CN217755839U - Double-deck steering conveyor - Google Patents

Abstract

The utility model relates to a ceramic manufacture equipment, especially a double-deck conveyer that turns to, turn to conveying mechanism and big specification pottery including frame, crane, elevating system and small dimension ceramic layer and turn to conveying mechanism, small dimension pottery turn to conveying mechanism's input with big specification pottery turns to conveying mechanism's input and is located same vertical line, small dimension pottery turn to conveying mechanism's output with big specification pottery turns to conveying mechanism's output and is located same vertical line. Through setting up the crane and setting up the small dimension ceramic layer that arranges from top to bottom on the crane and turn to conveying mechanism and big specification pottery and turn to conveying mechanism, can remove the crane according to actual need during the use for small dimension ceramic layer turns to conveying mechanism or big specification pottery and turns to the highly corresponding of conveying mechanism and assembly line and arranges, and need not to turn to conveying mechanism on the better assembly line when switching ceramic manufacture of different specifications, and it is comparatively convenient to use.

Description

Double-deck steering conveyor

Technical Field

The utility model relates to a ceramic manufacture equipment, especially a double-deck steering conveyor.

Background

With the popularization of the assembly line technology, more and more ceramic production enterprises adopt the assembly line to carry out production, and in order to avoid the problem that the assembly line is too long to influence the arrangement of the ceramic production enterprises in a workshop, a steering conveyor is usually required to be arranged to realize steering of the assembly line. Because the required steering conveyor that turns to when carrying is different on the assembly line to small dimension (being long wide dimension relatively less) ceramic plate and big specification (being long wide dimension relatively great) ceramic plate, for example, all adopt the cylinder to turn to the conveyer, the conveyer that turns to that is used for small dimension ceramic plate requires the interval between the cylinder to be relatively less, the cylinder is arranged as closely as possible, and the conveyer that turns to that is used for big specification ceramic plate requires the circular arc section that the cylinder range formed to be as big as possible, the interval that each cylinder kept away from the arc center one side of above-mentioned circular arc section can increase certainly under this condition, consequently, the assembly line that has been used for ceramic plate production, when the ceramic plate production of different specifications of needs switching, often need change the steering conveyor on the assembly line, it is inconvenient to use.

In view of the above, the present application has made an intensive study on the above problems, and has made this invention.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a use comparatively convenient bilayer and turn to conveyer.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a double-deck conveyer that turns to, includes the frame, still includes vertical sliding connection be in crane in the frame, be used for the drive the gliding elevating system of crane and install respectively little specification ceramic layer on the crane turns to conveying mechanism and big specification pottery and turns to conveying mechanism, little specification pottery turn to conveying mechanism's input with big specification pottery turns to conveying mechanism's input is located same vertical line, little specification pottery turn to conveying mechanism's output with big specification pottery turns to conveying mechanism's output is located same vertical line.

As an improvement of the utility model, elevating system includes fixed connection first pair output shaft reduction gear, output shaft in the frame are in elevator motor on first pair output shaft reduction gear's the input shaft and respectively with the first transfer line that two output shafts of first pair output shaft reduction gear are connected one to one, each first transfer line is kept away from the one end of first pair output shaft reduction gear all is connected with the second pair output shaft reduction gear, two of each second pair output shaft reduction gear all be connected with on the output shaft with the second transfer line that first transfer line arranged perpendicularly, each the correspondence is kept away from to the second transfer line the one end of second pair output shaft reduction gear all is connected with the sprocket, the lower part of frame be provided with each the lower sprocket that the sprocket one-to-one was arranged, the mutual correspondence is arranged go up the sprocket with all around being equipped with the lift chain between the lower sprocket, the crane with lift chain fixed connection.

As an improvement of the utility model, each first transfer line and each all realize connecting through chain coupling between second transfer line and the dual output shaft reduction gear that corresponds.

