CN214610011U - Go up cup device and medical equipment - Google Patents

Abstract

The embodiment of the utility model relates to the technical field of medical detection equipment, and discloses a cup feeding device and medical equipment, which comprise a holding box, wherein the holding box is provided with a holding cavity, the holding cavity is used for accommodating a reaction cup, and the side wall of the holding cavity is provided with a first through hole; one end of the material conveying plate is inserted into the accommodating cavity from the first through hole, and a material groove is formed in one surface of the material conveying plate, which is away from the cavity bottom of the accommodating cavity; the feeding mechanism is used for pushing the reaction cup in the accommodating cavity into the material groove; the controller, and shake cup mechanism, including rocking plate subassembly and rocking plate cylinder, the rocking plate subassembly rotates and sets up in the holding intracavity, and the rocking plate subassembly divide into first holding chamber and second holding chamber with the holding chamber, the rocking plate subassembly is connected in the piston rod of rocking plate cylinder, the rocking plate cylinder is connected with the controller electricity, when the rocking plate subassembly is in first preset position, the reaction cup is held in first holding chamber, when the rocking plate subassembly is rotated to second preset position by first preset position, the reaction cup falls into the second holding intracavity by first holding chamber under the effect of self gravity.

Description

Go up cup device and medical equipment

Technical Field

The embodiment of the utility model provides a relate to medical treatment check out test set technical field, especially relate to a go up cup device and medical equipment.

Background

In vitro diagnosis, samples (blood, body fluid or tissue, etc.) are taken out of human body and tested, and compared with the distribution level of normal people, the corresponding functional state and abnormal condition of the patient are determined, and the result is used as the basis for diagnosis and treatment.

In order to complete the detection process of in vitro diagnosis, samples need to be loaded in reaction cups and then put into a testing instrument for various reaction tests, before the sample detection step, disordered reaction cups can be screened in a feeding device as required and are conveyed to the testing instrument neatly for testing, in the prior art, the reaction cups can be conveyed by adopting a mode that a chain conveying mechanism is matched with a guide groove, the reaction cups borne on a chain are driven to move through the transmission of the chain, and then the reaction cups slide into a material groove and are arranged neatly by means of the self gravity of the reaction cups.

In the process of implementing the present invention, the inventor finds that: the reaction cup placed in the containing cavity is easy to block at the discharge port of the containing cavity, and the maintenance frequency of workers is high.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides a go up cup device to solve the technical problem that the in-process of going up the cup device that exists often blocks up of going up the cup among the background art.

In order to solve the above technical problem, the utility model discloses a technical scheme that embodiment adopted is: provided is a cup mounting device, including: the accommodating box is provided with an accommodating cavity, the accommodating cavity is used for accommodating the reaction cup, and the side wall of the accommodating cavity is provided with a first through hole; one end of the material conveying plate is inserted into the accommodating cavity from the first through hole, and a material groove is formed in one surface of the material conveying plate, which is away from the cavity bottom of the accommodating cavity; the feeding mechanism is used for pushing the reaction cup in the accommodating cavity into the material groove; the controller reaches and shakes cup mechanism, including shaking the board subassembly and shaking cup motor, shake the board subassembly rotate set up in the holding intracavity, and shake the board subassembly will the holding chamber divide into first holding chamber and second holding chamber, shake the board subassembly connect in shake the axis of rotation of cup motor, shake cup motor with the controller electricity is connected, when shaking the board subassembly and being in first default position, the reaction cup hold in first holding chamber, when shaking the board subassembly and rotating to the second default position by first default position, the reaction cup by under the effect of self gravity first holding chamber falls into in the second holding intracavity.

Optionally, the cup shaking mechanism further comprises an elastic element, one end of the elastic element is fixed to the cup shaking motor, the other end of the elastic element is fixed to the shaking plate, and the shaking plate is reset to the first preset position from the second preset position under the action of the elastic element.

Optionally, the side wall of the accommodating cavity is provided with a mounting hole; the rocking plate assembly comprises a rocking arm and a rotating plate, the rotating plate is rotatably arranged in the accommodating cavity, one end of the rocking arm is detachably connected with the rotating plate, and the other end of the rocking arm extends out of the mounting hole and is fixedly arranged on a rotating shaft of the cup rocking motor.

Optionally, the cup shaking mechanism further comprises a first detection device, the first detection device is arranged in the first accommodating cavity, and the first detection device is electrically connected with the controller.

