, the automatic sensing mode is the prior art, and the description is omitted. In addition, in order to prevent the old host 1000 from rising to damage the components on the top of the old external frame 600, such as the elevator motor 41, etc., safety stoppers 424 are further respectively arranged on the mounting seats 421 at both sides of the elevating path of the elevator nut, the distance between the two safety stoppers 424 is smaller than the width of the elevator nut, and the elevating height of the elevator nut is limited by the safety stoppers 424.

Wherein: the inner frame transmission mechanism comprises a driving wheel, a first transmission assembly and a second transmission assembly, the first transmission assembly and the second transmission assembly are respectively in transmission connection with the driving wheel, the lifting motor 41 is fixedly installed in the middle of one side of the old-made outer frame 600 through an installation frame, the driving wheel is connected to a motor shaft of the lifting motor 41 in a shaft mode, the first transmission assembly is in transmission connection with two groups of lifting assemblies 42 on the synchronizing plate 300 on one side, and the second transmission assembly is in transmission connection with two groups of lifting assemblies 42 on the synchronizing plate 300 on the other side. Specifically, the method comprises the following steps: the first transmission assembly and the second transmission assembly are the same and respectively comprise a driven wheel 43, a first chain wheel 44, a second chain wheel 45, a third chain wheel 46, a fourth chain wheel 47, a transmission chain A48 and a transmission chain B49, wherein the transmission chain A48 is respectively in transmission connection with the first chain wheel 44 and the second chain wheel 45, the transmission chain B49 is in transmission connection with the third chain wheel 46 and the fourth chain wheel 47, the driven wheel 43 and the first chain wheel 44 are coaxially installed on a first rotating shaft between the mounting frame and the old outer frame 600, the third chain wheel 46 and the second chain wheel 45 are coaxially installed on a lifting screw 423 close to the lifting motor 41, the fourth chain wheel 47 is coaxially installed on the lifting screw 423 far away from the lifting motor 41, and the driven wheel 43 is meshed with the driving wheel. Thus, when the lifting motor 41 works, the driving wheel can drive the first transmission assembly and the second transmission assembly to synchronously work, the first transmission assembly drives one of the synchronization plates 300 to ascend, the second transmission assembly drives the other synchronization plate 300 to ascend, the first transmission assembly drives one of the synchronization plates 300 to descend, and the second transmission assembly drives the other synchronization plate 300 to descend, so that the old-made main machine 1000 and the synchronization plates 300 on the left side and the right side of the old-made main machine can ascend or descend through the lifting driving mechanism 400 to match different brick heights.

In this embodiment, the antique finishing assembly a100 and the antique finishing assembly B200 have the same structure, and respectively include an antique finishing motor 12, an antique finishing inner frame 11, a working mechanism 15, a transmission shaft 13 and an eccentric link 14, the transmission shaft 13 is horizontally and rotatably disposed on the antique finishing inner frame 11 and perpendicular to the conveying direction of the workpiece, the left end and the right end of the transmission shaft 13 are respectively eccentrically connected to the eccentric link 14 through a joint bearing, the other end of each eccentric link 14 drives the working mechanism 15 to do work up and down above the conveyor 2000, and the antique finishing motor 12 is fixedly mounted on the top of the antique finishing inner frame 11 and is in transmission connection with the transmission shaft 13. In specific product application, one transmission shaft 13 can be designed to drive one working mechanism 15 to do work up and down through an eccentric connecting rod 14, certainly, in order to expand the adaptability of equipment and the specification range of processed products, one transmission shaft 13 can be designed to drive two working mechanisms 15 to do work up and down alternately through one eccentric connecting rod 14, or one antique-finished assembly is provided with two transmission shafts 13, and each transmission shaft 13 respectively drives two working mechanisms 15 to do work up and down alternately through one eccentric connecting rod 14.

