CN217543041U - Vitamin detector - Google Patents

Abstract

The utility model provides a vitamin detector, which comprises a housin, be provided with the detection head on the casing, install the support on the casing, it installs on the support to detect the head, one side that the detection head was kept away from to the support is connected with the landing slab, is provided with push away groove and standing groove side by side on the landing slab, and the standing groove setting is in the one side that is close to the support, and standing groove and push away are provided with first passageway between the groove, the standing groove is kept away from the one end that pushes away the groove and is provided with the second passageway, is provided with the test paper storehouse in the standing groove, the one end demountable installation in the standing groove of test paper storehouse, the lower extreme both sides in test paper storehouse are provided with first export and second export respectively, first export and first passageway intercommunication set up, the second export sets up with second passageway intercommunication, it is provided with the slidable push pedal to push away in the groove, first passageway to second passageway reciprocating motion can be followed to the push pedal. The automation level of the equipment is improved, the operation steps are simplified, and the pollution caused in the process of manually installing the electrode plate is reduced.

Description

Vitamin detector

Technical Field

The utility model relates to a vitamin detector, specifically speaking relates to a vitamin detector.

Background

The world health organization reports that 135 common human diseases occur, 106 of which are associated with inadequate vitamin intake. If the human body is lack of vitamins or the intake of the vitamins is unbalanced, other nutrients cannot be smoothly absorbed and utilized by the human body, so that various diseases are caused, and even death can be caused seriously.

Latent vitamin deficiency disease is a blind spot in modern medicine, and 1 of about 3 people is supposed to be in a latent vitamin deficiency state by experts, especially pregnant women, children and the old, and the latent deficiency rate is high. Among the most severe deficiencies are vitamins A, B2 and D; the common deficiency is a plurality of vitamins such as vitamin B1, B6, B9, vitamin C and the like. The vitamin blood concentration monitoring (TDM) is a win-win project of social benefit and economic benefit, and has great clinical detection significance.

The existing vitamin detection equipment mostly adopts single-channel, four-channel and five-channel detection in terms of channel quantity, and the working principle of the existing vitamin detection equipment comprises a secondary differential potential dissolution method, a chromatography-mass spectrometry method, an electrochemiluminescence method, a fluorescence immunochromatography method, a microbiological method and the like. However, a machine still can't realize the whole detection of vitamin commonly used, and current electrode slice needs independent package usually, electrode slice after the packing is ready-to-use, the electrode slice is placed in the outside of vitamin detector, all take manually, can't cooperate automatic use with the complete machine, the unable automatic machine of electrode slice after the packing gets paper, make the electrode slice easily cause the pollution with external contact, make operating personnel's operating procedure extension, be unfavorable for detection efficiency, after the electrode slice finishes using, generally need manually to take off, the degree of automation of whole machine is low, operating personnel's hand need contact the electrode slice, detection steps are loaded down with trivial details, and easily cause the carry pollution.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the shortcomings of the prior art and provide a vitamin detector.

The purpose of the utility model is achieved through the following technical measures: a vitamin detector is characterized in that: comprises a shell, wherein a plurality of detection heads are arranged on the shell, reagent seats for placing reagent bottles are arranged below the detection heads, the detection heads and the reagent seats are respectively provided with a plurality of detection heads, the detection heads and the reagent seats are arranged in one-to-one correspondence, a display panel is arranged on the shell, a bracket is arranged on the shell, the detection heads are arranged on the bracket, one side of the bracket, which is far away from the detection heads, is connected with a platform plate, the platform plate is provided with a push groove and a placing groove which are arranged side by side, the placing groove is arranged at one side close to the bracket, a first channel is arranged between the placing groove and the push groove, one end of the placing groove, which is far away from the push groove, is provided with a second channel, a test paper bin is arranged in the placing groove, electrode plates are arranged in the test paper bin, one end of the test paper bin is detachably arranged in the placing groove, a first outlet and a second outlet are respectively arranged at two sides of the lower end of the test paper bin, the first outlet is communicated with the first channel, the second outlet is communicated with the second channel, the first outlet and the second outlet are positioned on the same horizontal plane, a slidable push plate is arranged in the push groove and can reciprocate along the first channel to the second channel, the push plate is connected with a first power device for driving the push plate to move, the push plate and the first outlet are positioned on the same horizontal line, one end of the support, far away from the platform plate, is provided with a detection head, one end of the detection head is connected with the support, the other end of the detection head is provided with a detection port, the detection head is connected with a second power device for driving the detection head to rotate or return towards the platform plate, when the detection head rotates towards the platform plate, the detection port and the second channel are positioned on the same horizontal line, and an electrode plate socket is arranged in the detection head, the electrode plate socket is provided with a detection channel, the detection channel is communicated with the detection port, the electrode plate socket is provided with a driving lever, one end of the driving lever is located in the detection channel, the other end of the driving lever is located on the outer side of the detection head, the driving lever is slidably arranged, and the driving lever is connected with a third power device which drives the driving lever to slide towards the detection port.

Preferably, the reagent seat is connected with a fourth power device which drives the reagent seat to move towards or away from the detection head.

As a preferred scheme, one end of the test paper bin, which is connected with the placing groove, is detachably connected with a test paper cover, a sealed test paper cavity is enclosed by the test paper bin and the test paper cover, the test paper cover is connected with the test paper bin in a buckling mode, a pressing plate is arranged in the test paper cavity, one side, close to the test paper cover, of the pressing plate is used for placing an electrode plate, a spring is arranged on the other side of the pressing plate, and the spring is in a compression state.