Optionally, the cup shaking mechanism further comprises a second detection device, the second detection device is arranged in the second accommodating cavity, and the second detection device is electrically connected with the controller.

Optionally, the shaking direction of the shaking plate is perpendicular to the groove body direction of the trough.

Optionally, the feeding mechanism includes a feeding member, a driving assembly and a material supporting assembly; one end of the feeding part is inserted into the containing cavity from the second through hole, the feeding part is attached to the material conveying plate, a first inclined surface is arranged at the end part of one end of the feeding part and is a plane inclined towards the direction of the material conveying plate, the driving assembly is connected with the feeding part and is used for driving the feeding part to reciprocate between the second through hole and a preset feeding position so as to push the reaction cup in the containing cavity into the material groove, and the material supporting assembly is arranged in the material groove and is used for supporting the reaction cup pushed into the material groove so as to enable the reaction cup to stand in the material groove.

Optionally, the first inclined plane is further inclined from one end of the feeding member far away from the second through hole to one end of the feeding member close to the second through hole.

Optionally, the second through hole is located at a first edge of the cavity bottom of the accommodating cavity, and a plane of the cavity bottom of the accommodating cavity is inclined from a second edge to the first edge, where the second edge is an edge of the cavity bottom of the accommodating cavity opposite to the first edge.

In order to solve the above technical problem, the utility model discloses another technical scheme that embodiment adopted is: a medical device is provided, which comprises the cup mounting device.

Different from the prior art, the embodiment of the utility model provides an go up cup device and medical equipment. Through set up the rocking plate in the holding intracavity and filter the reaction cup that drops into, the condition that has reduced the reaction cup and all fall into the holding intracavity and block up the discharge gate takes place, it is concrete, the reaction cup that drops into falls into first holding chamber, the axis of rotation of cup motor is shaken in controller control rotates, and then drive the rocking plate and rotate, so that the rocking plate rotates to the second preset position by first preset position, when being in the second preset position, first holding chamber and second holding chamber intercommunication, the reaction cup falls into the second holding intracavity because of the effect of self gravity down.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings needed to be used in the embodiments of the present application will be briefly described below, and it is obvious that the drawings described below are only some embodiments of the present application, and it is obvious for a person skilled in the art to obtain other drawings based on the drawings without any creative effort.

Fig. 1 is a schematic structural view of a cup mounting device provided by the present invention;

FIG. 2 is a schematic structural view of the upper cup apparatus shown in FIG. 1 from another perspective;

FIG. 3 is a schematic structural view of a receiving box of the cup mounting apparatus of FIG. 1;

FIG. 4 is a schematic view of the holding box of FIG. 3 assembled with a rocking cup assembly;

FIG. 5 is a schematic structural view of a material conveying plate of the cup feeding device of FIG. 1;

FIG. 6 is a schematic structural view of a cup feeding mechanism of the cup feeding device of FIG. 1;

FIG. 7 is a schematic view of the structure of the loading member at the second through hole of the cup loading device in FIG. 1;

FIG. 8 is a schematic structural view of a feeding member of the cup feeding device of FIG. 1 between a second through hole and a preset feeding position;

fig. 9 is a schematic structural view of a feeding member of the cup feeding device of fig. 1 at a preset feeding position.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described in more detail with reference to the accompanying drawings and specific embodiments. It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for descriptive purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 and 2, the cup loading device includes a first frame (not shown), a second frame 20, a containing box 30, a material conveying plate 40, a material loading mechanism 50, a transferring mechanism 60, an identifying mechanism (not shown), and a controller (not shown). The feeding mechanism 50 is fixedly arranged on the first rack, the accommodating box 30 is positioned above the feeding mechanism 50, the accommodating box 30 is arranged at one end of the material conveying plate 40, the other end of the material conveying plate 40 and the transfer mechanism 60 are fixedly arranged on the second rack 20, and the controller is electrically connected with the feeding mechanism 50, the transfer mechanism 60 and the identification mechanism respectively.