As an improvement of the present invention, the small-sized ceramic steering mechanism includes a first support frame horizontally arranged, a first conveying motor and two first conveying rollers rotatably connected to the first support frame, the first support frame is provided with at least two sets of wheel sets, each of the wheel sets includes at least a plurality of guide wheels arranged in a circular arc shape, the axes of the guide wheels are vertically arranged, each of the wheel sets is arranged in a circular arc shape concentrically, two first conveying rollers and each of the wheel sets are located on the same horizontal plane, and two first conveying rollers are located on each of the wheel sets, each of the first conveying rollers is rotatably connected to a first conveying roller arranged in a one-to-one correspondence with each of the wheel sets, a first conveying belt is sleeved between the first conveying rollers, the first conveying belt abuts against each of the corresponding guide wheels, the guide wheels are arranged on one side of the arc center of the circular arc shape formed by the wheel sets, the first conveying motors are connected to at least one first conveying motor, and each of the first conveying belt is connected to at least one conveying motor.

As an improvement of the utility model, first support frame includes the outer circular arc roof beam and the interior circular arc roof beam and a plurality of bracing pieces that are convex one side and arrange that are mutual coaxial arrangement, each the one end of bracing piece all is in through bolt fixed connection on the outer circular arc roof beam, the other end all is in through bolt fixed connection on the interior circular arc roof beam, every all there is at least one through bolted connection on the bracing piece the leading wheel.

As an improvement of the utility model, big specification pottery turns to conveying mechanism includes the second support frame, be provided with direction of delivery mutually perpendicular's belt conveyor assembly and cylinder conveyor assembly on the second support frame, cylinder conveyor assembly includes a plurality of mutual parallel arrangement and is the horizontal straight line transport cylinder who arranges in proper order, adjacent two be formed with the clearance between the transport cylinder, belt conveyor assembly includes mutual parallel arrangement's second conveying roller and third conveying roller, is used for the drive second conveying roller and/or third conveying roller pivoted second conveying motor, two at least fixed connection be in second belt pulley, two at least fixed connection on the second conveying roller be in on the third conveying roller and respectively with each the third belt pulley that the second belt pulley one-to-one was arranged, around establishing at mutual correspondence the second belt pulley with first conveying belt between the third belt pulley, two at least respectively with each first carry the ejector pin that the one-to-arrangement and be used for driving each the jacking subassembly of ejector pin, cylinder conveyor assembly is located between the second conveying roller and the third conveying roller, each ejector pin all arranges horizontally, and each is located respectively between the transport ejector pin jacking subassembly.

As an improvement of the utility model, each the strap groove that is used for holding the correspondence first conveyor belt is all offered to the upside of ejector pin.

As an improvement of the utility model, the jacking subassembly is including being located the jacking frame, at least two of cylinder conveying component below rotate respectively to be connected just each other parallel arrangement's bull stick on the second support frame and be used for driving each the bull stick pivoted jacking motor, each the bull stick is all horizontally arranged, each all at least one branch of fixedly connected with on the pole body of bull stick, each the downside of ejector pin all fixedly connected with the pole setting of being connected of jacking frame fixed connection, at least two and each of fixedly connected with rotates the lifting rod of being connected a pair of branch on the jacking frame.

As an improvement of the utility model, each all the connecting rod of the mutual parallel arrangement of fixedly connected with on the bull stick, each all rotate on the connecting rod and be connected with same synchronizing bar, fixedly connected with pulls chain or flexible haulage rope on the synchronizing bar, be connected with the reduction gear just on jacking motor's the output shaft fixedly connected with the pull rod that the output shaft of reduction gear was arranged perpendicularly, perhaps fixedly connected with on jacking motor's the output shaft with the pull rod that jacking motor's output shaft was arranged perpendicularly, pull chain or flexible haulage rope keeps away from the one end of synchronizing bar is connected on the pull rod, just the pull rod with pull chain or the tie point of flexible haulage rope with the rotation axis dislocation arrangement of pull rod, the synchronizing bar be located on the rotation plane of pull rod or with the rotation plane parallel arrangement of pull rod.

As an improvement of the utility model, the belt conveyor assembly still include two respectively with the fourth conveying roller of the mutual parallel arrangement of second conveying roller, each the fourth conveying roller all is located the second conveying roller is kept away from one side of third conveying roller, just the second conveying roller is with two the fourth conveying roller is horizontal straight line and arranges in proper order, each all fixed cover is equipped with the fourth belt pulley that the mutual correspondence was arranged on the fourth conveying roller, and is corresponding to each other around being equipped with second conveyor belt between the fourth belt pulley.

