CN215316771U - Automatic processing production line for three-way pipe assembly of infusion apparatus - Google Patents
Automatic processing production line for three-way pipe assembly of infusion apparatus Download PDFInfo
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- CN215316771U CN215316771U CN202120539093.0U CN202120539093U CN215316771U CN 215316771 U CN215316771 U CN 215316771U CN 202120539093 U CN202120539093 U CN 202120539093U CN 215316771 U CN215316771 U CN 215316771U
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Abstract
The utility model relates to the technical field of three-way pipe pretreatment devices, in particular to an automatic treatment production line for assembling a three-way pipe of an infusion apparatus. The automatic processing production line for the three-way pipe assembly of the infusion apparatus comprises a rack, a three-way pipe feeding device, a three-way pipe taking and transferring device, a three-way pipe rotating and righting device and a three-way pipe overturning device, wherein the three-way pipe feeding device and the three-way pipe rotating and righting device are arranged on the rack in sequence, the three-way pipe taking and transferring device is arranged on a rack body above the three-way pipe feeding device and the three-way pipe rotating and righting device, and the three-way pipe overturning device is arranged on a rack body above the three-way pipe rotating and righting device. The three-way pipe three-way feeding device can feed a large amount of materials at one time, the three-way pipe is convenient to arrange in the feeding process, and the continuity of the feeding, arranging, grabbing and moving processes is high. The three-way pipe three-way device is compact in structural design, simple to operate, coherent in action and high in assembly precision, and greatly improves the assembly efficiency of the three-way pipe and the short pipe of the infusion apparatus.
Description
Technical Field
The utility model relates to the technical field of three-way pipe pretreatment devices, in particular to an automatic treatment production line for assembling a three-way pipe of an infusion apparatus.
Background
An infusion apparatus is a medical apparatus which is quite commonly used at present and is mainly used for carrying out intravenous infusion on patients. The infusion apparatus is a disposable medical product, and the demand of the infusion apparatus is very large, so that higher productivity and production efficiency are required. The pipeline of the infusion apparatus comprises a three-way pipe, a short pipe and a long pipe.
During the preparation process of the infusion apparatus, short tubes of the infusion apparatus and the three-way tube need to be assembled, the three-way tube needs to be preprocessed before assembly, the three-way tube is arranged in order and then moved integrally, and one port of the three-way tube is finally bonded and assembled with the short tubes of the infusion apparatus through operations such as rotation, overturning and the like. The prior pretreatment system for assembling the three-way pipe of the infusion apparatus has a plurality of defects in actual use, such as: (1) the quantity of one-time feeding is small, if the feeding quantity is increased, the quantity of conveying equipment is not increased, the input cost is high, but the feeding efficiency is low, the three-way pipe is inconvenient to arrange before feeding, and the continuity of the grabbing and moving process after arranging is poor; (2) the head of the three-way pipe in the efficient three-way pipe feeding device faces upwards, the lower end of the three-way pipe is a pipe end required to be assembled with the short pipe of the infusion apparatus, and the third pipe section positioned on the side face of the three-way pipe is arranged towards the short pipe of the infusion apparatus, so that the three-way pipe is favorably and stably conveyed, the side face is prevented from rotating and moving under the influence of gravity, but the third pipe section is easy to deflect when the three-way pipe conveyed in the way is assembled with the short pipe of the infusion apparatus; (3) the three-way pipe clamping and assembling device has the advantages of large structural design, complex operation procedures and poor operation precision, and influences the assembling efficiency of the three-way pipe and the short pipe of the infusion apparatus.
SUMMERY OF THE UTILITY MODEL
The utility model aims to provide an automatic processing production line for assembling a three-way pipe of an infusion apparatus, which overcomes the defects of the prior art, can meet the requirement of one-time large-scale feeding without adding conveying equipment, is convenient to arrange in the feeding process of the three-way pipe, has strong continuity of the processes of feeding, arranging, grabbing, moving and transporting to the next process, and greatly improves the feeding efficiency of the three-way pipe; the loaded three-way pipe is rotated, so that the third pipe section of the three-way pipe is not subjected to deflection and lateral movement in the subsequent manufacturing process; the three-way pipe three-way device is compact in structural design, simple to operate, coherent in action and high in assembly precision, and greatly improves the assembly efficiency of the three-way pipe and the short pipe of the infusion apparatus.
The technical scheme adopted by the utility model for solving the technical problems is as follows:
an automatic processing production line for assembling three-way pipes of infusion sets comprises a rack, and a three-way pipe feeding device, a three-way pipe taking and transferring device, a three-way pipe rotating and righting device and a three-way pipe overturning device which are arranged on the rack, wherein the three-way pipe feeding device and the three-way pipe rotating and righting device are sequentially arranged on the rack;
during the use, arrange the three-way pipe into one row through three-way pipe loading attachment, get material transfer device with the three-way pipe that the alignment is row through the three-way pipe and transfer to the rotatory normal position device of three-way pipe from three-way pipe loading attachment, the three-way pipe rotates 180 in the rotatory normal position device of three-way pipe, then snatch the three-way pipe through three-way pipe turning device, to overturning 90 with the three-way pipe, lift from vertical state for the horizontality, the one end that the three-way pipe needs to bond the equipment with the transfusion system nozzle stub is close to the transfusion system nozzle stub this moment, the third pipeline section of three-way pipe lateral wall is down, can not take place the inclined to heavy side to move under three-way pipe turning device's clamping effect and play self gravity effect, it can to move the three-way pipe to bond with the nozzle stub that has scribbled glue through three-way pipe turning device.
Furthermore, the three-way pipe feeding device comprises a three-way pipe conveying mechanism, a three-way pipe temporary storage mechanism positioned at the tail end of the three-way pipe conveying mechanism and a staggered reciprocating movement mechanism for moving the three-way pipe temporary storage mechanism, wherein P conveying channels for conveying the three-way pipes are arranged on the three-way pipe conveying mechanism, and n multiplied by P three-way pipe accommodating openings are formed in the three-way pipe temporary storage mechanism; when the three-way pipe temporary storage mechanism is used, the P conveying channels are fully filled with the three-way pipes, the P conveying channels are correspondingly aligned with the P three-way pipe accommodating openings one by one, the three-way pipes which are closest to the three-way pipe temporary storage mechanism enter the three-way pipe accommodating openings aligned with the P conveying channels, then the three-way pipe temporary storage mechanism is moved integrally by the staggered reciprocating movement mechanism, the P conveying channels are aligned with the other P three-way pipe accommodating openings one by one, the three-way pipes which are closest to the three-way pipe temporary storage mechanism enter the corresponding three-way pipe accommodating openings, the circulation is performed for n times, one three-way pipe is accommodated in all the three-way pipe accommodating openings, a large amount of disposable feeding can be met without increasing conveying equipment, the cost is saved, and the feeding rate of the three-way pipes is increased.
Further, the three-way pipe conveying mechanism is arranged on the rack and comprises a first bottom plate and a conveying channel arranged at the upper end of the first bottom plate at intervals; the main body of the conveying channel is of a rectangular structure, a T-shaped through hole is formed in the main body of the conveying channel along the length direction, the upper end of the T-shaped through hole is communicated with the upper end face of the main body of the conveying channel, the head of the three-way pipe is positioned in an opening at the upper end of the T-shaped through hole, one end of the three-way pipe, to be assembled with the short pipe of the infusion apparatus, is inserted into an opening at the lower end of the T-shaped through hole, and the other end of the three-way pipe is positioned in the T-shaped through hole and extends to the direction of the temporary storage mechanism of the three-way pipe; the first bottom plate and/or the conveying channel are arranged in a downward inclination mode towards the direction of the three-way pipe temporary storage mechanism, the three-way pipe can slide downwards under the action of gravity in the placement direction of the three-way pipe, and the position of the three-way pipe stably and smoothly enters the three-way pipe accommodating opening of the three-way pipe temporary storage mechanism in the downward sliding process. Furthermore, the lower end of the first bottom plate is connected with the vibrating motor, so that the three-way pipe can smoothly slide down to the three-way pipe accommodating opening of the three-way pipe temporary storage mechanism from the T-shaped through hole.
Further, the three-way pipe temporary storage mechanism comprises a base, a first slide rail, a first slide block, a lower support plate, side support plates, an upper support plate and a three-way pipe containing plate, wherein the base is installed on the rack, the first slide rail is arranged on the upper end face of the base, the direction of the first slide rail is perpendicular to the direction of the conveying channel, the first slide block is installed on the first slide rail, the upper end face of the first slide block is connected with the lower end face of the lower support plate, the side support plates are arranged at two ends of the lower support plate, the upper support plate is arranged between the upper ends of the side support plates, the three-way pipe containing plate is installed on the upper end face of the upper support plate, the three-way pipe containing plate is perpendicular to the direction of the conveying channel, three-way pipe containing openings are formed in the three-way pipe containing plate at intervals, and when the first slide block slides along the first slide rail under the action of external force, the three-way pipe containing plate is displaced, so that the three-way pipe containing openings are divided into n batches, Each batch of P pieces of the three-way pipe is aligned with the conveying channel, and the shape of the three-way pipe accommodating opening is based on that the three-way pipe does not move in the position of the three-way pipe accommodating opening and is conveniently grabbed by a three-way pipe clamping jaw on the three-way pipe taking and transferring device; the staggered reciprocating moving mechanism comprises a first connecting plate, a first air cylinder mounting plate, a second air cylinder and a second air cylinder mounting plate, wherein the first air cylinder mounting plate and the second air cylinder mounting plate are arranged on the upper end surface of the base at intervals along the length direction of the base, the first air cylinder is mounted on the first air cylinder mounting plate, the second air cylinder which is symmetrically arranged with the first air cylinder is mounted on the second air cylinder mounting plate, the first connecting plate is positioned in the middle of the first air cylinder mounting plate and the second air cylinder mounting plate, one end of the first connecting plate is fixed on the lower supporting plate or the upper supporting plate, two side surfaces of the other end of the first connecting plate are respectively connected with the first air cylinder and the second air cylinder, the second air cylinder contracts when the first air cylinder contracts, the second air cylinder extends out when the first air cylinder contracts, the first connecting plate is driven to move when the first air cylinder and the second air cylinder act, and the whole three-way pipe temporary storage mechanism is driven to move through the first connecting plate, and ensure the three-way pipe temporary storage mechanism to move stably.