Referring to fig. 3 and fig. 1 and 2 together, the accommodating box 30 is an inverted right trapezoid, and the accommodating box 30 includes a first side plate (not shown), a second side plate (not shown), a third side plate (not shown), and a fourth side plate (not shown). The first side plate, the second side plate, the third side plate and the fourth side plate jointly enclose a containing cavity 30a with an opening, the opening can be used as a feeding port for putting in reaction cups, the containing cavity 30a is used for containing the reaction cups put in from the feeding port, the side wall of the fourth side plate is provided with a first through hole 310, the first through hole 310 is used for allowing the reaction cups contained in the containing cavity 30a to flow out and allowing the containing box 30 to be installed on the material conveying plate 40, the bottom end of the first side plate bends towards the third side plate and is respectively connected with the bottom end of the second side plate, the bottom end of the third side plate and the bottom end of the fourth side plate to form a cavity bottom of the containing cavity 30a, the first edge of the cavity bottom of the containing cavity 30a is provided with a second through hole 320, the plane of the cavity bottom of the containing cavity 30a inclines towards the first edge from the second edge, the second edge is an edge opposite to the first edge in the cavity bottom of the containing cavity, and the second through hole 320 is adjacent to the first through hole 310, the second through hole 320 is used for inserting the feeding mechanism into the accommodating cavity. For convenience of illustration, the first through hole 310 for flowing out of the reaction cup accommodated in the accommodating chamber is defined as a discharge hole.

In order to reduce the occurrence of the reaction cup jamming in the accommodating cavity, referring to fig. 4 and also referring to fig. 3, in the embodiment of the present application, the cup loading device further includes a cup shaking mechanism 70. The cup shaking mechanism 70 comprises a cup shaking motor 710 and a shaking plate assembly 720, the shaking plate assembly 720 is rotatably disposed in the accommodating cavity 30a, the accommodating cavity 30a is divided into a first accommodating cavity 310a and a second accommodating cavity 320a by the shaking plate assembly 70, the first accommodating cavity 310a is located above the second accommodating cavity 320a, the first accommodating cavity 310a is communicated with the second accommodating cavity 320a through a circulation channel, the cup shaking motor 710 is disposed outside the accommodating box 30, a piston rod of the cup shaking motor 710 is connected with a part of the shaking plate assembly 720 extending out of the accommodating box 30 to drive the shaking plate assembly 720 to rotate around the rotation shaft, the shaking plate assembly 720 rotates to a first preset position, the first accommodating cavity 310a is isolated from the second accommodating cavity 320a, a reaction cup put through the material inlet can only fall into the first accommodating cavity 310a but can not fall into the second accommodating cavity 320a, the shaking plate assembly 720 rotates to a second preset position, the first accommodating cavity 310a is communicated with the second accommodating cavity 320a, the reaction cup in the first receiving chamber 310a rolls to the flow channel between the first receiving chamber 310a and the second receiving chamber 320a under the rotation of the rocking plate assembly 720, and falls into the second receiving chamber 320a under the self gravity. The first preset position refers to a position where the rocking plate is located when the rotating shaft of the cup rocking motor is not driven, and the second preset position refers to a position where the rocking plate is located when the rotating shaft of the cup rocking motor is driven to the highest point.

It can be understood that, in the embodiment of the present application, in order to achieve the resetting of the piston rod, the cup shaking mechanism 70 further includes an elastic member 730, one end of the elastic member 730 is fixed to the cup shaking motor 710, and the other end of the elastic member 730 is fixed to the shaking plate assembly 710, when the piston rod is driven to the highest point, the elastic member 730 is stretched, under the action of the elastic member 730, the piston rod is reset from the highest point to the position when the piston rod is not driven, and the shaking plate assembly 710 is also reset from the second preset position to the first preset position. In addition, for avoiding the direct silo that drops from first appearance chamber of reaction cup and cause the reaction cup to lie cup, card cup or fall the condition of cup and take place, in this application embodiment, shake the cell body direction of the perpendicular to silo of the direction of shaking of board subassembly 710, of course, in other embodiments of this application, shake the cell body direction that the direction of shaking of cup subassembly 710 can be on a parallel with the silo.

Further, the lateral wall of holding chamber still is equipped with the mounting hole, shakes board subassembly 720 and still includes rocking arm 7210 and commentaries on classics board 7220, changes board 7220 and rotates and set up in holding chamber 30a, and rocking arm 7210's one end detachably connects in commentaries on classics board 7220, and rocking arm 7210's the other end stretches out and sets firmly in the piston rod of shaking the cup motor from the mounting hole.