As a preferred scheme, a fixing frame is arranged in the test paper cavity, the fixing frame comprises vertical plates located on two sides and baffle plates located at the end parts of the two vertical plates, two ends of each baffle plate are fixedly connected with the two vertical plates respectively, the fixing frame is located in the middle of the test paper cavity, the fixing frame and the test paper cover are closed, the electrode plate is located in the fixing frame, the pressing plate is also located in the fixing frame, and the pressing plate is located at one end close to the baffle plates.

As a preferred scheme, the push plate is arranged in a long strip plate shape, one end, far away from the placing groove, of the push plate is connected with a push seat, the push seat comprises a sliding plate connected with the push plate and a driving plate connected with a first gear, the sliding plate is fixedly connected with the push plate through a bolt, the sliding plate is arranged parallel to the push plate in the horizontal direction, the driving plate is arranged on one side of the sliding plate, the driving plate is arranged in the vertical direction, and the first power device is in transmission connection with the driving plate.

As a preferred scheme, the push plate is arranged in a long strip plate shape, one end, far away from the placement groove, of the push plate is connected with a push seat, the push seat comprises a sliding plate connected with the push plate and a driving plate connected with a first gear, the sliding plate is fixedly connected with the push plate through a bolt, the sliding plate is arranged parallel to the push plate in the horizontal direction, the driving plate is arranged on one side of the sliding plate, the driving plate is arranged in the vertical direction, and the first power device is in transmission connection with the driving plate.

As a preferred scheme, the second power device is a second motor, the second motor is installed on the support, the output of second motor is connected with the driving gear, the driving gear meshing has rotating gear, rotating gear also installs on the support, the one end that detects the head and be close to the support is provided with the pivot, the one end of pivot with detect first fixed connection, the other end and rotating gear connection.

As a preferred scheme, a detection plate is arranged in the detection head, one end of the detection plate is close to the rotating shaft, the other end of the detection plate is close to the detection port, the electrode plate socket is arranged at the position, close to the detection port, of the detection plate, an elastic arm is arranged in the detection channel, one end of the elastic arm is fixed to the electrode plate socket, and the other end of the elastic arm is located in the detection channel.

As a preferred scheme, a first sliding groove for sliding the shifting lever is formed in the shell, a second sliding groove for sliding the shifting lever is formed in the electrode plate socket, the first sliding groove and the second sliding groove are arranged in parallel, the first sliding groove and the second sliding groove are both arranged along the movement direction of the electrode plate in the detection head, and the shifting lever is arranged at the end part, far away from the detection port, of the detection channel.

As a preferred scheme, the driving lever is connected with a push rod which drives the driving lever to move along the first sliding groove and the second sliding groove, one end of the driving lever, which is in contact with the push rod, is located on the outer side of the detection head, the push rod is located on one side, away from the detection port, of the driving lever, the third power device is connected with the push rod, the third power device is an electromagnet, the electromagnet comprises an inner coil and an inner iron core, and one end of the inner iron core is located on the outer side of the electromagnet and is fixedly connected with one end, away from the driving lever, of the push rod.

Owing to adopted above-mentioned technical scheme, compare with prior art, the utility model has the advantages that: the detection of the commonly used 9 vitamins is realized by arranging a plurality of detection heads and reagent seats corresponding to the detection heads one by one, the number of detectable samples in single batch detection is large, and the detection speed is high; the placing groove is arranged on the platform plate to place the test paper bin, the push plate pushes the test paper in the test paper bin to slide out to achieve paper taking, the problem that the test paper in the test paper bin of the vitamin detection equipment cannot be automatically taken out of the bin can be effectively solved, the electrode plates are placed in the closed test paper cavity, the springs and the press plate are matched to push the electrode plates to the first outlet and the second outlet end, the electrode plates are sequentially pushed out from the second outlet when the vitamin detection equipment is used, the plurality of electrode plates are placed in the cavity, the whole module is installed in a detection channel of the vitamin detector, the internal electrode plates can be detected for multiple times, operation steps are reduced, the automation degree is improved, the possibility of electrode plate pollution is reduced, and meanwhile, the detection efficiency is improved; the second power device is arranged to drive the detection head to rotate in a reciprocating mode towards the direction of the test paper pushing device, the detection head can rotate automatically, the electrode plate can be installed automatically after the detection head is matched with the test paper pushing structure, and the detection head can reset automatically under the action of the second power device after installation is finished, so that the automation level of equipment is improved, the operation steps are simplified, and pollution caused in the process of installing the electrode plate manually is reduced; the electrode plate after the test is unloaded through the deflector rod, the third power device automatically unloads the electrode plate for detection, manual operation is avoided, the automation degree is improved, the harm of the electrode plate after the test to operators is reduced, the operation is simpler, and the carrying pollution is reduced.

The present invention will be further described with reference to the accompanying drawings and the following detailed description.

Drawings

Fig. 1 is a schematic view of the overall structure of the vitamin detector of the present invention.

Fig. 2 is a schematic view of the inside front structure of the vitamin detector of the present invention.

Fig. 3 is a schematic view of the internal back structure of the vitamin detector of the present invention.