Adopt above-mentioned scheme, the utility model discloses following beneficial effect has:

1. through setting up the crane and setting up the small dimension ceramic layer that arranges from top to bottom on the crane and turn to conveying mechanism and big specification pottery and turn to conveying mechanism, can remove the crane according to actual need during the use for small dimension ceramic layer turns to conveying mechanism or big specification pottery and turns to the highly corresponding of conveying mechanism and assembly line and arranges, and need not to turn to conveying mechanism on the better assembly line when switching ceramic manufacture of different specifications, and it is comparatively convenient to use.

2. Through set up two at least first conveying motor on small dimension pottery turns to conveying mechanism for conveying speed between each first conveyer belt can be different, and then can let the conveying speed of inner arc side be less than the conveying speed of outer arc side when turning to, and the ceramic plate is difficult for appearing deflecting.

3. The belt conveying assembly and the roller conveying assembly which are mutually vertical in conveying direction are arranged on the large-specification ceramic steering conveying mechanism, and the ejector rods are used for switching the ceramic plates on the two conveying assemblies.

4. Through set up the race groove on the ejector pin, drop from the ejector pin under the elastic force effect when helping avoiding first conveyor belt to be jack-up, guarantee the stability of carrying.

5. The flexible crank-link mechanism is formed by arranging the traction chain or the flexible traction rope for connection, and the safety performance of high equipment is facilitated.

Drawings

FIG. 1 is a schematic structural diagram of a double-deck turning conveyor in an embodiment, in which parts such as a housing of a motor are omitted;

FIG. 2 is a schematic structural diagram of the lifting frame and the steering conveying mechanism in the embodiment;

FIG. 3 is a schematic view of the structure shown in FIG. 2 from another perspective;

FIG. 4 is a schematic structural diagram of a small-sized ceramic steering conveying mechanism in an embodiment;

FIG. 5 is a schematic structural diagram of another view of the small-sized ceramic turn conveying mechanism in the embodiment;

FIG. 6 is a schematic structural diagram of a large-size ceramic steering conveying mechanism in an embodiment;

fig. 7 is a schematic structural diagram of the jacking assembly in the embodiment, and parts such as the jacking motor are omitted in the diagram.

The designations in the figures correspond to the following:

10-a frame; 20-a lifting frame;

30-a small-size ceramic steering conveying mechanism; 31-a first support frame;

32-a first conveyor motor; 33-a first conveyor roller;

34-a guide wheel; 35-a first delivery wheel;

36-a drive roller;

38-a drive wheel; 39-a tension roller;

40-large-size ceramic steering conveying mechanism; 41-a second support frame;

42-a belt conveyor assembly; 43-a roller conveyor assembly;

44-a transport drum; 45-drum conveyor motor;

50-a lifting mechanism; 51-a first double output shaft reducer;

52-a lifting motor; 53-a first transfer lever;

54-a second dual output shaft reducer; 55-a second transmission rod;

59-chain coupling;

61-an outer circular arc beam; 62-inner circular arc beam;

63-support bars; 64-a connecting rod;

65-a guide wheel; 71-a second conveyor roller;

72-a third conveyor roller; 73-a second conveyor motor;

74-a second pulley; 75-a third pulley;

77-ejector pin;

78-a fourth conveyor roller; 79-a fourth pulley;

80-a jacking assembly; 81-jacking frames;

82-a rotating rod; 83-a jacking motor;

84-strut; 85-upright stanchion;

86-a jacking rod; 87-a connecting rod;

88-a synchronization rod; 89-a reducer;

90-a pull rod.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1 to 7, the present embodiment provides a double-deck turning conveyor, which includes a frame 10, a lifting frame 20 vertically slidably connected to the frame 10, a lifting mechanism 50 for driving the lifting frame 20 to slide, and a small-sized ceramic layer turning conveying mechanism 30 and a large-sized ceramic turning conveying mechanism 40 respectively mounted on the lifting frame 20, wherein the small-sized ceramic layer turning conveying mechanism 30 and the large-sized ceramic turning conveying mechanism 40 can also be used independently.