Referring to fig. 5 and fig. 1 and 2, one end of the material transporting plate 40 is inserted into the accommodating cavity from the first through hole 310 and abuts against the side wall of the second side plate, the other end of the material transporting plate is fixed to the second frame 20, one side surface of the inserted material transporting plate 40 is attached to the side wall of the third side plate, and the other side surface of the inserted material transporting plate 40 is attached to the feeding mechanism 50, wherein the material transporting plate 40 partially shields the discharge hole, so that the reaction cups flow out from the non-shielded portion of the discharge hole. Further, a trough 40a is arranged on a surface of the material transporting plate 40, which is away from the bottom of the second accommodating cavity 320a, the trough 40a is a through trough, a plane of a bottom of the trough 40a is inclined from one end of the material transporting plate 40 to the other end of the material transporting plate 40, a third through hole 410 is further arranged on a surface of the material transporting plate 40, which is close to the bottom of the second accommodating cavity 320a, the third through hole 410 is communicated with the bottom of the trough 40a, and the shape of the third through hole 410 is matched with that of the feeding mechanism 50, so that the feeding mechanism 50 extends out from the third through hole 410 to close or open the first through hole 30 b.

In order to reduce the sliding speed of the reaction cups in the material grooves, in the embodiment of the present application, the plane of the bottom of the material groove 40a close to one end of the material conveying plate 40 is a smooth plane, and the plane of the bottom of the material groove 40a far away from one end of the material conveying plate 40 is a rough plane. However, in other embodiments of the present application, the inclined angle of the trough 40a near the material conveying plate 40 is larger than the inclined angle of the trough 40a far from the material conveying plate 40, and the reaction cup can slide rapidly from the end of the trough 40a near the material conveying plate to the end far from the material conveying plate under the action of gravity and slowly approach to the end far from the material conveying plate. In addition, in order to increase the time for the toppling over of the poured reaction cups, in the embodiment of the present application, the wall of the trough 40a is provided with a protrusion (not shown) which extends in a wave shape from one end of the material conveying plate 40 to the other end of the material conveying plate 40.

In order to facilitate the reaction cup to flow out of the discharge port and then enter the feed chute, the discharge port of the containing box is abutted with a guide plate (not shown), the guide plate is arranged above the discharge port, a groove (not shown) is formed in the guide plate, and an opening of the groove is opposite to the first through hole. Furthermore, in order to avoid the blockage of the reaction cup on the material storage port, a cup blocking component (not shown) is arranged in the groove and comprises a blocking rod (not shown) and a stop block (not shown), one end of the blocking rod penetrates through the top of the groove, the other end of the blocking rod is connected to the stop block, and the stop block can open or close the material storage port under the sliding action of the blocking rod.

Referring to fig. 6, the feeding mechanism 50 includes a driving assembly 510, a feeding member 520, and a material supporting assembly 530, the driving assembly 510 is fixed to the first frame, and the feeding member 520 and the material supporting assembly 530 are both fixed to the driving assembly 510.

Specifically, the driving assembly 510 includes a base 5110, a side plate 5120, a driving belt 5130, a first rotating wheel 5140, a second rotating wheel 5150, and a motor 5160. The base 5110 is fixedly arranged on the first frame, the side plate 5120 is vertically fixed on the base 5110, the first rotating wheel 5140 is rotatably arranged on the side plate 5120, a mounting hole is formed in the side plate 5120, the opening position of the mounting hole corresponds to the position of the first rotating wheel 5140, the motor 5160 is fixed on the side plate 5120, the rotating shaft of the motor 5160 extends out of the mounting hole, the second rotating wheel 5150 is sleeved on the rotating shaft, the driving belt 5130 is sleeved on the first rotating wheel 5140 and the second rotating wheel 5150, the motor 5160 rotates by driving the second rotating wheel 5150, and the second rotating wheel 5150 drives the driving belt 5130 to reciprocate along the length direction of the side plate. It is understood that the motor 5160 may be a driving device with other structure, such as an air cylinder.

To achieve the reciprocating motion of the centralizer assembly 530, in the present embodiment, the drive assembly 510 further includes a first slider 5170 and a guide rod 5180. The first slider 5170 is fixed to one side of the transmission belt 5130 close to the other end of the material conveying plate 40, the first slider 5170 is provided with a sliding hole, the guide rod 5180 is vertically arranged on the base 5110, and the first slider 5170 penetrates through the sliding hole and is arranged on the guide rod 5180, so that the transmission belt 5130 drives the first slider 5170 to slide in the length direction of the guide rod 5180. Further, for preventing the movement path of the first slider 5170 from deviating, the first slider 5170 is further provided with a bump, the bump is inserted into the through hole of the side plate, the through hole is a strip-shaped hole, and the extending direction of the strip-shaped hole is parallel to the length direction of the side plate.