As a preferred embodiment, as shown in fig. 2, 3, 10: the two transmission shafts 13 are parallel to each other, the antique-making motor 12 is in transmission connection with one of the transmission shafts 13, and the two transmission shafts 13 are in transmission connection through a synchronous belt 16, namely, the work of one antique-making motor 12 can drive the two transmission shafts 13 to synchronously rotate in the same direction. Simultaneously, do that two roating seats 17 are adorned admittedly respectively at both ends about old inner tower 11 and lie in about two roating seats 17 of homonymy just right, the interval is provided with two operating device 15 around between two roating seats 17 that lie in the place ahead, the interval is provided with two operating device 15 around between two roating seats 17 that lie in the rear, same transmission shaft 13 both ends are respectively through eccentric connecting rod 14 eccentric hinge in the corresponding side of roating seat 17, can drive about just right two roating seat 17 synchronous syntropy actions through the eccentric connecting rod 14 at its both ends when transmission shaft 13 is rotatory like this: one side of the rotating seat 17 is pulled upwards or pushed downwards relative to the other side thereof, the side of the rotating seat 17 hinged with the eccentric connecting rod 14 is used as an execution end for controlling the rotating seat 17 to turn upwards and downwards, and when the rotating seat 17 turns upwards and downwards, the two working mechanisms 15 on the rotating seat 17 can be driven to alternately do work upwards and downwards.

Wherein: the roating seat 17 is including buffering restriction piece 171 and rotatory wane 172, buffering restriction piece 171 is through fixed plate 173 fixed mounting on doing old inner tower 11, the middle part cover of rotatory wane 172 is outside buffering restriction piece 171 and its front and back both ends are fixed respectively and are provided with operating device 15, the other end of eccentric connecting rod 14 articulates on the bearing frame of any side around rotatory wane 172.

In order to prevent the two working mechanisms 15 from freely rotating, the left end and the right end of each of the two working mechanisms 15 on the same rotary base 17 are respectively provided with a limiting rod 181, a pull rod 183 is movably sleeved on the limiting rod 181, the top end of the limiting rod 181 is fixedly provided with a limiting head 182, the other ends of the two pull rods 183 are respectively hinged to the same lifting plate 184, the lifting plate 184 is fixedly arranged on the old-made inner frame 11, and therefore the two working mechanisms 15 are limited from freely rotating when doing work downwards through the lifting plate 184, the limiting heads 182 and the two pull rods 183.

Wherein: the working mechanism 15 comprises a square pipe support 151 and a plurality of roughening impact heads 152 arranged on the square pipe support 151 at intervals, each roughening impact head 152 comprises a supporting shaft vertically and fixedly arranged on the square pipe support 151 through a self-lubricating bearing, a knocking block fixedly arranged at the bottom end of the supporting shaft, a locking nut locked at the top end of the supporting shaft and a spring sleeved outside the supporting shaft between the knocking block and the locking nut, the supporting shaft, the knocking block, the locking nut and the spring are assembled into a whole, and two ends of the square pipe support 151 are fixedly arranged on the rotating warping plate 172 through elastic bearing blocks 174 respectively.

In addition, the pressing plates 19 are horizontally arranged between the antique inner frames 11 below the middle of each rotating seat 17 in the embodiment, two ends of each pressing plate 19 are fixedly connected with the fixing plate 173 through the middle plate 190, a gap is reserved between each pressing plate 19 and the surface of a brickwork workpiece when the working mechanism 15 performs roughening antique finishing so as to prevent the brickwork from tilting, the gap is small, the brickwork can pass through the gap but is limited by the pressing plates 19 when tilting, and the size of the gap is generally 2-10 mm.