The input end of the small-sized ceramic steering and conveying mechanism 30 and the input end of the large-sized ceramic steering and conveying mechanism 40 are located on the same vertical line, the output end of the small-sized ceramic steering and conveying mechanism 30 and the output end of the large-sized ceramic steering and conveying mechanism 40 are located on the same vertical line, and particularly in the embodiment, the small-sized ceramic steering and conveying mechanism 30 is located right above the large-sized ceramic steering and conveying mechanism 40. Therefore, when in use, the lifting frame 20 can be used for switching the positions of the small-size ceramic layer steering and conveying mechanism 40 and the large-size ceramic layer steering and conveying mechanism 30 in a vertical sliding mode, so that one steering and conveying mechanism is connected with other conveying devices of a production line.

The lifting mechanism 50 may be a conventional mechanism, such as a hydraulic cylinder lifting mechanism, in this embodiment, the lifting mechanism 50 includes a first dual output shaft reducer 51 fixedly connected to the frame 10, a lifting motor 52 having an output shaft connected to an input shaft of the first dual output shaft reducer 51, and first transmission rods 53 respectively connected to two output shafts of the first dual output shaft reducer 51 in a one-to-one manner, wherein one end of each first transmission rod 53, which is far away from the first dual output shaft reducer 51, is connected to a second dual output shaft reducer 54, two output shafts of each second dual output shaft reducer 54 are connected to second transmission rods 55, which are arranged perpendicular to the first transmission rods 53, one end of each second transmission rod 55, which is far away from the corresponding second dual output shaft reducer 54, is connected to an upper sprocket, in addition, a lower sprocket is arranged in one-to-one correspondence to each upper sprocket is arranged at the lower portion of the frame 10, a lifting chain is wound between the upper sprocket and the lower sprocket arranged in correspondence to each other, and the lifting frame 20 is simultaneously and fixedly connected to each lifting chain, so that the four chains 58 can be used to pull the lifting frame 20, thereby ensuring the smoothness of the lifting action.

Preferably, in this embodiment, each first transmission rod 53 and each second transmission rod 55 are connected to the corresponding dual output shaft speed reducer through a chain coupling 59, so that chain wheels are disposed at both ends of each transmission rod, and the input end and the output end of the transmission rod do not need to be distinguished during machining, which is convenient for machining and production, and the assembly process is not prone to error.

The small-size ceramic steering and conveying mechanism 30 comprises a first support frame 31 horizontally arranged on the lifting frame 20, a first conveying motor 32 arranged on the first support frame 31, and two first conveying rollers 33 which are respectively connected with the first support frame 31 in a rotating mode or fixedly connected with the first support frame 31, wherein the first support frame 31 comprises an outer arc beam 61 and an inner arc beam 62 which are coaxially arranged, and a plurality of supporting rods 63 which are arranged on one side of a circular arc shape, one end of each supporting rod 63 is fixedly connected to the outer arc beam 61 through a bolt, the other end of each supporting rod is fixedly connected to the inner arc beam 62 through a bolt, and therefore the position of each supporting rod 63 can be conveniently adjusted.

At least two sets of wheel sets are disposed on the first support frame 31, and four sets of wheel sets are taken as an example in the present embodiment for description. Each wheelset all includes to a plurality of leading wheels 34 that are circular arc and arrange, each leading wheel 34 in same wheelset is circular arc and arranges, specifically, the axis of each leading wheel 31 all vertically arranges, the circular arc concentric arrangement that each wheelset arranged, two first conveying rollers 33 and each wheelset all are located same horizontal plane, and two first conveying rollers 33 all are located the circular arc footpath that each wheelset arranged and forms, in this embodiment, each bracing piece 63 all is located the circular arc footpath that each wheelset arranged and forms, and all there is at least one leading wheel 34 through bolted connection on each bracing piece 63, two first conveying rollers 33 still mutually perpendicular arrange and are located the both ends of first support frame 31 respectively, then, each wheelset all is located between two first conveying rollers 33.

Each first conveying roller 33 is rotatably connected with a first conveying wheel 35 which is arranged corresponding to each wheel set one by one, namely, each first conveying roller 33 is provided with four first conveying wheels 35. First conveyor belts (not shown in the figure) are sleeved between the first conveyor wheels 35 corresponding to each other, each first conveyor belt abuts against one side (i.e. one side facing the outer circular arc beam 61) of each guide wheel 34 in the corresponding wheel set, which is far away from the arc center of the circular arc formed by the arrangement of the wheel set, so that the conveying sections of the first conveyor belts are arranged in an arc shape, the input end of the small-size ceramic steering conveying mechanism 30 is formed at the position of one first conveyor roller 33, and the output end of the small-size ceramic steering conveying mechanism 30 is formed at the position of the other first conveyor roller 33. When the ceramic plate conveying device is used, the ceramic plates are placed on the first conveying belts at the same time to be conveyed.

