CN113252615A - Shading detection device for blood peptide oral liquid medicine bottle - Google Patents

Abstract

The application provides a shading detection device for blood peptide oral liquid medicine bottle belongs to and detects technical field. The shading detection device comprises a base, a support column, a first lifting mechanism, a second lifting mechanism, a clamping assembly, an illumination assembly and a light detection assembly; the bottom end of the pillar is connected with the base; the first lifting mechanism and the second lifting mechanism are movably connected with the support, and the first lifting mechanism is positioned on one side of the second lifting mechanism facing the base; the clamping assembly is connected with the first lifting mechanism; the illumination assembly is connected with the second lifting mechanism and is opposite to the clamping assembly; the optical detection assembly is connected with the base and is opposite to the clamping assembly; the first lifting mechanism and the second lifting mechanism are configured to respectively drive the clamping component and the light illuminating component to move towards the light detecting component, so that the light illuminating component and the light detecting component are respectively positioned at two sides of the blood peptide oral liquid medicine bottle. The quality guarantee period of the blood peptide oral liquid can be guaranteed.

Description

Shading detection device for blood peptide oral liquid medicine bottle

Technical Field

The application belongs to the technical field of detect, in particular to a shading detection device for blood peptide oral liquid medicine bottle.

Background

The blood peptide oral liquid is a health product and is packaged by a medicine bottle. In order to avoid direct irradiation of sunlight to the blood peptide oral liquid in the medicine bottle, the quality guarantee period of the blood peptide oral liquid is prolonged, and the medicine bottle is a dark shading medicine bottle.

In the related art, after the packaging of the medicine bottles is completed, the medicine bottles are usually packed and packed, and then directly put in storage or transferred to other warehouses.

However, since the medicine bottles are generally finished medicine bottles purchased in bulk from other manufacturers, quality cannot be absolutely guaranteed. If the light-shielding property of the medicine bottle does not meet the standard, the shelf life of the blood peptide oral liquid packaged in the medicine bottle is directly influenced.

Disclosure of Invention

The embodiment of the application provides a shading detection device for blood peptide oral liquid medicine bottle, can guarantee the light-proofness of medicine bottle to guarantee the shelf life of blood peptide oral liquid. The technical scheme is as follows:

the embodiment of the application provides a shading detection device for a blood peptide oral liquid medicine bottle, which comprises a base, a support, a first lifting mechanism, a second lifting mechanism, a clamping assembly, an illumination assembly and a light detection assembly, wherein the support is fixedly arranged on the base;

the bottom end of the strut is connected with the base;

the first lifting mechanism and the second lifting mechanism are connected with the strut and can move relative to the strut along the length direction of the strut, and the first lifting mechanism is positioned on one side of the second lifting mechanism facing the base;

the clamping assembly is connected with the first lifting mechanism and is used for clamping a blood peptide oral liquid medicine bottle;

the illumination assembly is connected with the second lifting mechanism and is opposite to the clamping assembly;

the optical detection assembly is connected with the base and is opposite to the clamping assembly;

the first lifting mechanism and the second lifting mechanism are configured to respectively drive the clamping component and the light detection component to move towards the light detection component, so that the light detection component and the light detection component are respectively positioned at two sides of the blood peptide oral liquid medicine bottle.

In one implementation of the present application, the clamping assembly includes a first platform, a receptacle, and a light shield;

the first platform is connected with the first lifting mechanism and is vertical to the support;

the jack is positioned on the first platform and penetrates through two opposite plate surfaces of the first platform, and the axial direction of the jack is parallel to the support column;

the light shield is located the first platform orientation one side of illumination subassembly, the light shield has into unthreaded hole and light-emitting hole, it faces to advance the unthreaded hole illumination subassembly, the light-emitting hole with first platform links to each other, and with the jack is linked together.

In another implementation manner of the present application, the light shield is a truncated cone-shaped structural member, the light inlet hole is located at the end of the light shield with the larger diameter, and the light outlet hole is located at the end of the light shield with the smaller diameter.

In yet another implementation of the present application, the clamping assembly further comprises a light reflecting layer;

the reflecting layer is attached to the inner wall of the light shield.

In yet another implementation of the present application, the inner circumferential wall of the receptacle has a snap ring;

the clamping ring is coaxial with the jack, and the inner peripheral wall of the clamping ring is arc-shaped.

In yet another implementation of the present application, the light detection assembly includes a support and a light intensity sensor;

the bracket is connected with the base;

the light intensity sensor is located one side of the support far away from the base, and is connected with the support, and the light intensity sensor is opposite to the jack.

In yet another implementation of the present application, the light detection assembly further comprises an insert rod;

the inserted bar is parallel to the support, the first end of the inserted bar is connected with the support, the second end of the inserted bar is movably inserted into the jack, and the second end of the inserted bar is connected with the light intensity sensor.

In yet another implementation of the present application, the illumination assembly includes a second platform and a lamp bead;

the second platform is connected with the second lifting mechanism and is vertical to the support;

the lamp beads are located on one side, facing the first platform, of the second platform and connected with the second platform, and the lamp beads are opposite to the light inlet holes.

In another implementation manner of the present application, the first platform is a strip-shaped structural member, the number of the insertion holes is multiple, the insertion holes are arranged along the length direction of the first platform at equal intervals, the light shields are in one-to-one correspondence with the insertion holes, and the light shields are communicated with the corresponding insertion holes;

the second platform is a strip-shaped structural member, the lamp beads correspond to the light shield one by one, and the lamp beads are opposite to the corresponding light inlet holes;

the support is a long strip-shaped structural member, the light intensity sensors correspond to the jacks one by one, and the light intensity sensors are opposite to the corresponding jacks.