In addition, in order to avoid the change of the relative position of the brickwork on the conveyor 2000 caused by impact during the old-fashioned process, the old-fashioned assembly a100 and the old-fashioned assembly B200 of the embodiment are further provided with a pressing wheel mechanism 700 at the bottom of the input side and the bottom of the output side respectively. Specifically, the method comprises the following steps: the pinch roller mechanism 700 comprises pinch roller shafts 71, pinch roller assemblies 73 and adjusting supports 72, two groups of adjusting supports 72 are arranged on the left side and the right side of the old-made inner frame 11 respectively, two ends of each pinch roller shaft 71 are horizontally and rotatably arranged on the adjusting supports 72, and the pinch roller assemblies 73 are horizontally sleeved in the middles of the pinch roller shafts 71 and are located above the conveyor 2000. The pinch roller assembly 73 comprises a plurality of elastic pinch rollers, spacing sleeves and limiting sleeves, the elastic pinch rollers are tightly sleeved on pinch roller shafts 71 and rotate along with the pinch roller shafts 71, the spacing sleeves are respectively sleeved on the pinch roller shafts between two adjacent elastic pinch rollers to enable the elastic pinch rollers to be spaced at a certain distance, and the limiting sleeves are locked on the pinch roller shafts 71 on the left side and the right side of the elastic pinch rollers to prevent the elastic pinch rollers from moving left and right. The adjusting support 72 comprises a guide seat 721, a moving seat 722, an adjusting piece 724, a damping spring 723 and a linear sliding bearing, the guide seat 721 is fixedly installed on the old inner frame 11, a guide groove is formed in the guide seat, the moving seat 722 is in sliding fit with the guide groove, the adjusting piece 724 is in threaded connection with the guide seat 721 and vertically penetrates through the guide seat 721 downwards to be fixedly connected with the top of the moving seat 722, the damping spring sleeve 723 is arranged outside the adjusting piece 724 between the top of the moving seat 722 and the guide seat 721, and the end of the pressure wheel shaft 71 is sleeved in the linear sliding bearing and installed in the moving seat 722 through a rolling bearing. Thus, the pressing wheel mechanism 700 floats upwards adaptively when contacting with the brick surface and keeps contacting with the brick surface, and the brick-laying follow-up conveyor 2000 also drives the elastic pressing wheel to roll on the brick surface when conveying backwards, and when the old-making assembly a100 and the old-making assembly B200 move left and right, the pressing wheel mechanism 700 does not move left and right, so that the brick-laying follow-up conveyor 2000 moves without sliding.

Furthermore, the bottom of the antique finishing assembly a100 and the bottom of the antique finishing assembly B200 are also respectively provided with a dust collection mechanism, the dust collection mechanism comprises a dust collection pump and a dust collection pipe 80, the dust collection pipe 80 is transversely arranged above the conveyor 2000 and connected with the antique finishing inner frame 11, the bottom of the dust collection pipe 80 is provided with a plurality of dust collection ports, the dust collection pump is connected with one end of the dust collection pipe 80 through a pipeline, chips generated by chiseling can be timely transferred through the dust collection mechanism, the surface is kept clean, and the processing quality of the chiseling position is guaranteed.

In this embodiment, the misalignment driving mechanism 500 includes a motor mounting seat 51, a dual-axis motor 52, two eccentric mounting seats 53, two push rods 54 and two fixing seats 55, two ends of the motor mounting seat 51 are respectively and fixedly mounted on the synchronization plate 300 between the antique assembly a100 and the antique assembly B200, the dual-axis motor 52 is fixedly mounted in the middle of the motor mounting seat 51, two output shafts of the dual-axis motor are both arranged along the conveying direction of the conveyor 2000, and the eccentric mounting seats 53 are respectively and fixedly mounted at the tail ends of the two output shafts; one of the fixing seats 55 is fixedly arranged on one side of the antique finishing assembly A100, the other fixing seat 55 is fixedly arranged on the other side of the antique finishing assembly B200, and the two fixing seats 55 are respectively arranged on two different sides perpendicular to the conveying direction of the conveyor 2000; one end of one push rod 54 is hinged to the fixed seat 55 on the old-made assembly A100, the other end of the other push rod 54 is hinged to the eccentric mounting seat 53 close to the old-made assembly A100, one end of the other push rod 54 is hinged to the fixed seat 55 on the old-made assembly B200, the other end of the other push rod 54 is hinged to the eccentric mounting seat 53 close to the old-made assembly B200, the phase difference between the hinged ends of the two push rods 54 and the eccentric mounting seat 53 is 180 degrees, the two push rods 54 move oppositely or away from each other, and then the old-made assembly A100 and the old-made assembly B200 are mutually staggered in the left-right direction, and the displacement is controlled by the eccentricity of the eccentric mounting seat 53.

Preferably, the eccentric amounts of the two eccentric mounts 53 are the same, so that the moving amounts of the two push rods 54 are the same. Each eccentric mounting seat 53 is provided with a limiting sliding groove 530, the other end of the push rod 54 is fixedly mounted at a certain position in the limiting sliding groove 530, and the arrangement of the limiting sliding groove 530 can facilitate the adjustment of the fixing position of the other end of the push rod 54, namely the eccentric amount, according to different bricklaying specifications and antique effects.