Further, the three-way pipe taking and transferring device comprises a clamping assembly, a longitudinal moving driving assembly, a sliding assembly and a horizontal moving driving assembly, wherein the longitudinal moving driving assembly is connected with the clamping assembly and used for moving the clamping assembly up and down; during the use, the clamping assembly is used for pressing from the three-way pipe temporary storage mechanism and getting the three-way pipe, and longitudinal movement drive assembly is used for driving the clamping assembly to reciprocate, and horizontal movement drive assembly is used for promoting the slip subassembly, and then drives longitudinal movement drive assembly and clamping assembly translation.
Furthermore, the clamping assembly comprises an air claw mounting plate, n multiplied by P parallel air claws arranged on the air claw mounting plate at intervals and a group of three-way pipe clamping jaws arranged on each parallel air claw, wherein the claw ends of the parallel air claws face downwards, each group of three-way pipe clamping jaws comprises two L-shaped three-way pipe clamping jaws which are symmetrically arranged, and the positions of the three-way pipe clamping jaws correspond to the positions of the accommodating openings of the three-way pipes; semicircular openings are symmetrically arranged at the contact end of the L-shaped three-way pipe clamping jaw, the parallel gas claw is opened and closed to drive the three-way pipe clamping jaw to be opened and closed, and the semicircular openings are clamped below the head of the three-way pipe when the three-way pipe clamping jaw is closed;
the longitudinal movement driving assembly comprises two side connecting plates, two horizontal supporting plates, a longitudinal movement cylinder, a first guide shaft and a first linear bearing, the two side connecting plates are arranged at intervals, the upper end of each side connecting plate is connected with the sliding assembly, the horizontal supporting plates are fixed between the lower ends of the side connecting plates, the longitudinal movement cylinder is longitudinally arranged on each horizontal supporting plate, the tail end of a piston rod of each longitudinal movement cylinder penetrates through the corresponding horizontal supporting plate downwards and is connected with the upper end face of the corresponding gas claw mounting plate, first linear bearings are arranged on the horizontal supporting plates on the two sides of the longitudinal movement cylinder, the first guide shaft is arranged in the first linear bearing, the lower end of the first guide shaft is connected with the upper end face of the corresponding gas claw mounting plate, the clamping assembly is driven to move up and down by the extension of the longitudinal movement cylinder, and the first guide shaft moves in the first linear bearing along with the extension of the longitudinal movement cylinder to play a role in stable guiding;
the sliding assembly comprises a second sliding rail, a second sliding block and a sliding seat, the second sliding rail is arranged on the rack, the second sliding block is arranged on the second sliding rail, the upper end face of the second sliding block is fixedly connected with the lower end face of the sliding seat, and the sliding seat is connected with the upper end of a side connecting plate of the longitudinal movement driving assembly;
the horizontal movement driving assembly comprises a first translation cylinder, a first translation cylinder mounting plate, a limiting piece and a limiting piece mounting plate, the first translation cylinder mounting plate is mounted on the rack, the first translation cylinder is mounted on the first translation cylinder mounting plate, the tail end of a piston rod of the first translation cylinder is connected with the sliding seat, the sliding seat is driven by the first translation cylinder to move along the setting direction of the second sliding rail in a telescopic mode, the limiting piece mounting plates are mounted on the rack on two sides of the first translation cylinder mounting plate, and the limiting piece for limiting the sliding seat is mounted on the limiting piece mounting plate; the telescopic driving of the first translation cylinder drives the sliding seat and the second sliding block to move along the sliding rail, so that the longitudinal movement driving assembly and the clamping assembly are enabled to translate, and the limiting part is used for limiting the movement of the sliding seat.
Furthermore, the three-way pipe rotating and righting device comprises a second bottom plate, a first translation driving mechanism arranged at the upper end of the second bottom plate and a three-way pipe rotating and righting mechanism connected with the first translation driving mechanism, the three-way pipe rotating and righting mechanism comprises a shell, a rotating shaft, three-way pipe seats and rotating shaft rotating and driving assemblies, n × P strips are arranged at intervals on the rotating shaft, the rotating shaft is installed in the shell through a bearing, the upper end of the rotating shaft penetrates out of the shell, the three-way pipe seats are installed at the upper end of the rotating shaft, and shaft sections of the rotating shaft, which are located inside the shell, are connected with the rotating shaft rotating and driving assemblies; during the use, at first through first translation actuating mechanism with the whole material transfer device that gets of three-way pipe rotation normal position mechanism to the three-way pipe and be used for snatching the centre gripping subassembly removal of three-way pipe, the centre gripping subassembly is unified to be put into the three-way pipe seat of three-way pipe rotation normal position mechanism with the three-way pipe, the three-way pipe is injectd at three-way pipe seat intermediate position, can not take place the side and move, translation actuating mechanism resets, drive all pivots through pivot rotation actuating mechanism and rotate 180 along circumference in step, make the third pipeline section that is located on the three-way pipe lateral wall rotatory to transfusion system nozzle stub dorsad, in order to do benefit to the equipment with three-way pipe and transfusion system nozzle stub in the follow-up process.
Furthermore, the first translation driving mechanism comprises a third slide rail, a third slide block, a third air cylinder and a second connecting plate, the third slide rail is mounted on the second bottom plate, the third slide rail is provided with the third slide block, the upper end surface of the third slide block is fixedly connected with the lower end surface of the shell, the third air cylinder is mounted on the second bottom plate, the tail end of a piston rod of the third air cylinder is connected with the second connecting plate, the second connecting plate is fixed on the shell, the third air cylinder stretches and retracts to drive the second connecting plate to move back and forth, and further the three-way pipe connected with the second connecting plate is pulled to rotate and righting the three-way pipe to translate, so that the three-way pipe rotation righting mechanism can be moved to be close to or far away from a clamping component used for grabbing the three-way pipe in the three-way pipe material taking and transferring device; the lower end surface of the shell is provided with a first contact block, the lower end surface of the second bottom plate is provided with a second contact block, and when the first contact block is in contact with the second contact block, the first translation driving mechanism is indicated to finish resetting;
the three-way pipe seat comprises an insert block, a side block arranged on one side of the upper end face of the insert block, a first shaft clamping plate arranged on the lower end face of the insert block and a second shaft clamping plate connected with the first shaft clamping plate through a fastener, wherein the first shaft clamping plate and the second shaft clamping plate are clamped at the upper end of a rotating shaft, the insert block is provided with an insertion hole, the side block is provided with a limiting groove, the size of the insertion hole is matched with that of one end of the three-way pipe, which needs to be connected with a short pipe of an infusion apparatus, the end of the three-way pipe, which needs to be connected with the short pipe of the infusion apparatus, is inserted into the insertion hole, the arc surface shape of the limiting groove is matched with the arc surface of a pipe section on the side face of the three-way pipe, and the pipe section on the side wall of the three-way pipe is limited in the limiting groove, so that the three-way pipe is prevented from circumferential movement in the rotating and righting process;
the rotating shaft rotation driving assembly comprises a gear, a fourth air cylinder, an air cylinder seat plate, a third connecting plate, a fourth sliding block, a fifth sliding block, a sliding block mounting plate, a fourth sliding rail and a rack, the gear is sleeved on the outer wall of the rotating shaft, the air cylinder seat plate is arranged on the inner wall of the shell, the fourth air cylinder is arranged in the inner cavity of the shell through the air cylinder seat plate, the arrangement direction of the fourth air cylinder is vertical to the direction of the rotating shaft, the tail end of a piston rod of the fourth air cylinder is connected with the starting end of the third connecting plate, a cylinder barrel of the fourth air cylinder is connected with the fourth sliding block through the sliding block mounting plate, the fifth sliding block is arranged on one side far away from the cylinder barrel of the fourth air cylinder at intervals through another sliding block mounting plate, the fourth sliding rail sequentially penetrates through the fourth sliding block and the fifth sliding block, the fourth sliding rail is fixedly connected with the rack, the arrangement directions of the fourth sliding rail and the rack are the same and are vertical to the rotating shaft, and teeth of the rack are meshed with the gears on the outer walls of all the rotating shaft, the tail end of the third connecting plate is fixedly connected with a fourth sliding rail and/or a rack, in the rotating shaft rotation driving assembly, the fourth sliding block and the fifth sliding block keep constant in position, under the telescopic driving of the fourth cylinder, the fourth sliding rail and the rack are pulled by the third connecting plate to translate, and the gear rotates in the translation process of the rack to drive the rotating shaft to rotate 180 degrees, so that the third pipe section on the side wall of the three-way pipe rotates to be opposite to the short pipe of the infusion apparatus, and the three-way pipe and the short pipe of the infusion apparatus can be assembled in the subsequent process; the upper end face of the fourth sliding rail and/or the rack is provided with a buffer positioning block, the height of the buffer positioning block is in clearance fit with the distance from the fourth sliding rail or the rack to the top face of the shell, and the buffer positioning block is mainly used for determining the meshing position of the rack and the gear in the installation process of the device; cylinder telescopic positioning blocks are arranged on the lower end face of the fourth sliding rail and/or the rack at intervals, when the fourth cylinder extends out, the tail end of a piston rod of the fourth cylinder is in contact with one cylinder telescopic positioning block, which indicates that 180-degree rotation is completed, and when the fourth cylinder contracts, the fourth sliding block is in contact with the other cylinder telescopic positioning block, which indicates that 180-degree rotation is completed; a long hole through which the rack and the fourth sliding rail can pass is formed in the side face of the shell; the side plates of the shell are fixed through fasteners.