FIG. 4 is a schematic view of the structure of the loading and unloading test paper of the vitamin detector of the present invention.

Fig. 5 is a schematic structural view of a test paper bin of the vitamin detector of the present invention.

Fig. 6 is a schematic view of the sectional structure of the test paper bin of the vitamin detector of the present invention.

Fig. 7 is a schematic diagram of the internal structure of the test paper bin of the vitamin detector of the present invention.

Fig. 8 is a schematic diagram of the upper structure of the test paper bin of the vitamin detector of the present invention.

Fig. 9 is a schematic view of a push plate structure of the vitamin detector of the present invention.

Fig. 10 is a schematic view of the platform plate structure of the vitamin detector of the present invention.

Fig. 11 is a schematic view of the sliding groove structure of the vitamin detector of the present invention.

Fig. 12 is a schematic view of the sectional structure of the platform plate of the vitamin detector of the present invention.

Fig. 13 is a schematic structural view of a vitamin detector head of the present invention.

Fig. 14 is a schematic view of the transmission structure of the vitamin detector head of the present invention.

Fig. 15 is a schematic view of the cross-sectional structure of a vitamin detector of the present invention.

Fig. 16 is a schematic structural view of an electrode plate socket of the vitamin detector of the present invention.

Fig. 17 is a schematic view of a slider structure of the vitamin detector of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The embodiment is as follows: as shown in fig. 1 to 17, the vitamin detector comprises a housing 57, wherein a detection head 12 is arranged on the housing 57, a reagent seat 58 for placing a reagent bottle is arranged below the detection head 12, a plurality of detection heads 12 and reagent seats 58 are arranged, and the detection heads 12 and the reagent seats 58 are arranged in a one-to-one correspondence manner. The casing 57 is provided with the display panel 59, the display panel 59 is provided with the display screen for displaying detection data, as shown in fig. 1, the detection heads are arranged downwards, the lower end parts of the detection heads 12 are provided with the electrode plates 8, the reagent seats 58 are provided with the reagent bottles, and the electrode plates 8 are arranged towards the reagent bottles.

In use, the reagent bottle is mounted in the reagent holder 58, and the blood sample is fully combined with the buffer solution and then added into the reagent bottle. And an electrode plate is arranged in the test paper bin above the device, after the option of 'start' of the screen is clicked, the test paper bin automatically adds the electrode plate to the detection head, and the reagent bottle automatically rises to start detection. After the detection is finished, the electrode slice is automatically knocked down, and the reagent bottle descends. And taking away the used reagent bottle together with the electrode slice. The next detection can be performed.

In the detection process, an electrochemical method is adopted, the object to be detected in the reagent bottle is deposited on the surface of an electrode plate by electrifying, then reverse voltage is applied to dissolve out the deposit, and a current sensor on the electrode plate senses current information to form a dissolution curve. Displaying on a display screen, and determining the content of the substance according to the dissolution process curve. The disposable electrode slice is automatically installed and automatically dropped, so that carrying pollution is prevented, cleaning is not needed, the installation and the disassembly are convenient, and the operation method is simple. Nine channels are used for parallel detection, nine vitamins A, B, B2, B6, B9, B12 and C, D, E can be detected simultaneously, the number of samples can be detected in single batch detection, and the detection speed is high.

As shown in fig. 2-4, a bracket 1 is mounted on the housing 57, the detection head 12 is mounted on the bracket 1, one side of the bracket, which is away from the detection head 12, is connected with a platform board 2, the platform board 2 is fixedly connected with the bracket 1, a push slot 3 and a placement slot 4 are arranged on the platform board 2 side by side, the placement slot 4 is arranged on one side close to the bracket 1, a first channel 5 is arranged between the placement slot 4 and the push slot 3, and a second channel 6 is arranged at one end of the placement slot 4, which is away from the push slot 3. Be provided with test paper storehouse 7 in the standing groove 4, placed electrode slice 8 in the test paper storehouse 7, test paper storehouse 7's one end demountable installation is in standing groove 4, and test paper storehouse 7 can be followed the shell top and taken out or lay in standing groove 4. As shown in fig. 6, a first outlet 9 and a second outlet 10 are respectively disposed on two sides of the lower end of the test paper bin 7, the first outlet 9 is communicated with the first channel 5, the second outlet 10 is communicated with the second channel 6, and the first outlet 9 and the second outlet 10 are located on the same horizontal plane. Be provided with slidable push pedal 11 in the push pedal 3, push pedal 11 can follow first passageway 5 to 6 reciprocating motion of second passageway, push pedal 11 is connected with the first power device of its motion of drive, push pedal 11 is by first passageway 5 when 6 motion to the second passageway, can pass through first export 9 and the second export 10 of test paper storehouse 7, the electrode piece that will be located between first export 9 and the second export 10 promotes the roll-off, push pedal 11 moves to 6 directions of second passageway promptly, reach inside the test paper storehouse 7 through first export 9 earlier, promote the electrode piece to move to second export 10, push pedal 11 also moves to second passageway 6 simultaneously, move to second passageway 6 department always, the electrode piece is pushed to the 6 outsides of second passageway this moment, realize taking out of electrode piece. The push plate 11 returns to the direction far away from the second channel 6, and after the push plate leaves the test paper bin 7, the electrode plate in the test paper bin 7 falls between the first outlet 9 and the second outlet 10 to prepare for next paper taking.