The number of the first conveying motors 32 is at least two, each first conveying motor 32 is in transmission connection with at least one first conveying belt, and each first conveying belt is in transmission connection with only one first conveying motor 32, in this embodiment, two first conveying motors 32 are taken as an example for illustration, two first conveying belts relatively close to the outer circular arc beam 61 are in transmission connection with one first conveying motor 32, and the other two first conveying belts are in transmission connection with the other first conveying motor 32, when in use, the rotating speed of the first conveying motor 32 in transmission connection with the two first conveying belts relatively close to the outer circular arc beam 61 is greater than that of the other first conveying motor 32, so that the conveying speed of the two first conveying belts relatively close to the outer circular arc beam 61 is greater than that of the other two first conveying belts, and thus it can be ensured that the ceramic plates are not easy to deflect when being conveyed in a turning direction.

The specific transmission connection structure between the first conveying motor 32 and the corresponding first conveying belt may be a conventional structure, for example, the first conveying motor 32 is directly connected with the corresponding first conveying wheel 35, preferably, in this embodiment, a support is fixedly connected to the lower side of the first support frame 31, drive rollers 36 connected with the output shafts of the first conveying motors 32 in a one-to-one manner are rotatably connected to the support, that is, two drive rollers 36 are provided, drive wheels 38 are fixedly sleeved on each drive roller, the number of the drive wheels is the same as that of the first conveying belts, and the first conveying belts are arranged in a one-to-one correspondence manner, specifically, two drive wheels 38 are connected to each drive roller 36, and each first conveying belt is simultaneously wound on the corresponding drive wheel 38, so as to implement the transmission connection between the first conveying motor 32 and the first conveying belt. The support is also rotatably connected with two tension rollers 39, the two tension rollers 39 are arranged, the two driving rollers 36 are positioned between the two tension rollers 39, and the horizontal positions of the two tension rollers 39 are higher than the horizontal positions of the two driving rollers 36 and lower than the horizontal positions of the support rods 63. In addition, first support frame 31 still includes the connecting rod 64 of fixed connection between outer arc roof beam 61 and inner arc roof beam 62, and connecting rod 64 has two at least, and specific quantity can be confirmed according to the actual demand, all is connected with on each connecting rod 64 in a rotating manner with each first conveyer belt one-to-one complex leading wheel 65, helps improving the transport stability of first conveyer belt like this.

The large-specification ceramic steering conveying mechanism 40 comprises a second supporting frame 41, wherein a belt conveying assembly 42 and a roller conveying assembly 43 which are perpendicular to each other in conveying direction are arranged on the second supporting frame 41, wherein one end, far away from the roller conveying assembly 43, of the belt conveying assembly 42 forms an input end of the large-specification ceramic steering conveying mechanism 40, and one end, far away from the belt conveying assembly 42, of the roller conveying assembly 43 forms an output end of the large-specification ceramic steering conveying mechanism 40.

The roller conveying assembly 43 comprises a plurality of conveying rollers 44 which are arranged in parallel and are arranged in a horizontal straight line in sequence, and a roller conveying motor 45 for driving each conveying roller 44 to rotate, a gap is formed between every two adjacent conveying rollers 44, and the upper side surfaces of the conveying rollers 44 form a conveying surface together.

The belt conveying assembly 42 includes a second conveying roller 71 and a third conveying roller 72 arranged in parallel, a second conveying motor 73 for driving the second conveying roller 71 and/or the third conveying roller 72 to rotate, at least two second belt pulleys 74 fixedly connected to the second conveying roller 71, at least two third belt pulleys 75 fixedly connected to the third conveying roller 72 and arranged corresponding to the second belt pulleys 74, respectively, a first conveying belt wound between the corresponding second belt pulleys 74 and third belt pulleys 75, at least two push rods 77 arranged corresponding to the first conveying belts 76, respectively, and a jacking assembly 80 for driving the push rods 77 to move up and down, wherein the specific transmission connection structure between the second conveying motor 73 and the second conveying roller 71 and the third conveying roller 72 may be a conventional structure, such as a transmission connection through a gear assembly, and in this embodiment, two second conveying motors 73 are connected to the second conveying roller 71 and the third conveying roller 72, respectively.