Furthermore, the three-way pipe overturning device comprises a second translation driving mechanism, a longitudinal translation driving mechanism, an overturning driving mechanism and a material taking mechanism, wherein the second translation driving mechanism is arranged on the rack and connected with the longitudinal translation driving mechanism;
the second translation driving mechanism is used for driving the longitudinal movement driving mechanism, the overturning driving mechanism and the material taking mechanism to integrally translate, the longitudinal movement driving mechanism is used for driving the overturning driving mechanism and the material taking mechanism to lift, the overturning driving mechanism is used for driving the material taking mechanism to overturn for 90 degrees, and the material taking mechanism is used for grabbing the three-way pipe;
during the use, drive the extracting mechanism through indulging moving actuating mechanism and move down, extracting mechanism presss from both sides and gets the three-way pipe, indulge move actuating mechanism and drive extracting mechanism and move up, upset actuating mechanism drive extracting mechanism produces 90 rotations for the one end level that the three-way pipe needs to assemble with the transfusion system nozzle stub is towards the transfusion system nozzle stub, then moves the three-way pipe to the transfusion system nozzle stub through second translation actuating mechanism, finally bonds the three-way pipe and the transfusion system nozzle stub that has scribbled the glue and assembles together.
Furthermore, the second translation driving mechanism comprises fifth slide rails, sixth slide blocks, a slide table plate, a translation cylinder connecting plate, a second translation cylinder and a second translation cylinder mounting plate, wherein the fifth slide rails are at least arranged in parallel and at intervals, the fifth slide rails are fixed on the rack, the fifth slide rails are provided with the sixth slide blocks in a matched manner, the slide table plate is fixed between the upper end surfaces of the sixth slide blocks, the translation cylinder connecting plate is arranged on the slide table plate, the second translation cylinder mounting plate is fixed on the rack, the second translation cylinder is mounted on the second translation cylinder mounting plate, the tail end of a piston rod of the second translation cylinder is connected with the translation cylinder connecting plate, and when the second translation cylinder is stretched, the slide table plate is pulled or pushed to translate along the direction of the slide rails;
the longitudinal movement driving mechanism comprises a vertical plate, a longitudinal movement air cylinder seat plate, a longitudinal movement air cylinder, a longitudinal movement jacking cylinder, a limiting jacking head, a second linear bearing, a second guide shaft, a guide shaft rear connecting plate and a first lifting connecting plate, wherein the vertical plate is arranged on the lower end surface of the sliding plate at intervals, the longitudinal movement air cylinder seat plate is fixed between the lower end surfaces of the vertical plates, the longitudinal movement air cylinder is arranged on the longitudinal movement air cylinder seat plate, the tail end of a piston rod of the longitudinal movement air cylinder downwards penetrates through the longitudinal movement air cylinder seat plate and then is connected with the first lifting connecting plate, the longitudinal movement jacking cylinders are arranged on the longitudinal movement air cylinder seat plates on the two sides of the longitudinal movement air cylinder, a jacking rod of each longitudinal movement jacking cylinder downwards extends out of the longitudinal movement air cylinder seat plate, the limiting jacking head matched with a jacking rod of each longitudinal movement jacking cylinder is arranged on the upper end surface of the first lifting connecting plate, the second linear bearings are respectively arranged in the second linear bearings, and the upper ends of the second guide shafts upwards penetrate through the sliding plate, a guide shaft rear connecting plate is connected between the upper end surfaces of the second guide shafts, the lower ends of the second guide shafts are connected with a first lifting connecting plate which is horizontally arranged, the longitudinal moving cylinder stretches and retracts to drive the first lifting connecting plate to lift, the longitudinal moving jacking cylinder is used for limiting the lifting range in the process, and the second guide shafts are used for enhancing the stability of the lifting process;
the overturning driving mechanism comprises a second lifting connecting plate, an overturning air cylinder seat plate, an overturning air cylinder, bearing seats, bearings, a coupler, a rotating shaft and a 90-degree overturning limiting assembly, the second lifting connecting plate is horizontally arranged and fixedly connected with the first lifting connecting plate, the overturning air cylinder seat plate is vertically arranged at one end of the second lifting connecting plate downwards, the overturning air cylinder is mounted on the overturning air cylinder seat plate, two bearing seats are arranged on the lower end face of the second lifting connecting plate at intervals, the bearings are mounted in the bearing seats, the rotating shaft is arranged between the two bearings, the rotating shaft is connected with the overturning air cylinder through the coupler, and the 90-degree overturning limiting assembly is arranged on the outer side of the bearing seat far away from the overturning air cylinder;
the 90-degree overturning limiting assembly comprises two limiting heads and limiting blocks, the two limiting heads are arranged at intervals, the upper ends of the limiting heads are fixed on the lower end face of the second lifting connecting plate, the limiting blocks are right-angle blocks, the limiting blocks are connected with the rotating shaft, one right-angle face of each limiting block is in contact with one limiting head, the other right-angle plate of each limiting block is in contact with the other limiting head when the rotating shaft rotates for 90 degrees, the overturning cylinder drives the rotating shaft to rotate when the overturning cylinder is started, and the rotating shaft can only rotate for 90 degrees under the limiting of the 90-degree overturning limiting assembly;
the material taking mechanism comprises an overturning connecting plate, a material taking air claw seat plate, a material taking air claw, a mechanical claw and a material pressing block, wherein the plate surface of the overturning connecting plate is connected with a rotating shaft, the lower end surface of the overturning connecting plate is connected with the material taking air claw seat plate, a plurality of material taking air claws are arranged on the plate surface of the material taking air claw seat plate at intervals, two mechanical claws which are matched with each other are arranged on each material taking air claw, the mechanical claws are bent in an L shape, the material pressing blocks which correspond to the material taking air claws in position one by one are arranged on the overturning connecting plate at intervals, the tail ends of the material pressing blocks extend into inner cavities formed by the two mechanical claws corresponding to the positions of the material pressing blocks, when the material taking air claws are started, the mechanical claws grip a three-way pipe, all three-way pipes are kept at the same height under the limit of the material pressing blocks, the overturning air cylinder is started, the rotating shaft rotates by 90 degrees, and overturns the vertical three-way pipe into a horizontal three-way pipe, so that one end of the three-way pipe, which is required to be assembled with the short pipe of the infusion apparatus, horizontally faces the short pipe of the infusion apparatus.
When the three-way pipe overturning device is used, the mechanical claw of the material taking mechanism grabs the three-way pipe after material feeding and aligning, and all the three-way pipes keep the same height under the limiting action of the material pressing block; a longitudinal moving cylinder of the longitudinal moving driving mechanism contracts to drive the three-way pipe to synchronously move upwards; the overturning cylinder of the overturning driving mechanism drives the rotating shaft to rotate, so as to drive the material taking air claw seat plate to rotate by 90 degrees, the three-way pipe is rotated to be in a horizontal state, and a three-way pipe interface needing to be assembled with a hose of an infusion apparatus faces to a short pipe of the infusion apparatus; and a second translation cylinder of the second translation driving mechanism drives the three-way pipe to move towards the short pipe of the infusion apparatus, so that the three-way pipe is bonded with the short pipe of the infusion apparatus which is coated with the glue, and the assembly is completed.
The utility model has the beneficial effects that: compared with the prior art, the automatic processing production line for assembling the three-way pipe of the infusion apparatus has the following advantages: (1) the three-way pipes are fully arranged in the P conveying channels, the P conveying channels are correspondingly aligned with the P three-way pipe accommodating openings one by one, the three-way pipes closest to the three-way pipe temporary storage mechanism enter the three-way pipe accommodating openings aligned with the P conveying channels, then the three-way pipe temporary storage mechanism is integrally moved by the staggered reciprocating movement mechanism, the P conveying channels are aligned with the other P three-way pipe accommodating openings one by one, the three-way pipes closest to the three-way pipe temporary storage mechanism enter the corresponding three-way pipe accommodating openings, the circulation is performed for n times, one three-way pipe is accommodated in each three-way pipe accommodating opening, and at the moment, the three-way pipes in the three-way pipe temporary storage mechanism are grabbed by the three-way pipe material taking and transferring device and transferred to the next process; the feeding device has the advantages that a large amount of feeding at one time can be met without adding conveying equipment, the cost is saved, the feeding speed of the three-way pipe is improved, the three-way pipe can stably move in the conveying channel and automatically align in the accommodating opening of the three-way pipe, the three-way pipe is stably grabbed by the three-way pipe feeding transfer device and is transferred to the next process, and the continuity of the whole process is high; (2) the three-way pipe rotating and righting mechanism is integrally moved to a clamping component for grabbing the three-way pipe in the three-way pipe taking and transferring device through the first translation driving mechanism, the three-way pipe is uniformly placed into a three-way pipe seat of the three-way pipe rotating and righting mechanism by the clamping component, the position of the three-way pipe in the three-way pipe seat is limited, the side shift cannot occur, the first translation driving mechanism is reset, all rotating shafts are driven by the rotating shaft rotating and driving component to synchronously rotate 180 degrees along the circumferential direction, so that a third pipe section on the side wall of the three-way pipe rotates to be opposite to the short pipe of the infusion apparatus, and the assembly of the three-way pipe and the short pipe of the infusion apparatus in the subsequent process is facilitated; (3) the three-way pipe assembling machine is compact in overall structure design, simple to operate, continuous in action and high in assembling precision, the material taking mechanism is driven to move downwards through the longitudinal moving driving mechanism, the three-way pipe is clamped by the material taking mechanism, the material taking mechanism is driven to move upwards through the longitudinal moving driving mechanism, the material taking mechanism is driven to rotate by 90 degrees through the overturning driving mechanism, the three-way pipe is enabled to horizontally face the short pipe of the infusion apparatus with one end assembled with the short pipe of the infusion apparatus, then the three-way pipe is moved towards the short pipe of the infusion apparatus through the second translational driving mechanism, finally the three-way pipe is bonded and assembled with the short pipe of the infusion apparatus coated with glue, and the assembling efficiency of the three-way pipe and the short pipe of the infusion apparatus is greatly improved.