Because the antique-and-curio assemblies A100 and B200 need to move, but the portability and the linearity of the movement only in the left-right direction of the antique-and-curio assemblies A100 and B200 need to be ensured, guide beams 111 are horizontally arranged between the synchronous plates 300 on the left side and the right side of the embodiment respectively in the front and the rear ends of the antique-and-curio inner frames 11, first rollers 112 in rolling fit with the top surfaces of the guide beams 111 are respectively arranged on the front and the rear ends of each antique-and-curio inner frame 11, limit beams 113 are further horizontally arranged on the left and the right ends of each antique-and-curio inner frame 11 respectively, and the limit beams 113 are perpendicular to the guide beams 111 and are respectively provided with second rollers 114 in rolling fit with the side surfaces of the guide beams 111 on the. In this way, the left and right movement of the old assembly a100 and the old assembly B200 is made more light by the first roller 112, the left and right movement is restricted to be linear only in the left and right directions by the old assembly a100 and the old assembly B200 being rolled on the top surface of the guide beam 111 and the second rollers 114 on the front and rear sides.

Preferably, the inner framework 11 includes outer side plates 115 located at the front and rear ends and inner side plates 116 located inside the outer side plates 115, a plurality of buffer blocks 117 are sandwiched between the outer side plates 115 and the inner side plates 116, the outer side plates 115 and the inner side plates 116 are fixedly connected together, the fixing seat 55 is fixedly mounted on the inner side plates 116, the front and rear ends of the limiting beam 113 are fixedly connected to the inner side plates 116, and the first roller 112 is mounted on the inner side plates 116 and is in rolling fit with the top surfaces of the lower guide beams 111.

Having shown and described the fundamental principles and the principal features of the invention and its advantages, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents.

Claims (6)

1. Dislocation actuating mechanism of equipment is made old to brickwork for order about making about and make old assembly A and make old assembly B dislocation, its characterized in that: the staggered driving structure comprises a motor mounting seat, a double-shaft motor, two eccentric mounting seats, two push rods and two fixing seats, wherein two ends of the motor mounting seat are fixedly arranged between an old-making assembly A and an old-making assembly B respectively; one fixing seat is fixedly arranged on one side of the antique finishing assembly A, the other fixing seat is fixedly arranged on the other side of the antique finishing assembly B, one end of one push rod is hinged to the fixing seat on the antique finishing assembly A, the other end of the push rod is hinged to the eccentric mounting seat close to the antique finishing assembly A, one end of the other push rod is hinged to the fixing seat on the antique finishing assembly B, the other end of the other push rod is hinged to the eccentric mounting seat close to the antique finishing assembly B, and the phase difference between the hinged ends of the two push rods and the eccentric mounting seat.

2. The dislocation driving mechanism of the bricklaying antique equipment according to claim 1, characterized in that: the eccentric amount of the two eccentric mounting seats is the same.

3. The dislocation driving mechanism of the bricklaying antique equipment according to claim 1, characterized in that: and each eccentric mounting seat is respectively provided with a limiting sliding groove, and the other end of the push rod is fixedly mounted in the limiting sliding groove.

4. The dislocation driving mechanism of the bricklaying antique equipment according to claim 1, characterized in that: the top of the old-made inner frame of the old-made assembly A and the top of the old-made inner frame of the old-made assembly B are matched with the corresponding guide beams through first rollers, the left side and the right side of each guide beam are connected through a synchronization plate, and two ends of the motor mounting seat are fixedly arranged on the synchronization plate between the old-made assembly A and the old-made assembly B respectively; the inner frame comprises outer side plates positioned at the front end and the rear end and inner side plates respectively positioned within the outer side plates, wherein a plurality of buffer blocks are clamped between the outer side plates and the inner side plates, and the outer side plates are fixedly connected with the inner side plates.

5. The dislocation driving mechanism of the bricklaying antique equipment according to claim 4, characterized in that: the fixing seat is fixedly arranged on the inner side plate.

6. The dislocation driving mechanism of the bricklaying antique equipment according to claim 4, characterized in that: guide beams are horizontally arranged between the left and right synchronous plates respectively within the front and rear ends of the two old inner frames, first idler wheels which are in rolling fit with the top surfaces of the guide beams are arranged on the inner side plates, limiting beams are horizontally arranged at the left and right ends of the old inner frames respectively, the limiting beams are perpendicular to the guide beams, and second idler wheels which are in rolling fit with the side surfaces of the guide beams are arranged at the front and rear ends of the limiting beams respectively.

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