One end of the roller conveying assembly 43 is located between the second conveying roller 71 and the third conveying roller 73, and each second belt pulley 74 and each conveying roller 44 are arranged in a staggered mode to ensure that each first conveying belt is located between two adjacent conveying rollers 44, and the horizontal position of the upper end point of each second belt pulley 74 and each third belt pulley 75 is slightly lower than that of the upper end point of each conveying roller 44 to ensure that each first conveying belt is lower than the conveying surface of the roller conveying assembly 43 when not jacked up by the jacking rod 77.

Each of the lift pins 77 is disposed horizontally and in parallel with the conveying rollers 44, and each of the lift pins 77 is located in a space included in the corresponding first conveying belt, and since each of the first conveying belts is located between two adjacent conveying rollers 44, each of the lift pins 77 corresponding thereto is also located between two adjacent conveying rollers 44, respectively. When the ceramic plate conveying device is used, the jacking assemblies 80 are used for driving the ejector rods 77 to move upwards to jack the upper sections (namely conveying sections) of the first conveying belts, so that the upper ends of the first conveying belts are lifted from the lower sides of the conveying rollers 44 to be above the conveying rollers 44, the first conveying belts are stretched at the same time, then ceramic plates are pushed onto the first conveying belts to be conveyed to the positions right above the conveying rollers 44 under the driving of the first conveying belts, then the ejector rods 77 are reset, the first conveying belts are synchronously reset under the elastic action, the ceramic plates are placed on the conveying rollers 44, and finally the ceramic plates are conveyed out from the output ends under the conveying action of the conveying rollers 44 to realize steering conveying.

Preferably, the upper side of each top bar 77 is provided with a belt groove for accommodating the corresponding first conveying belt, so that the first conveying belt can be prevented from sliding off the top bars 77 after being jacked up.

The jacking assembly 80 may adopt conventional assemblies, such as a jacking cylinder, in this embodiment, the jacking assembly 80 includes a jacking frame 81 located below the roller conveying assembly 43, at least two rotating rods 82 rotatably connected to the second supporting frame 41 respectively and arranged in parallel, and a lifting motor 83 for driving each rotating rod 82 to rotate, in this embodiment, two rotating rods 82 are taken as an example for illustration, each rotating rod 82 is arranged horizontally, at least one supporting rod 84 is fixedly connected to a rod body of each rotating rod 82, each supporting rod 84 is arranged in parallel, the jacking frame 81 is located above each rotating rod 82, a connecting upright rod 85 fixedly connected to the jacking frame 81 is fixedly connected to a lower side of each jacking rod 77, and at least two jacking rods 86 rotatably connected to each supporting rod 84 in a one-to-one manner are fixedly connected to the jacking frame 81, so that the jacking rods 86 can be driven to move up and down by reciprocating the rotating rods 82 to drive each jacking rod 77 to move up and down. The jacking frame 81 may be an integral frame or a separate frame.