Drawings
FIG. 1 is a schematic diagram of the general structure of an automatic processing production line for assembling a three-way pipe of an infusion apparatus of the present invention;
FIG. 2 is a schematic structural diagram of a three-way pipe feeding device and a three-way pipe taking and transferring device of the utility model;
FIG. 3 is a schematic structural diagram of the three-way pipe feeding device and the three-way pipe taking and transferring device at a second angle;
FIG. 4 is a schematic structural diagram of the three-way pipe feeding device and the three-way pipe taking and transferring device at a third angle;
FIG. 5 is a schematic structural diagram of a three-way pipe conveying mechanism of the three-way pipe feeding device of the utility model;
FIG. 6 is a schematic structural diagram of a three-way pipe temporary storage mechanism and a staggered reciprocating mechanism of the three-way pipe feeding device of the utility model;
FIG. 7 is another angle structure diagram of the temporary three-way pipe storage mechanism and the staggered reciprocating mechanism of the three-way pipe feeding device of the utility model;
FIG. 8 is a schematic structural view of a three-way pipe material taking and transferring device of the present invention;
FIG. 9 is an enlarged view of the structure of area A of FIG. 8 according to the present invention;
FIG. 10 is a schematic diagram of the general structure of the tee pipe rotation righting device of the present invention;
FIG. 11 is a schematic view of another angle of the tee rotation righting device of the present invention;
FIG. 12 is an enlarged view of the structure of the area B in FIG. 10 according to the present invention;
FIG. 13 is a schematic structural view of the three-way pipe rotating righting device of the present invention with a plate removed from the housing;
FIG. 14 is a schematic structural view of the three-way pipe rotating righting device of the present invention, wherein the shell of the three-way pipe rotating righting device only has a lower plate;
FIG. 15 is a schematic diagram of the general structure of the tee pipe inverting apparatus of the present invention;
FIG. 16 is a schematic view of the overall structure of the tee inverting apparatus of the present invention at another angle;
FIG. 17 is a schematic structural view of the tee pipe inverting apparatus of the present invention with the frame removed;
FIG. 18 is a schematic view of another angular configuration of the tee inversion apparatus of the present invention with the frame removed;
wherein, 1 frame, 2 three-way pipe loading device, 201 three-way pipe conveying mechanism, 2011 first bottom plate, 2012 conveying channel, 2013T-shaped perforation, 202 three-way pipe temporary storage mechanism, 2021 base, 2022 first slide rail, 2023 first slide block, 2024 lower support plate, 2025 side support plate, 2026 upper support plate, 2027 three-way pipe containing plate, 2028 three-way pipe containing opening, 203 dislocation reciprocating mechanism, 2031 first connecting plate, 2032 first cylinder, 2033 first cylinder mounting plate, 2034 second cylinder, 2035 second cylinder mounting plate, 3 three-way pipe transfer device, 301 clamping component, 3011 air claw mounting plate, 3012 parallel air claw, 3013 three-way pipe clamping jaw, 3014 semicircular opening, 302 longitudinal movement driving component, 3021 side connecting plate, 3022 horizontal support plate, 3023 longitudinal movement cylinder, 3024 first guide shaft, 3025 first linear bearing, sliding component, 303303 second slide rail, 3032 second slide block, 3033 sliding seat, 304 horizontal movement driving component, 3041 first translation cylinder, 3042 first translation cylinder mounting plate, 3043 limiting part, 3044 limiting part mounting plate, 4 three-way pipe rotation righting device, 401 second bottom plate, 402 first translation driving mechanism, 4021 third slide rail, 4022 third slide block, 4023 third cylinder, 4024 second connecting plate, 4025 first contact block, 4026 second contact block, 403 three-way pipe rotation righting mechanism, 4031 shell, 4032 rotating shaft, 4033 inserting block, 4034 side block, 4035 first shaft clamping plate, 4036 second shaft clamping plate, 4037 inserting hole, 4038 limiting groove, 4039 gear, 40310 fourth cylinder, 40311 cylinder seat plate, 40312 third connecting plate, 40313 fourth slide block, 40314 fifth slide block, 40315 slide block mounting plate, 40316 fourth slide rail, 50117 rack, 40318 buffer positioning block, 40319 cylinder telescopic positioning block, 40320 long strip hole, 5015 three-way pipe turning device, 4031 second translation driving mechanism, 4031 fifth slide rail mounting plate, 4031, 5012 sixth sliding block, 5013 sliding block plate, 5014 translational cylinder connecting plate, 5015 second translational cylinder, 5016 second translational cylinder mounting plate, 502 longitudinal movement driving mechanism, 5021 vertical plate, 5022 longitudinal movement cylinder seat plate, 5023 longitudinal movement cylinder, 5024 longitudinal movement top cylinder, 5025 limit top head, 5026 second linear bearing, 5027 second guide shaft, 5028 guide shaft rear connecting plate, 5029 first lifting connecting plate, 503 overturning driving mechanism, 5031 second lifting connecting plate, 5032 overturning cylinder seat plate, 5033 overturning cylinder, 5034 bearing seat, 5035 bearing, 5036 coupler, 5037 rotating shaft, 5038 limit head, 5039 limit block, 504 material taking mechanism, 5041 overturning connecting plate, 5042 material taking air claw seat plate, 5043 material taking air claw, 5044 mechanical claw, 5045 material pressing block and 6 three-way pipe.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.
In the embodiment shown in fig. 1-18, an automatic processing production line for assembling three-way pipes of infusion sets comprises a rack 1, and a three-way pipe feeding device 2, a three-way pipe taking and transferring device 3, a three-way pipe rotating and righting device 4 and a three-way pipe turning device 5 which are arranged on the rack 1, wherein the three-way pipe feeding device 2 and the three-way pipe rotating and righting device 4 are sequentially arranged on the rack, the three-way pipe taking and transferring device 3 is arranged on a rack body of the rack 1 above the three-way pipe feeding device 2 and the three-way pipe rotating and righting device 4, and the three-way pipe turning device 5 is arranged on a rack body of the rack 1 above the three-way pipe rotating and righting device 4;
during the use, arrange tee bend 6 into one row through tee bend loading attachment 2, get material transfer device 3 with the tee bend that the alignment is row through the tee bend and transfer three-way pipe 6 to the rotatory normal position device 4 of tee bend from tee bend loading attachment 2, tee bend 6 rotates 180 in the rotatory normal position device 4 of tee bend, then snatch tee bend 6 through tee bend turning device 5, to turning 90 with tee bend 6, lift to the horizontality from vertical state, the one end that tee bend 6 needs to bond the equipment with the transfusion system nozzle stub is just to the transfusion system nozzle stub this moment, the third pipeline section of the lateral wall of tee bend 6 is down, the tee bend can not take place the inclined to one side to move under the clamping effect of tee bend turning device 5 and the effect of tee bend 6 self gravity, it can to bond with the transfusion system nozzle stub that has scribbled the glue with tee bend 6 removal through tee bend turning device 5.
In this embodiment, the three-way pipe feeding device 2 comprises a three-way pipe conveying mechanism 201, a three-way pipe temporary storage mechanism 202 located at the tail end of the three-way pipe conveying mechanism 201, and a staggered reciprocating movement mechanism 203 for moving the three-way pipe temporary storage mechanism 202, wherein P conveying channels for conveying the three-way pipes 6 are arranged on the three-way pipe conveying mechanism 201, and 2 × P three-way pipe accommodating openings are formed in the three-way pipe temporary storage mechanism 202; during the use, all arrange tee pipe 6 fully in P transfer passage, P transfer passage corresponds and P tee pipe holding opening one-to-one aligns, arrange in tee pipe 6 that is closest to tee pipe temporary storage mechanism 202 gets into its tee pipe holding opening of aiming at, then dislocation reciprocating motion mechanism 203 moves tee pipe temporary storage mechanism 202 as a whole, make P transfer passage and other P tee pipe holding opening one-to-one align, arrange in tee pipe 6 that is closest to tee pipe temporary storage mechanism 202 gets into its tee pipe holding mouth that corresponds, 2 times so circulate, a tee pipe 6 has all been held in all tee pipe holding openings, need not to increase conveying equipment and can satisfy disposable a large amount of material loadings, and the cost is saved improves the material loading rate of tee pipe 6.
In this embodiment, the three-way pipe conveying mechanism 201 is installed on the rack 1, and the three-way pipe conveying mechanism 201 includes a first bottom plate 2011 and a conveying channel 2012 arranged at an upper end of the first bottom plate 2011 at an interval; the main body of the conveying channel 2012 is of a rectangular structure, a T-shaped through hole 2013 is formed in the main body of the conveying channel 2012 along the length direction, the upper end of the T-shaped through hole 2013 is communicated with the upper end face of the main body of the conveying channel 2012, the head of the three-way pipe 6 is positioned in an upper end opening of the T-shaped through hole 2013, one end of the three-way pipe 6 to be assembled with the short pipe of the infusion apparatus is inserted into a lower end opening of the T-shaped through hole 2013, and the other end of the three-way pipe 6 is positioned in the T-shaped through hole 2013 and extends to the direction of the three-way pipe temporary storage mechanism 202; the first bottom plate 2011 and/or the conveying channel 2012 are inclined downwards in the direction of the three-way pipe temporary storage mechanism 202, the placing direction of the three-way pipe 6 is favorable for the three-way pipe 6 to smoothly slide downwards under the action of gravity, and the position of the three-way pipe stably and smoothly enters the three-way pipe accommodating opening of the three-way pipe temporary storage mechanism 202 in the sliding-down process.