As shown in fig. 5-8, one end of the test paper bin 7 connected to the placing groove 4 is detachably connected to a test paper cover 17, the test paper bin 7 and the test paper cover 17 enclose a closed test paper cavity 18, in this embodiment, the test paper cover 17 is connected to the test paper bin 7 in a snap-fit manner. As shown in fig. 4-5, the test paper cover 17 is provided with a slip sheet 19 facing the test paper bin 7, the test paper bin 7 is provided with a groove 20 for accommodating the slip sheet 19, the groove 20 is provided with a limiting protrusion, the slip sheet 19 is provided with a limiting groove matched with the limiting protrusion, the test paper bin 7 and the test paper cover 17 are connected in a buckling manner, and the test paper cover is simple in structure and convenient to disassemble and assemble.

As shown in fig. 6 to 7, in this embodiment, the test paper compartment 7 is integrally provided in a rectangular parallelepiped shape, the test paper cavity 18 is provided with a pressing plate 21, one side of the pressing plate 21 close to the test paper cover 17 is provided with the electrode sheet 8, and the other side of the pressing plate 21 is provided with a spring 22. In this embodiment, clamp plate 21 sets up along the horizontal direction, and the electrode slice 8 of placing is parallel with clamp plate 21, and electrode slice 8 places the one end that is close to test paper lid 17, and clamp plate 21 compresses tightly electrode slice 8 under the effect of spring 22, and simultaneously along with the reduction of electrode slice 8, clamp plate 21 can make electrode slice 8 be located the one end of test paper lid 17 all the time.

As shown in fig. 6, a mounting hole 23 is formed in one end of the test paper bin 7, which is away from the test paper cover 17, the mounting hole 23 is a blind hole and is arranged toward the opening of the test paper cavity 18, one end of the spring 22 is located in the mounting hole 23, and the other end of the spring 22 is in contact with the pressing plate 21. In this embodiment, the number of the mounting holes 23 is two, the number of the corresponding springs 22 is two, the number of the pressing plates 21 is one, and the two springs 22 are symmetrically arranged in the horizontal direction, so that the pressing plates 21 are stressed more uniformly and move more stably.

As shown in fig. 6-7, a fixing frame 24 is disposed in the test paper cavity 18, the fixing frame 24 includes vertical plates 25 located at two sides and baffle plates 26 located at end portions of the two vertical plates 25, two ends of the baffle plates 26 are respectively fixedly connected with the two vertical plates 25, the fixing frame 24 is located at a middle position of the test paper cavity 18, one end of the fixing frame 24 is fixedly connected with the test paper cover 17, in this embodiment, one end of each vertical plate 25, which is far away from the baffle plate 26, is fixed to the test paper cover 17, the two vertical plates 25 are respectively located at two sides of the test paper cover 17, a connection portion between the vertical plate 25 and the test paper cover 17 is located at a middle position of the test paper cover 17, the fixing frame 24 and the test paper cover 17 are closed, the electrode plate 8 is located in the fixing frame 24, a distance between the two vertical plates 25 is equal to a width of the electrode plate 8, the pressing plate 21 is also located in the fixing frame 24, and the pressing plate 21 is located at one end near the baffle plate 26, the fixing frame 24 can effectively limit the electrode plate 8, and can assist in arrangement of the electrode plate 8 when the electrode plate 8 is installed, so that the electrode plate 8, and the electrode plate 8 can be orderly arranged. In this embodiment, the two springs 22 are respectively located at two sides of the baffle 26, so that the pressure of the pressing plate 21 is more uniform.

As shown in fig. 6, the first outlet 9 and the second outlet 10 are both connected to the outside at one end and to the test paper chamber 18 at the other end. The first outlet 9 and the second outlet 10 are both arranged in a strip shape, the first outlet 9 and the second outlet 10 are arranged oppositely, the bottoms of the ends, close to the test paper cavity 18, of the first outlet 9 and the second outlet 10 are flush with the inner wall of the test paper cover 17, the electrode plate 8 at the inner bottom can be aligned to the first outlet 9 and the second outlet 10, and the electrode plate 8 can orderly slide out from the second outlet 10. The length of first export 9 and second export 10 equals with the width of electrode slice 8, and the minimum height of second export 10 is not less than the thickness of an electrode slice 8, is not more than the thickness of two electrode slices 8, and electrode slice 8 can be smoothly followed second export 10 roll-off.

As shown in fig. 4, the first outlet 9 is used for being matched with the push plate 11 to push the electrode plate 8 out towards the second outlet 10, and the second outlet 10 is used for sliding the electrode plate 8 outwards from the interior of the test paper cavity 18. The height of the first outlet 9 close to the outside is greater than that of the first outlet close to the test paper cavity 18, which is beneficial to guiding the push plate 11 and enables the push plate 11 to move more smoothly. The one end height that second export 10 is close to test paper chamber 18 is greater than the other end, and like this, when electrode slice 8 outwards moved from test paper chamber 18 and passed through second export 10, the height of second export 10 was greater than electrode slice 8's thickness far away at first, can guarantee that electrode slice 8 enters into second export 10 smoothly, and the height of second export 10 is the same with electrode slice 8's thickness at last, can do effective location to electrode slice 8's roll-off, makes electrode slice 8 according to the orbit roll-off of second export 10, gets into detection mouth 13 smoothly. Electrode slice 8 is promoted electrode slice 8 from the 10 roll-offs of second export in the test paper chamber 18 is entered into with electrode slice 11 from first export 9, later 11 return of push pedal, electrode slice 8 above falls to the below under the effect of spring 22 and clamp plate 21, when needing electrode slice 8, electrode slice 8 roll-offs are promoted again to push pedal 11, reciprocate in proper order, need not 8 volume extranal packing of electrode slice, and take more swiftly convenient, and reduced electrode slice 8 and external contact, avoid polluting.