In addition, in order to realize the reciprocating motion of the feeding member 520 between the second through hole 320 and the preset feeding position, in this embodiment of the application, the driving assembly 510 further includes a guide rail 5190 and a second slider 5191, the guide rail 5190 is disposed on the side plate 5120, the guide rail 5190 is perpendicular to the base 5110, the other end of the feeding member 520 is fixed to the second slider 5191, the second slider 5191 is fixed to a side of the transmission belt 5130 away from the material conveying plate 40, and the second slider 5191 is disposed through the guide rail 5190, so that the transmission belt 5130 drives the second slider 5191 to slide along the length direction of the guide rail 5190. Further, in order to prevent the second slider 5191 from moving away from the guide rail 5190, a first blocking member (not shown) and a second blocking member (not shown) are respectively disposed at two ends of the guide rail 5190 for blocking the sliding of the second slider 5191, and in addition, in order to enable the feeding member 520 to stay in the second through hole 320, a supporting block for the second slider 5191 to be padded is further disposed on the base.

For the above-mentioned loading element 520, one end of the loading element 520 is inserted into the receiving cavity 310a from the second through hole 320 and is flush with the plane of the cavity bottom of the second receiving cavity 320a under the action of the supporting block, the other end of the loading element 520 is fixed to the second slider 5191, one side surface of one end of the loading element 520 inserted into the second receiving cavity 320a is attached to the other side surface of the material transporting plate 40, one end of the loading element 520 is further provided with a first inclined surface 520a, the first inclined surface 520a is a plane inclined towards the direction of the material transporting plate, the first inclined surface 520a is also inclined towards one end close to the second through hole 320 from one end of the loading element 520 far away from the second through hole 320, and the inclined angle is consistent with the inclined angle of the cavity bottom plane. Under the action of the motor 5160 driving the transmission belt 5130 to rotate, one side of the transmission belt 5130 far away from the other end of the material conveying plate 40 moves from the second rotating wheel 5150 towards the first rotating wheel 5140, and then reciprocates between the second through hole 320 and the preset material loading position, so as to push the reaction cup in the second accommodating cavity 320a into the trough 40 a.

As for the material holding assembly 530, please continue to refer to fig. 6, the material holding assembly 530 includes a material holding plate 5310 and a connecting rod 5320, one end of the connecting rod 5320 is fixed on the first sliding block 5170, one end of the material holding plate 5310 is connected to the other end of the connecting rod 5320, the other end of the material holding plate 5310 is inserted into the trough 40a from the third through hole 410, an end of the other end of the material holding plate 5310 is provided with a second inclined surface 5310a, the second inclined surface 5310a is a plane inclined toward the material conveying plate 40, the second inclined surface 5310a is further inclined toward one end close to the second through hole 320 from one end of the trough body of the trough 40a, and the other end of the material holding plate 5310 reciprocates between the bottom of the trough 40a and the notch under the driving of the connecting rod 5320 by the driving belt 5130 to hold the reaction cup pushed into the trough 40a, so that the reaction cup stands in the trough 40 a.

It should be noted that, in this embodiment of the application, one side of the belt 5130 away from the other end of the material conveying plate is connected to the second slider 5191, one side of the belt 5130 close to the other end of the material conveying plate is connected to the first slider 5170, and the first slider 5170 is located above the second slider 5191, that is, the feeding member 520 and the material supporting plate 5310 move synchronously and oppositely under the driving action of the same belt, when the feeding member 520 moves upwards, the feeding member 520 pushes a reaction cup to fall into the material slot 40a, and when the feeding member 520 moves downwards, the material supporting plate 5310 rises to support the reaction cup falling into the material slot 40a, so that the reaction cup stands upright in the material slot 40 a.