In this embodiment, the three-way pipe temporary storage mechanism 202 includes a base 2021, a first slide rail 2022, a first slider 2023, a lower support plate 2024, a side support plate 2025, an upper support plate 2026, and a three-way pipe accommodating plate 2027, where the base 2021 is mounted on the machine frame 1, the upper end surface of the base 2021 is provided with the first slide rail 2022, the direction of the first slide rail 2022 is perpendicular to the direction of the conveying channel 2012, the first slide rail 2022 is mounted with the first slider 2023, the upper end surface of the first slider 2023 is connected to the lower end surface of the lower support plate 2024, the two ends of the lower support plate 2024 are provided with the side support plates 2025, the upper support plate 2026 is disposed between the upper ends of the side support plates 2025, the upper end surface of the upper support plate 2026 is mounted with the three-way pipe accommodating plate 2027, the three-way pipe accommodating plate 2027 is disposed in a direction perpendicular to the direction of the conveying channel 2012, the three-way pipe accommodating plate 2027 is provided with three-way pipe accommodating openings 2028 at intervals, when the first slider 2023 slides along the first slide rail 2022 under the external force, the three-way pipe accommodating plate 2027 is displaced so that the three-way pipe accommodating openings 2028 are aligned with the conveying channel 2012 in 2 batches, P in each batch, the shape of the three-way pipe accommodating openings 2028 does not move according to the position of the three-way pipe 6 in the three-way pipe accommodating openings 2028, and the three-way pipe accommodating openings are conveniently and accurately grabbed by the three-way pipe clamping jaws on the three-way pipe taking and transferring device 3;
in this embodiment, the reciprocating moving mechanism 203 includes a first connection plate 2031, a first cylinder 2032, a first cylinder mounting plate 2033, a second cylinder 2034, and a second cylinder mounting plate 2035, the upper end surface of the base 2021 is provided with the first cylinder mounting plate 2033 and the second cylinder mounting plate 2035 at intervals along the length direction of the base 2021, the first cylinder 2032 is mounted on the first cylinder mounting plate 2033, the second cylinder 2034 symmetrically arranged with the first cylinder 2032 is mounted on the second cylinder mounting plate 2035, the first connection plate 2031 is located at the middle of the first cylinder mounting plate 2033 and the second cylinder mounting plate 5, one end of the first connection plate 2031 is fixed on the lower support plate 2024 or the upper support plate 2026, the two side surfaces of the other end of the first connection plate 2031 are respectively connected with the first cylinder 2032 and the second cylinder 2034, the second cylinder 2034 contracts when the first cylinder 2032 extends, the second cylinder 2034 extends when the first cylinder 2032 contracts, the first connecting plate 2031 is driven to move by the first cylinder 2032 and the second cylinder 2034, the whole three-way pipe temporary storage mechanism 202 is driven to move by the first connecting plate 2031, and the three-way pipe temporary storage mechanism 202 is ensured to move stably.
In this embodiment, the three-way pipe taking and transferring device 3 comprises a clamping assembly 301, a longitudinal movement driving assembly 302 connected with the clamping assembly 301 and used for moving the clamping assembly 301 up and down, a sliding assembly 303 installed on the rack 1 and connected with the longitudinal movement driving assembly 302, and a horizontal movement driving assembly 304 installed on the rack 1 and connected with the sliding assembly 303; during use, clamping assembly 301 is used for clamping tee 6 from tee temporary storage 202, and longitudinal movement drive assembly 302 is used for driving clamping assembly 301 to move up and down, and horizontal movement drive assembly 304 is used for pushing sliding assembly 303, and then drives longitudinal movement drive assembly 302 and clamping assembly 301 to translate.
In this embodiment, the clamping assembly 301 includes an air claw mounting plate 3011, 2 × P parallel air claws 3012 arranged on the air claw mounting plate 3011 at intervals, and a set of three-way pipe clamping jaws 3013 arranged on each parallel air claw 3012, the jaw ends of the parallel air claws 3012 face downward, each set of three-way pipe clamping jaws 3013 includes two L-shaped three-way pipe clamping jaws 3013 arranged symmetrically, and the positions of the three-way pipe clamping jaws 3013 correspond to the positions of the three-way pipe accommodating openings 2028; semicircular openings 3014 are symmetrically arranged at the contact end of the L-shaped three-way pipe clamping jaw, the parallel air claw 3012 is opened and closed to drive the three-way pipe clamping jaw 3013 to be opened and closed, and the semicircular opening 3014 is clamped below the head of the three-way pipe 6 when the three-way pipe clamping jaw 3013 is closed;
the longitudinal movement driving assembly 302 comprises two side connecting plates 3021, horizontal supporting plates 3022, longitudinal movement cylinders 3023, a first guide shaft 3024 and a first linear bearing 3025, the side connecting plates 3021 are arranged at intervals, the upper ends of the side connecting plates 3021 are connected with the sliding assembly 303, the horizontal supporting plate 3022 is fixed between the lower ends of the side connecting plates 3021, the longitudinal movement cylinders 3023 are mounted on the horizontal supporting plates 3022, the ends of the piston rods of the longitudinal movement cylinders 3023 penetrate the horizontal supporting plates 3022 downward and are connected with the upper end surfaces of the air claw mounting plates 3011, the first linear bearings 3025 are arranged on the horizontal supporting plates 3022 on both sides of the longitudinal movement cylinders 3023, the first guide shafts 3024 are mounted in the first linear bearings 3025, the lower ends of the first guide shafts 3024 are connected with the upper end surfaces of the air claw mounting plates 3011, the extension and retraction of the longitudinal movement cylinders 3023 drive the clamping assembly 301 to move up and down, the first guide shafts 3024 move in the first linear bearings 3025 along with the extension and retraction of the longitudinal movement cylinders 3023, the function of stable guiding is achieved;
the sliding assembly 303 comprises a second sliding rail 3031, a second sliding block 3032 and a sliding seat 3033, the second sliding rail 3031 is mounted on the frame 1, the second sliding block 3032 is mounted on the second sliding rail 3031, the upper end surface of the second sliding block 3032 is fixedly connected with the lower end surface of the sliding seat 3033, and the sliding seat 3033 is connected with the upper end of the side connecting plate 3021 of the longitudinal movement driving assembly 302;
the horizontal movement driving assembly 304 includes a first translation cylinder 3041, a first translation cylinder mounting plate 3042, a limiting member 3043 and a limiting member mounting plate 3044, the first translation cylinder mounting plate 3042 is mounted on the frame 1, the first translation cylinder mounting plate 3042 is mounted with the first translation cylinder 3041, the end of the piston rod of the first translation cylinder 3041 is connected with the sliding base 3033, the sliding base 3033 is driven by the expansion of the first translation cylinder 3041 to move along the setting direction of the second sliding rail 3031, the limiting member mounting plates 3044 are mounted on the frame 1 at two sides of the first translation cylinder mounting plate 3042, and the limiting member 3043 for limiting the sliding base 3033 is mounted on the limiting member mounting plates 3044; the expansion and contraction of the first translation cylinder 3041 drives the sliding base 3033 and the second sliding block 3032 to move along the second sliding rail 3031, so that the longitudinal movement driving assembly 302 and the clamping assembly 301 translate, and the limiting member 3043 is used for limiting the movement of the sliding base 3033.
In this embodiment, the three-way pipe rotating and righting device 4 includes a second bottom plate 401, a first translation driving mechanism 402 disposed at the upper end of the second bottom plate, and a three-way pipe rotating and righting mechanism 403 connected to the first translation driving mechanism 402, the three-way pipe rotating and righting mechanism 403 includes a housing 4031, a rotating shaft 4032, a three-way pipe socket and a rotating shaft rotating and driving assembly, 2 × P pieces are disposed at intervals on the rotating shaft 4032, the rotating shaft 4032 is mounted in the housing 4031 through a bearing, the upper end of the rotating shaft 4032 penetrates through the housing 4031, the three-way pipe socket is mounted at the upper end of the rotating shaft 4032, and shaft sections of the rotating shaft 4032 inside the housing 4031 are all connected to the rotating shaft rotating and driving assembly; during the use, at first through first translation actuating mechanism 402 with the rotatory normal position mechanism 403 of three-way pipe wholly get material transfer device 3 to the three-way pipe and be used for snatching the clamping component 301 removal of three-way pipe, clamping component 301 puts three-way pipe 6 in the three-way pipe seat of the rotatory normal position mechanism 403 of three-way pipe, three-way pipe 6 is injectd in the three-way pipe seat position, the sidesway can not take place, first translation actuating mechanism 402 resets, drive all pivots 4032 along the rotation in a circumferential direction 180 in step through the pivot rotation actuating assembly for the third pipe section that is located on the lateral wall of three-way pipe 6 rotates to the transfusion system nozzle stub dorsad, in order to do benefit to the equipment with three-way pipe 6 and transfusion system nozzle stub in the follow-up process.