As shown in fig. 5 and 7, the indicator arrow 27 is further provided on the indicator cover 17, and the indicator arrow 27 points in the direction from the first outlet 9 to the second outlet 10, indicating the sliding-out direction of the electrode sheet 8, so that when the indicator cover is mounted, one end of the first outlet 9 corresponds to the push piece, thereby preventing the indicator cover from being reversely mounted.

As shown in fig. 7, a spring guide groove 28 is formed in the test paper cover 17, the spring guide groove 28 is formed by being recessed towards a direction away from the test paper cavity 18, in this embodiment, the spring guide grooves 28 are formed on two sides of the test paper cover 17, and two sets of spring guide grooves 28 are provided, the two sets of spring guide grooves 28 respectively correspond to two springs one by one, and when the number of electrode pads remaining in the test paper cover 17 is small, the springs can be located in the spring guide grooves 28 to continuously push the push plate until the electrode pads are completely pushed out.

In the using process, the test paper cover 17 is opened, the electrode plates 8 are sequentially and horizontally placed into the test paper bin 7, and after the test paper cover 17 is buckled, the test paper cover 17 is placed downwards. The first outlet 9 is arranged towards the push plate according to the marked arrow 27. The spring 22 will press against the pressure plate 21 and thereby press the electrode pad 8 downwards to ensure that the bottommost electrode pad 8 is aligned with the first outlet 9 and the second outlet 10 on either side of the test paper cover 17.

As shown in fig. 9-12, both sides of the placement groove 4 are provided with positioning beads 29, the test paper compartment 7 is provided with positioning grooves 30 corresponding to the positioning beads 29, during installation, the positioning beads 29 are located in the positioning grooves 30 to ensure that the first outlet 9 is aligned with the first channel 5, and the second outlet 10 is aligned with the second channel 6, in this embodiment, two positioning beads 29 are provided, which are respectively located on both sides of the placement groove 4, and two positioning grooves 30 are also provided, which are respectively located on both sides of the test paper compartment 7, and the positioning beads 29 are spring press-in type and have certain elasticity, when the test paper compartment 7 is installed, the positioning beads 29 are compressed inside the positioning grooves 30, and when the positioning grooves 30 are located at the positioning beads 29, the positioning beads 29 return and compress on the test paper compartment 7 to position the test paper compartment 7, and when the test paper in the test paper compartment 7 is used up and needs to be replaced, the positioning beads do not obstruct the test paper compartment 7 to be taken away.

As shown in fig. 9-11, the pushing plate 11 is in a long plate shape, one end of the pushing plate 11 away from the placing groove 4 is connected with a pushing seat 31, and the output end of the first power device is in transmission connection with the pushing seat 31. The first power device is a first motor 32, and the first motor 32 is fixed on one side of the platform plate 2 departing from the placing groove 4 through a mounting plate. The output end of the first motor 32 is connected with a first gear 33, the push seat 31 comprises a sliding plate 34 connected with the push plate 11 and a driving plate 35 connected with the first gear 33, the sliding plate 34 is fixedly connected with the push plate 11 through a bolt, and the sliding plate 34 is arranged parallel to the push plate 11 along the horizontal direction. The driving plate 35 is disposed on one side of the sliding plate 34, the driving plate 35 is disposed along the vertical direction, the length of the driving plate 35 is much greater than that of the sliding plate 34, in this embodiment, as shown in fig. 9 and 10, the sliding plate 34 is disposed in a square plate shape, and the driving plate 35 is disposed in a long plate shape. One end of the driving plate 35, which is far away from the sliding plate 34, is provided with a sliding tooth 36 which is matched with the first gear 33, the driving plate 35 is positioned above the first gear 33, the sliding tooth 36 is arranged downwards towards the first gear 33, the length of the sliding plate 34 is L1, the length of the driving plate 35 is L0, the length of the sliding tooth 36 is L2, and L2= L0-L1.

As shown in fig. 9 and 10, the corresponding portion of the push slot 3 and the push seat 31 is blank, that is, no other component is provided, so that the smoothness of the sliding of the push seat 31 can be effectively ensured. The first motor 32 drives the first gear 33 to rotate, and the pushing seat 31 drives the pushing plate 11 to slide back and forth along the direction from the first channel 5 to the second channel 6 under the driving of the sliding teeth 36, so as to take out the test paper.

In this embodiment, in order to ensure the stability of the movement of the pushing seat 31, the platform board 2 is provided with the roller 37, the roller 37 is disposed above the driving board 35, and is located on the same vertical line with the first gear 33, the roller 37 is mounted on the platform board 2 through a bolt shaft, the driving board 35 is located between the roller 37 and the first gear 33, in this embodiment, the two rollers 37 are disposed side by side, the driving board 35 can be pressed on the first gear 33 to ensure the stability of the movement, and the roller 37 and the driving board 35 are in rolling friction, so that the friction force is small.