The specific transmission connection structure between the lifting motor 83 and the rotating rod 82 can be a conventional structure, for example, the output shaft of the lifting motor 83 is directly connected with the rotating rod 82, or transmission connection is realized through a belt assembly, a chain assembly or a gear assembly, and the like, preferably, in this embodiment, connecting rods 87 arranged in parallel are fixedly connected to the rotating rods 82, the connecting rods 87 are located on the same vertical plane, and the connecting rods 87 are rotatably connected to the same synchronizing rod 88, so that the synchronizing rod 88 can be moved to drive the rotating rods 82 to synchronously rotate. The synchronizing rod 88 is located above each rotating rod 82, a traction chain or a flexible traction rope (not shown) is fixedly connected to the synchronizing rod 88, a speed reducer 89 is connected to the output shaft of the elevator motor 83, and a pull rod 90 arranged perpendicular to the output shaft of the speed reducer 89 is fixedly connected to the output shaft of the speed reducer 89, but of course, the pull rod 90 arranged perpendicular to the output shaft of the elevator motor 83 may be directly fixedly connected to the output shaft of the elevator motor 83, that is, the speed reducer 89 may not be provided, and the case where the speed reducer 89 is provided is described in this embodiment. When the crank-link mechanism is used, the lifting motor 83 drives the pull rod 90 to rotate, the synchronous rod 88 is pulled to move, and the rotating rods 82 are driven to synchronously rotate, so that one end of each support rod 84, far away from the corresponding rotating rod 82, swings upwards, and finally drives each ejector rod 77 to move upwards; when each ejector pin 77 needs to move downwards, the lifting motor 83 drives the pull rod 90 to continue rotating, so that the traction chain or the flexible traction rope is in a loose state, each ejector pin 77 resets under the action of gravity, and simultaneously drives the synchronous rod 88 to reset, so that the energy is saved, and when the ejector pin 77 moves downwards, the action of the pull rod 90 is not influenced, and the safety is relatively high.

Preferably, in this embodiment, the belt conveying assembly 42 further includes two fourth conveying rollers 78 respectively arranged in parallel with the second conveying roller 71, each fourth conveying roller 78 is located on one side of the second conveying roller 71 away from the third conveying roller 72, the second conveying roller 71 and the two fourth conveying rollers 78 are sequentially arranged in a horizontal straight line, a fourth belt pulley 79 arranged in correspondence to each other is fixedly sleeved on each fourth conveying roller 78, and a second conveying belt (not shown in the figure) is wound between the corresponding fourth belt pulleys. Thus, in use, the ceramic plate may be pushed onto the second conveyor belt and then transported to the first conveyor belt by the second conveyor belt.

The present invention has been described in detail with reference to the accompanying drawings, but the embodiments of the present invention are not limited to the above embodiments, and those skilled in the art can make various modifications to the present invention according to the prior art, and these all belong to the protection scope of the present invention.

Claims (10)

1. The utility model provides a double-deck conveyer that turns to, includes the frame, its characterized in that still includes vertical sliding connection and is in crane in the frame, be used for the drive the gliding elevating system of crane and install respectively little specification pottery on the crane turns to conveying mechanism and big specification pottery and turns to conveying mechanism, little specification pottery turn to conveying mechanism's input with big specification pottery turns to conveying mechanism's input and is located same vertical line, little specification pottery turn to conveying mechanism's output with big specification pottery turns to conveying mechanism's output and is located same vertical line.

2. The double-deck steering conveyor according to claim 1, wherein the lifting mechanism comprises a first double-output shaft reducer fixedly connected to the frame, a lifting motor having an output shaft connected to an input shaft of the first double-output shaft reducer, and first transmission rods respectively connected to two output shafts of the first double-output shaft reducer in a one-to-one manner, one end of each first transmission rod, which is far away from the first double-output shaft reducer, is connected to a second double-output shaft reducer, two output shafts of each second double-output shaft reducer are connected to a second transmission rod which is arranged perpendicular to the first transmission rod, one end of each second transmission rod, which is far away from the corresponding second double-output shaft reducer, is connected to an upper sprocket, a lower sprocket is arranged at a lower portion of the frame in a one-to-one manner in correspondence to each upper sprocket, a lifting chain is wound between the upper sprocket and the lower sprocket which are arranged in a one-to-one manner, and the lifting frame is fixedly connected to the lifting chain.

3. The double-deck steering conveyor according to claim 2, wherein each of said first drive links and each of said second drive links are coupled to a corresponding dual output shaft reducer by a chain coupling.

4. The double-deck steering conveyor according to any one of claims 1 to 3, wherein the small-format ceramic steering mechanism comprises a first support frame arranged horizontally, a first conveying motor arranged on the first support frame, and two first conveying rollers rotatably connected to the first support frame, the first support frame is provided with at least two sets of wheel sets, each set of wheel sets comprises at least a plurality of guide wheels arranged in an arc shape, axes of the guide wheels are arranged vertically, the wheel sets are arranged concentrically in the arc shape, the two first conveying rollers and the wheel sets are located on the same horizontal plane, the two first conveying rollers are located in a radial direction of the arc shape formed by the arrangement of the wheel sets, the first conveying rollers are rotatably connected to the first conveying rollers, the first conveying rollers are arranged in one-to-one correspondence with the wheel sets, first conveying belts are sleeved between the first conveying rollers corresponding to each other, the first conveying belts abut against the guide wheels in the corresponding wheel sets on a side away from the arc center of the arc shape formed by the arrangement of the wheel sets, the first conveying motors are each at least two first conveying belts, and each first conveying motor is connected to at least one conveying belt.