In this embodiment, the first translation driving mechanism 402 includes a third slide rail 4021, a third slider 4022, a third cylinder 4023 and a second connecting plate 4024, the third slide rail 4021 is mounted on the second base plate 401, the third slide rail 4021 is provided with the third slider 4022, the upper end surface of the third slider 4022 is fixedly connected to the lower end surface of the housing 4031, the third cylinder 4023 is mounted on the second base plate 401, the end of the piston rod of the third cylinder 4023 is connected to the second connecting plate 4024, the second connecting plate 4024 is fixed to the housing 4031, the third cylinder 4023 extends and retracts to drive the second connecting plate 4024 to move back and forth, and then the three-way pipe rotation righting mechanism 403 connected to the second connecting plate 4024 is pulled to translate, so as to move the three-way pipe rotation righting mechanism 403 to be close to or far away from the clamping assembly 301 for grabbing the three-way pipe 6 in the three-way pipe material taking device 3; a first contact block 4025 is arranged on the lower end surface of the housing 4031, a second contact block 4026 is arranged on the lower end surface of the second base plate 401, and when the first contact block 4025 contacts the second contact block 4026, the first translation driving mechanism 402 is reset;
the three-way pipe seat comprises an insert 4033, a side block 4034 arranged on one side of the upper end face of the insert 4033, a first shaft clamp 4035 arranged on the lower end face of the insert 4033 and a second shaft clamp 4036 connected with the first shaft clamp 4035 through a fastener, the first shaft clamp 4035 and the second shaft clamp 4036 are clamped at the upper end of a rotating shaft 4032, a jack 4037 is arranged on the insert 4032, a limit groove 4038 is arranged on the side block 4034, the size of the jack 4037 is matched with that of one end, needing to be connected with a short pipe of an infusion apparatus, of the three-way pipe 6, one end, needing to be connected with the short pipe of the infusion apparatus is inserted into the jack 4037, the arc surface shape of the limit groove 4038 is matched with the arc surface of a pipe section on the side face of the three-way pipe 6, and the pipe section on the side wall of the three-way pipe 6 is limited in the limit groove 4038, so that the three-way pipe 6 is prevented from moving circumferentially in the rotating righting process;
the rotating shaft rotation driving assembly comprises a gear 4039, a fourth cylinder 40310, a cylinder seat plate 40311, a third connecting plate 40312, a fourth slider 40313, a fifth slider 40314, a slider mounting plate 40315, a fourth sliding rail 40316 and a rack 40317, wherein the gear 4039 is sleeved on the outer wall of the rotating shaft 4032, the cylinder seat plate 40311 is arranged on the inner wall of the housing 4031, the fourth cylinder 40310 is arranged in the inner cavity of the housing 4031 through the cylinder seat plate 40311, the arrangement direction of the fourth cylinder 40310 is perpendicular to the direction of the rotating shaft 4032, the tail end of a piston rod of the fourth cylinder 40310 is connected with the starting end of the third connecting plate 40312, a cylinder barrel of the fourth cylinder 40310 is connected with the fourth slider 40313 through the slider mounting plate 40315, the fifth slider 40314 is arranged on one side far away from the fourth cylinder 40310 at intervals through another slider mounting plate 40315, the fourth sliding rail 16 sequentially passes through the fourth slider 40313 and the fifth slider 40314, the fourth slider 40316 is fixedly connected with the rack 40317, the fourth 40316 is arranged in the same direction as the rack 4032, teeth of the rack 40317 are meshed with gears 4039 on the outer walls of all the rotating shafts 4032, the tail end of the third connecting plate 40312 is fixedly connected with the fourth sliding rail 40316 and/or the rack 40317, in the rotating shaft rotation driving assembly, the fourth sliding block 40313 and the fifth sliding block 40314 are kept in constant positions, the third connecting plate 40312 pulls the fourth sliding rail 40316 and the rack 40317 to translate under the telescopic driving of the fourth cylinder 40310, and the gear 4039 rotates to drive the rotating shaft 4032 to rotate 180 degrees in the translation process of the rack 40317, so that a third pipe section on the side wall of the three-way pipe 6 rotates to face away from the short pipe of the infusion apparatus, and the three-way pipe 6 and the short pipe of the infusion apparatus can be assembled in a subsequent process conveniently; a buffering positioning block 40318 is arranged on the upper end face of the fourth sliding rail 40316 and/or the rack 40317, the height of the buffering positioning block 40318 is in clearance fit with the distance from the fourth sliding rail 4031 or the rack 40317 to the top face of the housing 4031, and the buffering positioning block 40318 is mainly used for determining the meshing position of the rack 40317 and the gear 4039 in the device installation process; cylinder telescopic positioning blocks 40319 are arranged on the lower end face of the fourth sliding rail 40313 and/or the rack 40317 at intervals, when the fourth cylinder 40310 extends, the tail end of a piston rod of the fourth cylinder 40310 is in contact with one cylinder telescopic positioning block 40319 to indicate that 180-degree rotation is completed, and when the fourth cylinder 40310 contracts, the fourth slider 40313 is in contact with the other cylinder telescopic positioning block 40319 to indicate that 180-degree rotation is completed; a long strip hole 40320 for allowing the rack 40317 and the fourth sliding rail 40316 to pass through is formed in the side surface of the housing 4031; the side plates of the housing 4031 are fixed by fasteners.
In this embodiment, the three-way pipe turning device 5 includes a second translation driving mechanism 501, a longitudinal translation driving mechanism 502, a turning driving mechanism 503 and a material taking mechanism 504, the second translation driving mechanism 501 is installed on the rack 1, the second translation driving mechanism 501 is connected with the longitudinal translation driving mechanism 502, the turning driving mechanism 503 is connected below the longitudinal translation driving mechanism 502, and the turning driving mechanism 503 is connected with the material taking mechanism 504;
the second translation driving mechanism 501 is used for driving the longitudinal movement driving mechanism 502, the overturning driving mechanism 503 and the material taking mechanism 504 to integrally translate, the longitudinal movement driving mechanism 502 is used for driving the overturning driving mechanism 503 and the material taking mechanism 504 to lift, the overturning driving mechanism 503 is used for driving the material taking mechanism 504 to overturn by 90 degrees, and the material taking mechanism 504 is used for grabbing the three-way pipe 6;
when the three-way pipe splicing device is used, the material taking mechanism 504 is driven to move downwards through the longitudinal moving driving mechanism 502, the material taking mechanism 504 clamps the three-way pipe 6, the longitudinal moving driving mechanism 502 drives the material taking mechanism 504 to move upwards, the overturning driving mechanism 503 drives the material taking mechanism 504 to rotate for 90 degrees, so that one end, required to be assembled with the short pipe of the infusion apparatus, of the three-way pipe 6 horizontally faces the short pipe of the infusion apparatus, then the three-way pipe is moved towards the short pipe of the infusion apparatus through the second translation driving mechanism 501, and finally the three-way pipe 6 and the short pipe of the infusion apparatus coated with glue are spliced and assembled together.
In this embodiment, the second translation driving mechanism 501 includes a fifth slide rail 5011, a sixth slider 5012, a sliding table 5013, a translation cylinder connecting plate 5014, a second translation cylinder 5015, and a second translation cylinder mounting plate 5016, where the fifth slide rail 5011 is at least two parallel and spaced apart from the fifth slide rail 5011, the fifth slide rail 5011 is fixed to the rack 1, the fifth slide rail 5011 is provided with the sixth slider 5012 in a matching manner, the sliding table 5013 is fixed between upper end surfaces of the sixth slider 5012, the sliding table 5013 is provided with the translation cylinder connecting plate 5014, the second translation cylinder mounting plate 5014 is fixed to the rack 1, the second translation cylinder mounting plate 5016 is provided with the second translation cylinder 5015, a distal end of a piston rod of the second translation cylinder 5015 is connected to the translation cylinder connecting plate 5014, and when the second translation cylinder 5015 extends and retracts, the sliding table 5013 is pulled or pushed to translate along the direction of the fifth slide rail 5011;
the longitudinal movement driving mechanism 502 comprises a vertical plate 5021, a longitudinal movement cylinder seat plate 5022, a longitudinal movement cylinder 5023, a longitudinal movement top cylinder 5024, a limit top head 5025, a second linear bearing 5026, a second guide shaft 5027, a guide shaft rear connecting plate 5028 and a first lifting connecting plate 5029, the lower end face of the sliding plate 5013 is provided with the vertical plate 5021 at intervals, a longitudinal movement cylinder seat plate 5022 is fixed between the lower end faces of the vertical plate 5021, the longitudinal movement cylinder 5023 is installed on the longitudinal movement cylinder seat plate 5022, the tail end of a piston rod of the longitudinal movement cylinder 5023 downwards penetrates through the longitudinal movement cylinder seat plate 5022 and then is connected with the first lifting connecting plate 5029, the longitudinal movement cylinder seat plate 5024 on two sides of the longitudinal movement cylinder 5023 is provided with the longitudinal movement top cylinder 5024, a top rod of the longitudinal movement top cylinder 5024 downwards extends out of the longitudinal movement cylinder seat plate 5022, the upper end face of the first lifting connecting plate 5029 is provided with the limit top head 5025 matched with a top rod of the longitudinal movement top cylinder 5024, the second linear bearing 5026 is arranged on the longitudinal movement cylinder seat plate 5022, second guide shafts 5027 are arranged in the second linear bearings 5026, the upper ends of the second guide shafts 5027 upwards penetrate through sliding table plates 5013, guide shaft rear connecting plates 5028 are connected between the upper end faces of the second guide shafts 5027, the lower ends of the second guide shafts 5027 are connected with first lifting connecting plates 5029 which are horizontally arranged, the longitudinal movement cylinders 5023 stretch to drive the first lifting connecting plates 5029 to lift, in the process, the longitudinal movement top cylinders 5024 are used for limiting the lifting range, and the second guide shafts 5027 are used for enhancing the stability of the lifting process;
the overturning driving mechanism 503 comprises a second lifting connecting plate 5031, an overturning cylinder seat plate 5032, an overturning cylinder 5033, a bearing seat 5034, a bearing 5035, a coupler 5036, a rotating shaft 5037 and a 90-degree overturning limiting component, wherein the second lifting connecting plate 5031 is horizontally arranged and fixedly connected with the first lifting connecting plate 5029, one end of the second lifting connecting plate 5031 is vertically and downwards provided with the overturning cylinder seat plate 5032, the overturning cylinder seat plate 5032 is provided with the overturning cylinder 5033, the lower end face of the second lifting connecting plate 5031 is provided with two bearing seats 5034 at intervals, the bearing seats 5034 are internally provided with bearings, the rotating shaft 5037 is arranged between the two bearings, the rotating shaft 5037 is connected with the overturning cylinder 5033 through the coupler 5036, and the outer side of the bearing seat 5034 far away from the overturning cylinder 5033 is provided with the 90-degree overturning limiting component;
the 90-degree overturning limiting assembly comprises two limiting heads 5038 and two limiting blocks 5039, the two limiting heads 5038 are arranged at intervals, the upper end of each limiting head 5038 is fixed on the lower end face of the second lifting connecting plate 5031, each limiting block 5039 is a right-angle block, each limiting block 5039 is connected with the rotating shaft 5037, one right-angle face of each limiting block 5039 is in contact with one limiting head 5038, when the rotating shaft 5037 rotates for 90 degrees, the other right-angle plate of each limiting block 5039 is in contact with the other limiting head 5038, when the overturning air cylinder 5033 is started, the overturning air cylinder 5033 drives the rotating shaft 5037 to rotate, and under the limiting effect of the 90-degree overturning limiting assembly, the rotating shaft 5037 can only rotate for 90 degrees;
the material taking mechanism 504 comprises a turning connecting plate 5041, a material taking air claw seat plate 5042, a material taking air claw 5043, a mechanical claw 5044 and a material pressing block 5045, wherein the plate surface of the turning connecting plate 5041 is connected with a rotating shaft 5037, the lower end surface of the turning connecting plate 5041 is connected with the material taking air claw seat plate 5042, a plurality of material taking air claws 5043 are arranged on the plate surface of the material taking air claw seat plate 5042 at intervals, two mechanical claws 5044 which are mutually matched are arranged on each material taking air claw 5043, the mechanical claws 5044 are bent in an L shape, material pressing blocks 5045 which are in one-to-one correspondence with the positions of the material taking air claws 5043 are arranged on the turning connecting plate 5041 at intervals, the tail ends of the material pressing blocks 5045 extend into inner cavities formed by the two mechanical claws 5044 which are in correspondence with the positions, when the material taking air claws 5043 are started, the mechanical claws 5044 grab the three-way pipe 6, all the three-way pipes 6 are kept at the same height under the limit of the block 5045, at the moment, the turning cylinder 5033 is started, the rotating shaft 5037 rotates by 90 degrees to turn the vertical three-way pipe 6 into a horizontal three-way pipe 6, so that the end of the three-way pipe 6, which needs to be assembled with the short pipe of the infusion apparatus, faces horizontally towards the short pipe of the infusion apparatus.