As shown in fig. 11 and 12, the platform board 2 is further provided with a sliding groove 38, the sliding groove 38 is located on a side away from the placing groove 4, and the driving board 35 slides along the sliding groove 38, so that the stability of the sliding of the driving board 35 is ensured.

In this embodiment, the one end of pushing away from standing groove 4 of slot 3 still is connected with spacing photoelectricity 39, and spacing photoelectricity 39 passes through the bolt fastening and deviates from the one side of pushing away slot 3, has seted up photoelectricity hole 40 on pushing away slot 3, and photoelectricity hole 40 is the through-hole. The sliding plate 34 drives the pushing plate 11 to move towards the direction far away from the placing groove 4, when the pushing plate 11 exits the test paper bin 7, the photoelectric hole 40 is shielded by the sliding plate 34, the limiting photoelectric 39 senses the change of the optical signal, the resetting is judged to be finished, and at the moment, the limiting photoelectric 39 controls the first motor 32 to stop, namely, the pushing plate 11 is reset to a proper position.

As shown in fig. 4, 13 and 14, in this embodiment, the second power device is a second motor 41, the second motor 41 is installed on the bracket 1, an output end of the second motor 41 is connected with a driving gear 42, the driving gear 42 is meshed with a rotating gear 43, the rotating gear 43 is also installed on the bracket 1, the rotating gear 43 and the driving gear 42 are both located on one side of the bracket 1 away from the detection head 12, a rotating shaft 44 is disposed at one end of the detection head 12 close to the bracket 1, one end of the rotating shaft 44 is fixedly connected to the detection head 12, the other end is connected to the rotating gear 43, the rotating gear 43 drives the rotating shaft 44 to rotate, the rotating shaft 44 drives the detection head 12 to rotate, and the detection head 12 rotates towards the push plate. In this embodiment, the detection head 12 includes a housing 45 and an internal detection chamber 46 enclosed by the housing 45. One end of the rotating shaft 44 is cylindrical and passes through the housing 45 and the bracket 1 and is fixed with the center of the rotating gear 43, and a bearing is installed between the rotating shaft 44 and the bracket 1, so that the rotating gear 43 drives the rotating shaft 44 to rotate when rotating. The other end of the rotating shaft 44 is located in the detection cavity 46 and is in a mutually vertical plate shape and is attached to the inner surface of the shell 45, and the rotating shaft 44 is fixedly connected with the shell 45 through a bolt, so that the shell 45 is driven to rotate together when the rotating shaft 44 rotates, and the rotation of the detection head 12 to the push plate is realized.

In this embodiment, push pedal 11 is the horizontal direction setting, detects head 12 and is vertical direction setting, and detection mouth 13 is towards opening setting downwards, unloads the test paper easily after accomplishing the detection.

As shown in fig. 4 and 13, one end of the detection head 12 is connected to the bracket 1, the other end is provided with a detection port 13, the detection head 12 is connected to a second power device for driving the detection head to rotate or return towards the platform plate 2, and when the detection head 12 rotates towards the platform plate 2, the detection port 13 and the second channel 6 are located on the same horizontal line. An electrode plate socket 14 is arranged in the detection head 12, a detection channel 15 is arranged on the electrode plate socket 14, the detection channel 15 is communicated with the detection port 13, and the electrode plate 8 enters the detection channel 15 from the detection port 13 for detection. The electrode plate socket 14 is provided with a shifting lever 16, one end of the shifting lever 16 is positioned at the detection channel 15, the other end of the shifting lever 16 is positioned outside the detection head 12, the shifting lever 16 can be arranged in a sliding manner, and the shifting lever 16 is connected with a third power device for driving the shifting lever to slide towards the detection port 13.

As shown in fig. 14 to 15, a detection plate 47 is arranged in the detection chamber 46, the detection plate 47 is arranged in a plate shape, one end of the detection plate 47 is arranged near the rotating shaft 44, the other end of the detection plate 47 is arranged near the detection port 13, an electrode plate socket 14 is arranged near the detection port 13, the electrode plate socket 14 is provided with a detection channel 15 facing the detection port 13, the electrode plate socket 14 is fixed on the detection plate 47, an elastic arm 48 is arranged in the detection channel 15, one end of the elastic arm 48 is fixed on the electrode plate socket 14, the other end of the elastic arm is located in the detection channel 15, and the elastic arm 48 presses the electrode plate 8 on the electrode plate socket 14 and fixes the electrode plate 8.

As shown in fig. 16, the elastic arms 48 are provided with a plurality of elastic arms 48, in this embodiment, five elastic arms are provided, wherein two long elastic arms 48 and three short elastic arms 48 are provided, one end of each elastic arm 48 located in the detection channel 15 is bent to form a squeezing point, each elastic arm 48 has certain elasticity, when the electrode plate 8 is installed, the second motor 41 drives the detection head 12 to rotate towards the push plate until the detection port 13 is aligned with the test paper pushing device, the push plate acts to push the electrode plate 8 into the detection channel 15 from the detection port 13, and five elastic arms 48 compress five points on the electrode plate 8, so as to ensure the stability of detection of the electrode plate 8, and the second motor 41 drives the detection head 12 to return again. In this embodiment, as shown in fig. 13-14, a photoelectric sensor 49 is disposed on the bracket 1, a photoelectric blocking piece 50 matched with the photoelectric sensor 49 is disposed on the rotating gear 43, when a test paper signal is transmitted, the second motor 41 operates, the driving gear 42 rotates to drive the rotating gear 43 to rotate, at this time, the photoelectric blocking piece 50 on the rotating gear 43 is far away from the photoelectric sensor 49, the detection head 12 connected with the rotating gear 43 through the rotating shaft 44 rotates, and the detection port 13 at the bottom is aligned with the electrode plate 8 and is pushed out of position. After the automatic installation of the electrode plate 8 is finished, the second motor 41 operates, the driving gear 42 rotates in the opposite direction, the rotating gear 43 rotates in the opposite direction, the detection head 12 resets until the photoelectric blocking piece 50 returns to the position of the photoelectric sensor 49, the photoelectric sensor 49 senses the change of the optical signal, and the resetting is finished.