For avoiding the cell body that the reaction cup in silo 40a breaks away from silo 40a, in this application embodiment, still be equipped with on fortune flitch 40 and enclose the fender (not shown), it includes that the first fender that encloses to enclose that encloses, the second encloses fender and third and encloses the fender, the first fender that encloses is enclosed by the second and is formed by the one end bending type extension that encloses the fender, the first fender that encloses sets up in one of them cell wall of silo, the first fender that encloses flows from one side of silo 40a in order to block the reaction cup, the third encloses the fender and is formed by the other end bending type extension that the second enclosed the fender, the third encloses the fender unsettled setting in one of them cell wall of silo 40a, the third encloses the fender and flows from the opposite side of silo 40a in order to block the reaction cup. However, in other embodiments of the present application, the first enclosure, the second enclosure and the third enclosure can be formed by splicing, and the third enclosure is disposed on another wall of the trough 40a to block the reaction cup from flowing out from another side of the trough.

As for the above-mentioned transfer mechanism, please refer to fig. 1, the transfer mechanism 60 includes a support 610, a turntable 620 and a rotating assembly 630, the support 610 is installed on the second support 20, the rotating assembly 620 is fixedly installed on the support 610, the rotating assembly 620 is connected to the turntable 630, the rotating assembly 620 is used for driving the turntable 630 to rotate, the turntable 630 is located at the other end of the material conveying plate 40, the whole turntable 630 is T-shaped, a shaft hole for connecting the rotating assembly 630 is formed at the root of the turntable 630, four accommodating notches 630a for clamping the parts of the reaction cups are formed at the end of the turntable 630, the four accommodating notches 630a are uniformly distributed at the end of the turntable 630, when the rotating assembly 620 drives the turntable 630 to rotate to a preset third position, the receiving notch 630a is aligned with an end of the trough 40a far from the receiving cavity 30a, and the cuvette in the trough 40a falls into the receiving notch 630a and is carried in the receiving notch 630 a. It should be understood that in other embodiments of the present application, the number of the receiving notches 630a is not limited to four, for example, the number of the receiving notches 630a may be one or more than two, and when the number of the receiving notches 630a is more than two, the receiving notches 630a may be uniformly distributed at the end of the turntable or distributed at different intervals. In addition, the rotating assembly 630 is a servo motor in the embodiment of the present application.

It can be understood that, in order to identify the reaction cup in the inverted cup state, in the embodiment of the present application, the cup edge of the reaction cup is implemented by using a principle that there is a height difference between the cup edge of the reaction cup and the identification mechanism, specifically, the controller is electrically connected to the rotating assembly 630, the controller is configured to control the rotating assembly 630 to rotate in the first direction after the turntable 620 is loaded on the reaction cup at the preset third position, so that the turntable 630 carries the reaction cup from the preset third position to the preset first position, the identification mechanism identifies whether the reaction cup carried by the turntable 620 is inverted, and when the reaction cup carried by the turntable is identified to be inverted, the controller controls the rotating assembly 630 to rotate in the second direction, so that the turntable 630 carries the reaction cup from the preset first position to the preset second position. In other embodiments of the present application, a manipulator may be used to grasp the reaction cup in the inverted state. It should be noted that the preset first position refers to the reaction cup moving to the side of the position where the identification mechanism is located, the preset second position refers to the reaction cup dropping out of the turntable 630 from the accommodating notch 630a, the preset third position refers to one of the accommodating notches on the turntable 630 aligning to the other notch of the trough, the first direction refers to the rotation of the turntable 630 along the rotation axis counterclockwise under the action of the rotation assembly, and the second direction refers to the rotation of the turntable 630 along the rotation axis clockwise under the action of the rotation assembly.

In order to remove the reaction cups in the inverted cup state, in the embodiment of the present application, the transferring mechanism 60 further includes a blocking component 640, the blocking component 640 is fixed to the bracket 610, and the blocking component 640 is configured to push the reaction cups carried in the accommodating notch away from the accommodating notch in the process that the turntable 630 carries the reaction cups to the preset second position. Specifically, the blocking assembly 640 includes a link 6410 and a baffle 6420, one end of the link 6410 is fixed to the bracket 610, the other end of the link 6410 is fixed to one end of the baffle 6420, and the other end of the baffle 6420 extends above the turntable 630, and most of the reaction cups sliding through the trough 40a are in an inverted cup state, and when the reaction cups are inverted in the accommodating notches 630a, the height of the baffle 6420 is lower than that of the inverted reaction cups, so that the inverted reaction cups are pushed out of the turntable 630 by the baffle 6420.