In the embodiment, in the use process of the three-way pipe turnover device 5, the mechanical claw 5044 of the material taking mechanism 504 grabs the three-way pipe 6 after material feeding and aligning, and all the three-way pipes 6 keep the same height under the limiting action of the material pressing block 5045; the longitudinal movement cylinder 5023 of the longitudinal movement driving mechanism 502 contracts to drive the three-way pipe 6 to move upwards synchronously; the overturning cylinder belt 5033 of the overturning driving mechanism 503 moves the rotating shaft 5037 to rotate, so as to drive the material taking gas claw seat plate 5042 to rotate by 90 degrees, the three-way pipe 6 is rotated to be in a horizontal state, and the interface of the three-way pipe which needs to be assembled with the hose of the infusion apparatus faces the short pipe of the infusion apparatus; the second translation cylinder 5015 of the second translation driving mechanism 501 drives the three-way pipe to move towards the short pipe of the infusion apparatus, so that the three-way pipe is bonded with the short pipe of the infusion apparatus which is already glued, and the assembly is completed.
The above embodiments are only specific examples of the present invention, and the protection scope of the present invention includes but is not limited to the product forms and styles of the above embodiments, and any suitable changes or modifications made by those skilled in the art according to the claims of the present invention shall fall within the protection scope of the present invention.
Claims (10)
1. The utility model provides an automatic processing production line of transfusion system three-way pipe equipment which characterized in that: the three-way pipe feeding device and the three-way pipe rotating and righting device are sequentially mounted on the rack, the three-way pipe feeding device is mounted on a rack support body above the three-way pipe feeding device and the three-way pipe rotating and righting device, and the three-way pipe overturning device is mounted on the rack support body above the three-way pipe rotating and righting device.
2. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 1, characterized in that: the three-way pipe feeding device comprises a three-way pipe conveying mechanism, a three-way pipe temporary storage mechanism and a staggered reciprocating movement mechanism, wherein the three-way pipe temporary storage mechanism is positioned at the tail end of the three-way pipe conveying mechanism, the staggered reciprocating movement mechanism is used for moving the three-way pipe temporary storage mechanism, P conveying channels used for conveying the three-way pipes are arranged on the three-way pipe conveying mechanism, and n multiplied by P three-way pipe accommodating openings are formed in the three-way pipe temporary storage mechanism.
3. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 2, characterized in that: the three-way pipe conveying mechanism is arranged on the rack and comprises a first bottom plate and a conveying channel arranged at the upper end of the first bottom plate at intervals; the main body of the conveying channel is of a rectangular structure, a T-shaped through hole is formed in the main body of the conveying channel along the length direction, the upper end of the T-shaped through hole is communicated with the upper end face of the main body of the conveying channel, the head of the three-way pipe is positioned in an opening at the upper end of the T-shaped through hole, one end of the three-way pipe, to be assembled with the short pipe of the infusion apparatus, is inserted into an opening at the lower end of the T-shaped through hole, and the other end of the three-way pipe is positioned in the T-shaped through hole and extends to the direction of the temporary storage mechanism of the three-way pipe; the first bottom plate and/or the conveying channel are/is arranged in a downward inclining mode towards the direction of the three-way pipe temporary storage mechanism.
4. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 3, characterized in that: the three-way pipe temporary storage mechanism comprises a base, a first slide rail, a first slide block, a lower support plate, side support plates, an upper support plate and a three-way pipe containing plate, wherein the base is installed on a rack, the first slide rail is arranged on the upper end surface of the base, the direction of the first slide rail is perpendicular to the direction of a conveying channel, the first slide block is installed on the first slide rail, the upper end surface of the first slide block is connected with the lower end surface of the lower support plate, the side support plates are arranged at two ends of the lower support plate, the upper support plate is arranged between the upper ends of the side support plates, the three-way pipe containing plate is installed on the upper end surface of the upper support plate, the setting direction of the three-way pipe containing plate is perpendicular to the direction of the conveying channel, and three-way pipe containing openings are arranged on the three-way pipe containing plate at intervals; dislocation reciprocating motion mechanism includes first connecting plate, first cylinder mounting panel, second cylinder and second cylinder mounting panel, the up end of base is provided with first cylinder mounting panel and second cylinder mounting panel along base length direction interval, installs first cylinder on the first cylinder mounting panel, install the second cylinder that sets up with first cylinder symmetry on the second cylinder mounting panel, first connecting plate is located the middle part of first cylinder mounting panel and second cylinder mounting panel, the one end of first connecting plate is fixed on lower support plate or last backup pad, the both sides face of the other end of first connecting plate is connected with first cylinder and second cylinder respectively.
5. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 3, characterized in that: the three-way pipe taking and transferring device comprises a clamping assembly, a longitudinal moving driving assembly, a sliding assembly and a horizontal moving driving assembly, wherein the longitudinal moving driving assembly is connected with the clamping assembly and used for moving the clamping assembly up and down, the sliding assembly is installed on the rack and connected with the longitudinal moving driving assembly, and the horizontal moving driving assembly is installed on the rack and connected with the sliding assembly.
6. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 5, characterized in that: the clamping assembly comprises an air claw mounting plate, n multiplied by P parallel air claws arranged on the air claw mounting plate at intervals and a group of three-way pipe clamping jaws arranged on each parallel air claw, wherein the claw ends of the parallel air claws face downwards, each group of three-way pipe clamping jaws comprises two L-shaped three-way pipe clamping jaws which are symmetrically arranged, and the positions of the three-way pipe clamping jaws correspond to the positions of the accommodating openings of the three-way pipes; the contact end of the L-shaped three-way pipe clamping jaw is symmetrically provided with semicircular openings;
the longitudinal movement driving assembly comprises two side connecting plates, horizontal supporting plates, longitudinal movement cylinders, first guide shafts and first linear bearings, the two side connecting plates are arranged at intervals, the upper ends of the side connecting plates are connected with the sliding assembly, the horizontal supporting plates are fixed between the lower ends of the side connecting plates, the longitudinal movement cylinders are longitudinally arranged on the horizontal supporting plates, the tail ends of piston rods of the longitudinal movement cylinders downwards penetrate through the horizontal supporting plates and are connected with the upper end faces of the gas claw mounting plates, the horizontal supporting plates on the two sides of the longitudinal movement cylinders are provided with the first linear bearings, the first guide shafts are arranged in the first linear bearings, and the lower ends of the first guide shafts are connected with the upper end faces of the gas claw mounting plates;
the sliding assembly comprises a second sliding rail, a second sliding block and a sliding seat, the second sliding rail is arranged on the rack, the second sliding block is arranged on the second sliding rail, the upper end face of the second sliding block is fixedly connected with the lower end face of the sliding seat, and the sliding seat is connected with the upper end of a side connecting plate of the longitudinal movement driving assembly;
the horizontal migration drive assembly comprises a first translation cylinder, a first translation cylinder mounting plate, a limiting part and a limiting part mounting plate, wherein the first translation cylinder mounting plate is mounted on the frame, the first translation cylinder is mounted on the first translation cylinder mounting plate, the tail end of a piston rod of the first translation cylinder is connected with the slide seat, the first translation cylinder stretches out and draws back to drive the slide seat to move along the setting direction of the second slide rail, the limiting part mounting plate is mounted on the frame of two sides of the first translation cylinder mounting plate, and the limiting part mounting plate is mounted with the limiting part for limiting the slide seat.
7. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 6, characterized in that: the three-way pipe rotating and righting device comprises a second bottom plate, a first translation driving mechanism arranged at the upper end of the second bottom plate and a three-way pipe rotating and righting mechanism connected with the first translation driving mechanism, the three-way pipe rotating and righting mechanism comprises a shell, a rotating shaft, a three-way pipe seat and a rotating shaft rotating driving assembly, n multiplied by P strips are arranged at intervals of the rotating shaft, the rotating shaft is installed in the shell through a bearing, the shell is penetrated out of the upper end of the rotating shaft, the three-way pipe seat is installed at the upper end of the rotating shaft, and a shaft section of the rotating shaft, which is located inside the shell, is connected with the rotating shaft rotating driving assembly.
8. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 7, characterized in that: the first translation driving mechanism comprises a third slide rail, a third slide block, a third air cylinder and a second connecting plate, the third slide rail is mounted on the second bottom plate, the third slide rail is provided with the third slide block, the upper end face of the third slide block is fixedly connected with the lower end face of the shell, the third air cylinder is mounted on the second bottom plate, the tail end of a piston rod of the third air cylinder is connected with the second connecting plate, the second connecting plate is fixed on the shell, the lower end face of the shell is provided with a first contact block, and the lower end face of the second bottom plate is provided with a second contact block;
the three-way pipe seat comprises an insert block, a side block arranged on one side of the upper end face of the insert block, a first shaft clamping plate arranged on the lower end face of the insert block and a second shaft clamping plate connected with the first shaft clamping plate through a fastener, wherein the first shaft clamping plate and the second shaft clamping plate are clamped at the upper end of a rotating shaft, the insert block is provided with an insertion hole, the side block is provided with a limiting groove, the size of the insertion hole is matched with that of one end of the three-way pipe, which is required to be connected with the short pipe of the infusion apparatus, and the arc shape of the limiting groove is matched with the arc surface of the pipe section on the side face of the three-way pipe;
the rotating shaft rotation driving assembly comprises a gear, a fourth air cylinder, an air cylinder seat plate, a third connecting plate, a fourth sliding block, a fifth sliding block, a sliding block mounting plate, a fourth sliding rail and a rack, the gear is sleeved on the outer wall of the rotating shaft, the air cylinder seat plate is arranged on the inner wall of the shell, the fourth air cylinder is arranged in the inner cavity of the shell through the air cylinder seat plate, the arrangement direction of the fourth air cylinder is vertical to the direction of the rotating shaft, the tail end of a piston rod of the fourth air cylinder is connected with the starting end of the third connecting plate, a cylinder barrel of the fourth air cylinder is connected with the fourth sliding block through the sliding block mounting plate, the fifth sliding block is arranged on one side far away from the cylinder barrel of the fourth air cylinder at intervals through another sliding block mounting plate, the fourth sliding rail sequentially penetrates through the fourth sliding block and the fifth sliding block, the fourth sliding rail is fixedly connected with the rack, the arrangement directions of the fourth sliding rail and the rack are the same and are vertical to the rotating shaft, and teeth of the rack are meshed with the gears on the outer walls of all the rotating shaft, the tail end of the third connecting plate is fixedly connected with the fourth sliding rail and/or the rack; the upper end surface of the fourth sliding rail and/or the rack is provided with a buffer positioning block, and the height of the buffer positioning block is in clearance fit with the distance from the fourth sliding rail or the rack to the top surface of the shell; the lower end face of the fourth sliding rail and/or the rack is provided with cylinder telescopic positioning blocks at intervals; a long hole through which the rack and the fourth sliding rail can pass is formed in the side face of the shell; the side plates of the shell are fixed through fasteners.
9. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 8, characterized in that: the three-way pipe overturning device comprises a second translation driving mechanism, a longitudinal translation driving mechanism, an overturning driving mechanism and a material taking mechanism, wherein the second translation driving mechanism is installed on the rack and connected with the longitudinal translation driving mechanism, the overturning driving mechanism is connected below the longitudinal translation driving mechanism, and the overturning driving mechanism is connected with the material taking mechanism.
10. The automatic processing production line for assembling the three-way pipe of the infusion apparatus according to claim 9, characterized in that: the second translation driving mechanism comprises fifth sliding rails, sixth sliding blocks, sliding table plates, translation cylinder connecting plates, second translation cylinders and second translation cylinder mounting plates, the fifth sliding rails are at least arranged in parallel at intervals, the fifth sliding rails are fixed on the rack, the fifth sliding rails are provided with the sixth sliding blocks in a matched manner, the sliding table plates are fixed between the upper end surfaces of the sixth sliding blocks, the translation cylinder connecting plates are arranged on the sliding table plates, the second translation cylinder mounting plates are fixed on the rack, the second translation cylinders are mounted on the second translation cylinder mounting plates, and the tail ends of piston rods of the second translation cylinders are connected with the translation cylinder connecting plates;
the longitudinal movement driving mechanism comprises a vertical plate, a longitudinal movement air cylinder seat plate, a longitudinal movement air cylinder, a longitudinal movement jacking cylinder, a limiting jacking head, a second linear bearing, a second guide shaft, a guide shaft rear connecting plate and a first lifting connecting plate, wherein the vertical plate is arranged on the lower end surface of the sliding plate at intervals, the longitudinal movement air cylinder seat plate is fixed between the lower end surfaces of the vertical plates, the longitudinal movement air cylinder is arranged on the longitudinal movement air cylinder seat plate, the tail end of a piston rod of the longitudinal movement air cylinder downwards penetrates through the longitudinal movement air cylinder seat plate and then is connected with the first lifting connecting plate, the longitudinal movement jacking cylinders are arranged on the longitudinal movement air cylinder seat plates on the two sides of the longitudinal movement air cylinder, a jacking rod of each longitudinal movement jacking cylinder downwards extends out of the longitudinal movement air cylinder seat plate, the limiting jacking head matched with a jacking rod of each longitudinal movement jacking cylinder is arranged on the upper end surface of the first lifting connecting plate, the second linear bearings are respectively arranged in the second linear bearings, and the upper ends of the second guide shafts upwards penetrate through the sliding plate, a guide shaft rear connecting plate is connected between the upper end surfaces of the second guide shafts, and the lower ends of the second guide shafts are connected with a first lifting connecting plate which is horizontally arranged;
the overturning driving mechanism comprises a second lifting connecting plate, an overturning air cylinder seat plate, an overturning air cylinder, bearing seats, bearings, a coupler, a rotating shaft and a 90-degree overturning limiting assembly, the second lifting connecting plate is horizontally arranged and fixedly connected with the first lifting connecting plate, the overturning air cylinder seat plate is vertically arranged at one end of the second lifting connecting plate downwards, the overturning air cylinder is mounted on the overturning air cylinder seat plate, two bearing seats are arranged on the lower end face of the second lifting connecting plate at intervals, the bearings are mounted in the bearing seats, the rotating shaft is arranged between the two bearings, the rotating shaft is connected with the overturning air cylinder through the coupler, and the 90-degree overturning limiting assembly is arranged on the outer side of the bearing seat far away from the overturning air cylinder;
the 90-degree overturning limiting assembly comprises two limiting heads and limiting blocks, the two limiting heads are arranged at intervals, the upper ends of the limiting heads are fixed on the lower end face of the second lifting connecting plate, the limiting blocks are right-angle blocks, the limiting blocks are connected with the rotating shaft, one right-angle face of each limiting block is in contact with one limiting head, and the other right-angle plate of each limiting block is in contact with the other limiting head when the rotating shaft rotates 90 degrees;
the material taking mechanism comprises a turnover connecting plate, a material taking gas claw seat plate, a material taking gas claw, a mechanical claw and a material pressing block, wherein the plate surface of the turnover connecting plate is connected with a rotating shaft, the lower end surface of the turnover connecting plate is connected with the material taking gas claw seat plate, a plurality of material taking gas claws are arranged on the plate surface of the material taking gas claw seat plate at intervals, two mechanical claws which are matched with each other are arranged on each material taking gas claw, the mechanical claws are bent in an L shape, the material pressing blocks which correspond to the positions of the material taking gas claws one to one are arranged on the turnover connecting plate at intervals, and the tail ends of the material pressing blocks extend into inner cavities formed by the two mechanical claws corresponding to the positions of the material pressing blocks.
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113102976A (en) * | 2021-03-16 | 2021-07-13 | 烟台凯博机械自动化设备有限公司 | Pretreatment system before assembly of three-way pipe of infusion apparatus |
CN114770095A (en) * | 2022-04-27 | 2022-07-22 | 烟台凯博机械自动化设备有限公司 | Tee joint feeding and assembling device and method |
CN115123813A (en) * | 2022-07-19 | 2022-09-30 | 苏州英维特精密机械有限公司 | Automobile parts is with feeding agencies |
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2021
- 2021-03-16 CN CN202120539093.0U patent/CN215316771U/en active Active
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN113102976A (en) * | 2021-03-16 | 2021-07-13 | 烟台凯博机械自动化设备有限公司 | Pretreatment system before assembly of three-way pipe of infusion apparatus |
CN114770095A (en) * | 2022-04-27 | 2022-07-22 | 烟台凯博机械自动化设备有限公司 | Tee joint feeding and assembling device and method |
CN114770095B (en) * | 2022-04-27 | 2024-03-01 | 烟台凯博机械自动化设备有限公司 | Tee joint feeding assembly device and method |
CN115123813A (en) * | 2022-07-19 | 2022-09-30 | 苏州英维特精密机械有限公司 | Automobile parts is with feeding agencies |
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Denomination of utility model: Automatic processing production line for three-way pipe assembly of infusion set Effective date of registration: 20220707 Granted publication date: 20211228 Pledgee: Yantai financing guarantee Group Co.,Ltd. Pledgor: YANTAI KAIBO AUTOMATION TECHNOLOGIES Co.,Ltd. Registration number: Y2022980009996 |
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