As shown in fig. 4 and 13, the detection port 13 is disposed on the housing 45, a first sliding slot 51 in which the shift lever 16 slides is disposed on the housing 45, a second sliding slot 52 in which the shift lever 16 slides is disposed on the electrode pad socket 14, the first sliding slot 51 and the second sliding slot 52 are disposed in parallel, the first sliding slot 51 and the second sliding slot 52 are both disposed along the movement direction of the electrode pad 8 in the detection head 12, and the shift lever 16 is disposed at an end portion of the detection channel 15 away from the detection port 13.

As shown in fig. 15, the shift lever 16 is connected with a push rod 53 driving it to move along the first slide groove 51 and the second slide groove 52. The push rod 53 is arranged in a long strip shape, one end of the shifting rod 16, which is in contact with the push rod 53, is positioned on the outer side of the detection head 12, namely, the outer side of the first chute 51, one end of the push rod 53, which is in contact with the shifting rod 16, is in a U shape, the U-shaped push rod 53 surrounds three side surfaces of the shifting rod 16, the push rod 53 is positioned on one side of the shifting rod 16, which is far away from the detection port 13, and the third power device is connected with the push rod 53. In this embodiment, the third power device is an electromagnet 54, the electromagnet 54 includes an inner coil and an iron core 55, and one end of the iron core 55 is located outside the electromagnet 54 and is fixedly connected to one end of the push rod 53 away from the shift lever 16. In this embodiment, as shown in fig. 15, the iron core 55 is fixedly connected to the push rod 53 through a bolt, the electromagnet 54 is arranged in the same direction as the detection head 12, and the detection port 13 is arranged downward, that is, the push rod 53 and the shift lever 16 both move in the vertical direction, the electromagnet 54 is energized to generate suction, the iron core 55 moves downward to drive the push rod 53 and the shift lever 16 to move downward, so as to push the electrode sheet 8 out of the detection channel 15, thereby realizing paper discharge.

As shown in fig. 15 and 17, the width of the end of the shift lever 16 close to the detection channel 15 is greater than the width of the first sliding slot 51, and the width of the end of the shift lever 16 connected with the push rod 53 is less than the width of the first sliding slot 51, so as to ensure the stability of the sliding of the shift lever 16. One end of the shifting lever 16, which is close to the detection channel 15, is connected with a sliding block 56, one end of the shifting lever 16, which is close to the sliding block 56, is provided with a U-shaped opening, one end of the sliding block 56 is located in the U-shaped opening, the width of one end of the sliding block 56, which is located in the detection channel 15, is larger than the width of the second sliding groove 52, and the width of one end of the sliding block 56, which is connected with the shifting lever 16, is smaller than the width of the second sliding groove 52, so that the sliding stability of the sliding block 56 is ensured. The inner wall that the electrode slice 8 was kept away from second spout 52 with electrode slice socket 14 after the installation has certain space, and the one end that driving lever 16 was kept away from to slider 56 is located the space, and electrode slice 8 is H1 to the distance of electrode slice socket 14 keeping away from the inner wall of driving lever 16 extending direction, driving lever 16 is H2 to the distance of keeping away from the inner wall of extending direction, and H2 < H1, and when slider 56 moved downwards under driving lever 16 drove promptly, can promote electrode slice 8 and move together, left elastic arm 48 until electrode slice 8, electro-magnet 54 outage, later electrode slice 8 drops under the action of gravity. The iron core automatically resets after the electromagnet is powered off, the electromagnet is a standard part and has the model of KK0530B, and the iron core resets to be a self-contained function in the electromagnet without the cooperation of an additional device.