5. The double-deck steering conveyor according to claim 4, wherein the first support frame includes an outer arc beam and an inner arc beam which are coaxially arranged with each other, and a plurality of support bars arranged in a side of an arc shape, one end of each of the support bars is fixedly connected to the outer arc beam by a bolt, the other end thereof is fixedly connected to the inner arc beam by a bolt, and at least one of the guide wheels is connected to each of the support bars by a bolt.

6. The double-deck steering conveyor according to any one of claims 1 to 3, wherein the large-size ceramic steering conveyor mechanism comprises a second support frame, a belt conveying assembly and a roller conveying assembly which are perpendicular to each other in conveying direction are arranged on the second support frame, the roller conveying assembly comprises a plurality of conveying rollers which are arranged in parallel and are sequentially arranged in a horizontal straight line, a gap is formed between every two adjacent conveying rollers, the belt conveying assembly comprises a second conveying roller and a third conveying roller which are arranged in parallel, a second conveying motor for driving the second conveying roller and/or the third conveying roller to rotate, at least two second belt pulleys fixedly connected to the second conveying roller, at least two third belt pulleys fixedly connected to the third conveying roller and respectively arranged in one-to-one correspondence with the second belt pulleys, a first conveying belt wound between the second belt pulleys and the third belt pulleys which are arranged in one-to-one correspondence with the first conveying belts, and at least two ejector rods for driving the ejector rods to move up and down, the jacking roller conveying assembly is arranged between the second conveying roller and the third conveying roller, and the jacking roller conveying rollers are respectively arranged between the two adjacent ejector rods.

7. The double-deck steering conveyor of claim 6, wherein each of the carrier rods has a belt groove formed in an upper side thereof for receiving the corresponding first conveyor belt.

8. The double-deck steering conveyor according to claim 6, wherein said jacking assembly comprises a jacking frame located below said roller conveying assembly, at least two rotating rods rotatably connected to said second supporting frame respectively and arranged in parallel with each other, and a jacking motor for driving each rotating rod to rotate, each rotating rod is arranged horizontally, at least one supporting rod is fixedly connected to a rod body of each rotating rod, a connecting vertical rod fixedly connected to said jacking frame is fixedly connected to a lower side of each top rod, and at least two jacking rods rotatably connected to each supporting rod in a one-to-one manner are fixedly connected to said jacking frame.

9. The double-deck steering conveyor according to claim 8, wherein each of the rotating rods is fixedly connected with a connecting rod arranged in parallel to each other, each of the connecting rods is rotatably connected with a same synchronizing rod, the synchronizing rod is fixedly connected with a traction chain or a flexible traction rope, the output shaft of the jacking motor is connected with a speed reducer, the output shaft of the speed reducer is fixedly connected with a pull rod arranged perpendicular to the output shaft of the speed reducer, or the output shaft of the jacking motor is fixedly connected with a pull rod arranged perpendicular to the output shaft of the jacking motor, one end of the traction chain or the flexible traction rope, which is far away from the synchronizing rod, is connected to the pull rod, a connection point of the pull rod with the traction chain or the flexible traction rope is arranged in a staggered manner with a rotation axis of the pull rod, and the synchronizing rod is located on a rotation surface of the pull rod or arranged in parallel to a rotation surface of the pull rod.

10. The double-deck steering conveyor according to claim 6, wherein the belt conveying assembly further comprises two fourth conveying rollers respectively arranged in parallel with the second conveying rollers, each fourth conveying roller is located on a side of the second conveying roller away from the third conveying roller, the second conveying roller and the two fourth conveying rollers are sequentially arranged in a horizontal straight line, each fourth conveying roller is fixedly sleeved with a corresponding fourth belt pulley, and a second conveying belt is wound between the corresponding fourth belt pulleys.

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