In order to prevent the reaction cups from falling off the accommodating gaps before moving to the identification mechanism, in the embodiment of the present application, the transfer mechanism 60 further includes a guide 650, the guide 650 is mounted on the bracket 610, a surface of the guide 650 facing the turntable 630 is provided with a bearing step 650a, the bearing step 650a is located below the turntable 630, and the bearing step 650a is located between the preset first position and the preset second position, when the turntable 630 carries the reaction cups between the preset third position and the preset second position, the reaction cups on the turntable 630 are borne on the bearing step 650 a.

In order to facilitate the sequenced reaction cups to flow to the inspection instrument, in the embodiment of the present application, the cup loading device further includes a cup taking mechanism (not shown), the cup taking mechanism is connected to the controller, the controller is configured to control the cup taking mechanism to take away the reaction cups loaded in the accommodating gaps when the identification mechanism identifies that the reaction cups loaded on the turntable are upright, further, the cup taking mechanism is a manipulator or a gripper, and the identification mechanism is an image identification device.

In order to further reduce the occurrence of the situation that the reaction cup is stuck, crossed or inverted, the recognition mechanism includes a first sensor (not shown), a second sensor (not shown) and a third sensor (not shown), the first sensor is disposed in the first accommodating cavity 310a, the second sensor is disposed in the second accommodating cavity 320a, the third sensor is disposed on the material conveying plate, the first sensor is used for detecting whether the reaction cup exists in the first accommodating cavity 310a, the second sensor is used for detecting whether the reaction cup exists in the second accommodating cavity 320a, and the third sensor is used for detecting whether the reaction cup exists in the material trough 40 a. The motor, the cup shaking motor, the first sensor, the second sensor and the third sensor are respectively connected with the controller. The controller is used for controlling the motor to work or stop working according to detection signals of the first sensor, the second sensor and the third sensor.

For the convenience of the reader to understand the present application, the following brief description of the operation of the cup mounting device in the above embodiment is provided with reference to the above drawings and fig. 7, 8 and 9:

the first sensor is arranged in the first accommodating cavity and can detect whether the first accommodating cavity has the reaction cup, and if the first sensor does not have a detection signal, the controller can automatically remind a worker to enable the worker to add the reaction cup into the first accommodating cavity.

Pour into a plurality of reaction cup into first appearance intracavity through putting the mouth in, the reaction cup is mixed and disorderly unordered state at first appearance intracavity, is in the second and holds the second sensor of intracavity and does not have detection signal, and controller control shakes cup motor drive rocking plate to make the reaction cup hold the intercommunication passageway between the chamber by first appearance chamber and second and fall into the second under the effect of gravity and hold the intracavity, be in the second and hold the second sensor of intracavity and have detection signal, controller control shakes the cup motor and stops the drive rocking plate.

The third sensor sets up on the curb plate, can detect whether response cup in the silo, if the third sensor does not have the detected signal, controller driving motor rotates, and then drive material loading spare at the second through-hole with predetermine material loading position reciprocating motion, and hold up the flitch at the notch of silo and predetermine material holding position reciprocating motion, because the second holds the chamber bottom in chamber and is the inclined plane, the one end of material loading spare can fall into because of the effect of self gravity to the response cup, and in material loading spare reachs predetermineeing material loading position and fall into the silo of next-door neighbour's fortune flitch often, then, material loading spare can move to second through-hole department under the effect of drive belt, meanwhile, hold up the flitch also reachs predetermineeing material holding position under the effect of drive belt, will fall into the reaction cup of silo and right.

The reaction cup after righting slips off from the one end of silo earlier fast under the action of gravity, slowly the other end of landing to the silo again, and aim at the accommodate breach of the other end of silo and will transport to predetermineeing the primary importance from the third position of predetermineeing from the reaction cup of silo other end landing, whether stand upside down by identification mechanism discernment reaction cup, when identification mechanism discerned the reaction cup that the carousel bore and fell, controller control carousel rotated the reaction cup to predetermineeing the second position, and the reaction cup that is in predetermineeing the second position can fall into in the waste cup box under the effect of gravity, when identification mechanism discerned the reaction cup that the carousel bore and bore upright, the controller control was got cup mechanism and is carried out the action of cup. And ending the cup feeding process of one reaction cup, and then carrying out the next circulation feeding process according to the flow.