As shown in fig. 2-3, the reagent holder 58 is connected to a fourth power device for driving the reagent holder to move toward or away from the detection head, in this embodiment, the fourth power device is a fourth motor 60, the fourth motor 60 is installed inside the casing 57, an output end of the fourth motor 60 is connected to a lead screw 61, the lead screw 61 is provided with a nut holder 62 in a matching manner, and one side of the nut holder 62 extends out of the casing 57 and is fixedly connected to the reagent holder 58. The two sides of the screw 61 are provided with guide shafts for guiding, and the fourth motor 60 rotates to drive the nut seat 62 to move up and down, so as to drive the reagent seat 58 to move towards or away from the detection head.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. A vitamin detector is characterized in that: comprises a shell, wherein a plurality of detection heads are arranged on the shell, reagent seats for placing reagent bottles are arranged below the detection heads, the detection heads and the reagent seats are respectively provided with a plurality of detection heads, the detection heads and the reagent seats are arranged in one-to-one correspondence, a display panel is arranged on the shell, a bracket is arranged on the shell, the detection heads are arranged on the bracket, one side of the bracket, which is far away from the detection heads, is connected with a platform plate, the platform plate is provided with a push groove and a placing groove which are arranged side by side, the placing groove is arranged at one side close to the bracket, a first channel is arranged between the placing groove and the push groove, one end of the placing groove, which is far away from the push groove, is provided with a second channel, a test paper bin is arranged in the placing groove, electrode plates are arranged in the test paper bin, one end of the test paper bin is detachably arranged in the placing groove, a first outlet and a second outlet are respectively arranged at two sides of the lower end of the test paper bin, the first outlet is communicated with the first channel, the second outlet is communicated with the second channel, the first outlet and the second outlet are positioned on the same horizontal plane, a slidable push plate is arranged in the push groove and can reciprocate along the first channel to the second channel, the push plate is connected with a first power device for driving the push plate to move, the push plate and the first outlet are positioned on the same horizontal line, one end of the support, which is far away from the platform plate, is provided with a detection head, one end of the detection head is connected with the support, the other end of the detection head is provided with a detection port, the detection head is connected with a second power device for driving the detection head to rotate or return towards the platform plate, when the detection head rotates towards the platform plate, the detection port and the second channel are positioned on the same horizontal line, and an electrode plate socket is arranged in the detection head, the electrode plate socket is provided with a detection channel, the detection channel is communicated with the detection port, the electrode plate socket is provided with a driving lever, one end of the driving lever is located in the detection channel, the other end of the driving lever is located on the outer side of the detection head, the driving lever is slidably arranged, and the driving lever is connected with a third power device which drives the driving lever to slide towards the detection port.

2. The vitamin detector of claim 1, wherein: and the reagent seat is connected with a fourth power device for driving the reagent seat to move towards or away from the detection head.

3. The vitamin detector of claim 1, wherein: the test paper storehouse is connected the one end of standing groove and can be dismantled and be connected with the test paper lid, the test paper storehouse encloses into confined test paper chamber with test paper lid is inside, the test paper lid is connected with test paper storehouse buckle, the test paper intracavity is provided with the clamp plate, the electrode slice is placed to one side that the clamp plate is close to the test paper lid, the opposite side of clamp plate is provided with the spring, the spring is in compression state.

4. The vitamin detector of claim 3, wherein: the test paper cavity is internally provided with a fixing frame, the fixing frame comprises vertical plates positioned on two sides and baffle plates positioned at the end parts of the two vertical plates, two ends of each baffle plate are fixedly connected with the two vertical plates respectively, the fixing frame is positioned in the middle of the test paper cavity, the fixing frame and the test paper cover are closed, the electrode plate is positioned in the fixing frame, the pressing plate is also positioned in the fixing frame, and the pressing plate is positioned at one end close to the baffle plates.

5. The vitamin detector of claim 4, wherein: the push plate is rectangular platelike and sets up, the one end that the standing groove was kept away from to the push plate is connected with and pushes away the seat, it includes the sliding plate of being connected with the push plate and the drive plate of being connected with first gear to push away the seat, the sliding plate passes through bolt fixed connection with the push plate, the sliding plate sets up along the horizontal direction and is on a parallel with the push plate, the drive plate sets up the one side at the sliding plate, the drive plate sets up along vertical direction, a power device with the drive plate transmission is connected.

6. The vitamin detector of claim 5, wherein: the first power device is a first motor, the first motor is fixed on one side, away from the placing groove, of the platform plate through the mounting plate, the output end of the first motor is connected with a first gear, one end, away from the sliding plate, of the driving plate is provided with sliding teeth matched with the first gear, and the driving plate is located above the first gear.

7. The vitamin detector of claim 1, wherein: the second power device is a second motor, the second motor is installed on the support, the output end of the second motor is connected with a driving gear, the driving gear is meshed with a rotating gear, the rotating gear is also installed on the support, a rotating shaft is arranged at one end, close to the support, of the detection head, one end of the rotating shaft is fixedly connected with the detection head, and the other end of the rotating shaft is connected with the rotating gear.

8. The vitamin detector of claim 7, wherein: the electrode plate socket is arranged at the position, close to the detection port, of the detection plate, an elastic arm is arranged in the detection channel, one end of the elastic arm is fixed to the electrode plate socket, and the other end of the elastic arm is located in the detection channel.

9. The vitamin detector of claim 8, wherein: the detection head comprises an inner detection cavity surrounded by a shell and the shell, a first sliding groove for sliding of a driving lever is formed in the shell, a second sliding groove for sliding of the driving lever is formed in an electrode plate socket, the first sliding groove and the second sliding groove are arranged in parallel, the first sliding groove and the second sliding groove are arranged along the movement direction of the electrode plate in the detection head, and the driving lever is arranged at the end part, far away from a detection port, of the detection channel.

10. The vitamin detector of claim 9, wherein: the driving lever is connected with a push rod which drives the driving lever to move along a first sliding groove and a second sliding groove, one end of the driving lever, which is in contact with the push rod, is located on the outer side of the detection head, the push rod is located on one side, away from the detection port, of the driving lever, the third power device is connected with the push rod, the third power device is an electromagnet, the electromagnet comprises an inner coil and an inner iron core, and one end of the inner iron core is located on the outer side of the electromagnet and is fixedly connected with one end, away from the driving lever, of the push rod.

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