The embodiment of the utility model provides a go up cup device and medical equipment. Screening is carried out to the reaction cup who drops into through setting up the rocking plate in the holding intracavity, reduced the whole condition emergence that falls into the holding intracavity and block up the discharge gate of reaction cup, it is concrete, the reaction cup who drops into falls into first holding chamber, the piston rod of cup motor is shaken in controller control is flexible, and then it rotates to drive the rocking plate, so that the rocking plate rotates to the second preset position by first preset position, when being in the second preset position, first holding chamber and second holding chamber intercommunication, the reaction cup falls into the second holding intracavity because of the effect of self gravity down.

It should be noted that the preferred embodiments of the present invention are described in the specification and the drawings, but the present invention can be realized in many different forms, and is not limited to the embodiments described in the specification, and these embodiments are not provided as additional limitations to the present invention, and are provided for the purpose of making the understanding of the disclosure of the present invention more thorough and complete. Moreover, the above technical features are combined with each other to form various embodiments which are not listed above, and all the embodiments are regarded as the scope of the present invention; further, modifications and variations will occur to those skilled in the art in light of the foregoing description, and it is intended to cover all such modifications and variations as fall within the true spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A cup mounting apparatus, comprising:

the accommodating box is provided with an accommodating cavity, the accommodating cavity is used for accommodating the reaction cup, and the side wall of the accommodating cavity is provided with a first through hole;

one end of the material conveying plate is inserted into the accommodating cavity from the first through hole, and a material groove is formed in one surface of the material conveying plate, which is away from the cavity bottom of the accommodating cavity;

the feeding mechanism is used for pushing the reaction cup in the accommodating cavity into the material groove;

a controller, and

shake cup mechanism, including rocking the board subassembly and shake the cup motor, rocking the board subassembly rotate set up in the holding intracavity, and the rocking the board subassembly will the holding chamber divide into first holding chamber and second holding chamber, rocking the board subassembly connect in the axis of rotation of rocking the cup motor, shake the cup motor with the controller electricity is connected, when rocking the board subassembly and being in first preset position, the reaction cup receive hold in first holding chamber, rocking the board subassembly by first preset position rotate to the second when presetting the position, the reaction cup by under the effect of self gravity first holding chamber falls into the second holding intracavity.

2. The cup mounting apparatus according to claim 1,

shake cup mechanism still includes the elastic component, the one end of elastic component is fixed in shake the cup motor, the other end is fixed in shake the board, shake the board and be in under the effect of elastic component by the second preset position reset to first preset position.

3. The cup mounting device as claimed in claim 1, wherein the side wall of the accommodating cavity is provided with a mounting hole;

the rocking plate assembly comprises a rocking arm and a rotating plate, the rotating plate is rotatably arranged in the accommodating cavity, one end of the rocking arm is detachably connected with the rotating plate, and the other end of the rocking arm extends out of the mounting hole and is fixedly arranged on a rotating shaft of the cup rocking motor.

4. The cup mounting apparatus according to claim 1,

the first detection device is arranged in the first accommodating cavity and electrically connected with the controller.

5. The cup mounting apparatus according to claim 1,

the second detection device is arranged in the second accommodating cavity and electrically connected with the controller.

6. The cup mounting device as claimed in any one of claims 1 to 5, wherein the direction of the rocking plate is perpendicular to the direction of the trough body of the trough.

7. The cup mounting device as claimed in claim 1, wherein the accommodating cavity is provided with a second through hole;

the feeding mechanism comprises a feeding part, a driving assembly and a material supporting assembly; one end of the feeding part is inserted into the containing cavity from the second through hole, the feeding part is attached to the material conveying plate, a first inclined surface is arranged at the end part of one end of the feeding part and is a plane inclined towards the direction of the material conveying plate, the driving assembly is connected with the feeding part and is used for driving the feeding part to reciprocate between the second through hole and a preset feeding position so as to push the reaction cup in the containing cavity into the material groove, and the material supporting assembly is arranged in the material groove and is used for supporting the reaction cup pushed into the material groove so as to enable the reaction cup to stand in the material groove.

8. The apparatus as claimed in claim 7, wherein the first inclined surface is further inclined from an end of the loading member away from the second through hole to an end of the loading member close to the second through hole.

9. The cup mounting device according to claim 7 or 8, wherein the second through hole is located at a first edge of the bottom of the accommodating cavity, and a plane of the bottom of the accommodating cavity is inclined from a second edge to the first edge, wherein the second edge is an edge of the bottom of the accommodating cavity opposite to the first edge.

10. A medical device comprising a cup mounting apparatus as claimed in any one of claims 1 to 9.

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