In yet another implementation of the present application, the outer wall of the strut has a rack extending along a length of the strut;

the first lifting mechanism comprises a lifting seat, a motor and a driving gear, the supporting column is sleeved with the lifting seat in a movable mode, the motor is connected with the lifting seat, the driving gear is coaxially connected with an output shaft of the motor, and the driving gear is meshed with the rack.

The technical scheme provided by the embodiment of the application has the following beneficial effects:

when the shading detection device that provides through this application embodiment detects the light proofness of blood peptide oral liquid medicine bottle, drive centre gripping subassembly and illumination subassembly to suitable position through first elevating system and second elevating system for enough space installation medicine bottle that awaits measuring has. After the adjustment is finished, the medicine bottle to be measured is clamped to the clamping assembly. Then, the first lifting mechanism is driven, so that the medicine bottle to be detected moves towards the optical detection assembly until the medicine bottle to be detected is aligned with the optical detection assembly. Then, the second lifting mechanism is driven, so that the illumination assembly moves towards the medicine bottle to be detected until the illumination assembly is aligned with the medicine bottle to be detected. At this moment, illumination subassembly and light detection subassembly are located the both sides of the medicine bottle that awaits measuring respectively, and the illumination subassembly shines the medicine bottle that awaits measuring, and the light detection subassembly then detects the intensity of the light that sees through the medicine bottle that awaits measuring to reach the purpose of detecting the light-proofness of the medicine bottle that awaits measuring.

That is to say, through the shading detection device that this application embodiment provided, can detect the light proofness of blood peptide oral liquid medicine bottle to avoid not meeting the requirements because of the light proofness of medicine bottle, and lead to the shelf life of blood peptide oral liquid to receive the influence.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a shading detection device provided in an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a clamping assembly provided in an embodiment of the present application;

fig. 3 is a schematic structural diagram of an illumination assembly provided in an embodiment of the present application;

FIG. 4 is a schematic structural diagram of a light detection assembly provided in an embodiment of the present application;

fig. 5 is an assembly schematic diagram of a first lifting mechanism provided in an embodiment of the present application.

The symbols in the drawings represent the following meanings:

10. a base;

20. a pillar; 21. a rack; 22. a guide groove;

30. a first lifting mechanism; 31. a lifting seat; 32. a motor; 33. a drive gear; 34. a through hole; 35. a guide projection;

40. a second lifting mechanism;

50. a clamping assembly; 51. a first platform; 52. a jack; 53. a light shield; 53a, light inlet holes; 53b, a light-emitting hole; 54. a light-reflecting layer; 55. a snap ring;

60. an illumination assembly; 61. a second platform; 62. a lamp bead;

70. a light detection component; 71. a support; 72. a light intensity sensor; 73. and (4) inserting the rod.

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

The blood peptide oral liquid is a health product and is packaged by a medicine bottle. In order to avoid direct irradiation of sunlight to the blood peptide oral liquid in the medicine bottle, the quality guarantee period of the blood peptide oral liquid is prolonged, and the medicine bottle is a dark shading medicine bottle.

In the related art, after the packaging of the medicine bottles is completed, the medicine bottles are usually packed and packed, and then directly put in storage or transferred to other warehouses.

However, since the medicine bottles are generally finished medicine bottles purchased in bulk from other manufacturers, quality cannot be absolutely guaranteed. If the light-shielding property of the medicine bottle does not meet the standard, the shelf life of the blood peptide oral liquid packaged in the medicine bottle is directly influenced.

In order to solve the technical problem, the embodiment of the application provides a shading detection device for a blood peptide oral liquid medicine bottle. Fig. 1 is a schematic structural diagram of the shading detection device, and referring to fig. 1, in the present embodiment, the shading detection device includes a base 10, a support column 20, a first lifting mechanism 30, a second lifting mechanism 40, a clamping assembly 50, an illumination assembly 60, and an optical detection assembly 70.

The bottom end of the supporting column 20 is connected to the base 10, the first lifting mechanism 30 and the second lifting mechanism 40 are both connected to the supporting column 20 and can move relative to the supporting column 20 along the length direction of the supporting column 20, and the first lifting mechanism 30 is located on the side of the second lifting mechanism 40 facing the base 10. The holding assembly 50 is connected to the first lifting mechanism 30 for holding the blood peptide oral liquid bottle. The illumination assembly 60 is connected to the second elevating mechanism 40, and the illumination assembly 60 is opposite to the holding assembly 50. The light detecting member 70 is connected to the base 10, and the light detecting member 70 is opposed to the holding member 50.

The first and second elevating mechanisms 30 and 40 are configured to drive the holding assembly 50 and the light detecting assembly 60 to move toward the light detecting assembly 70, respectively, such that the light detecting assembly 60 and the light detecting assembly 70 are respectively located at two sides of the blood peptide oral liquid medicine bottle.

When the shading detection device that provides through this application embodiment detects the light proofness of blood peptide oral liquid medicine bottle, drive centre gripping subassembly 50 and illumination subassembly 60 to suitable position through first elevating system 30 and second elevating system 40 for enough space installation medicine bottle that awaits measuring has. After the adjustment is completed, the medicine bottle to be tested is clamped to the clamping assembly 50. Then, the first elevating mechanism 30 is driven to move the vial to be tested toward the optical detection assembly 70 until the vial to be tested is aligned with the optical detection assembly 70. Then, the second lifting mechanism 40 is driven, so that the illumination assembly 60 moves towards the medicine bottle to be tested until the illumination assembly 60 is aligned with the medicine bottle to be tested. At this time, the illumination assembly 60 and the light detection assembly 70 are respectively located at two sides of the medicine bottle to be detected, the illumination assembly 60 illuminates the medicine bottle to be detected, and the light detection assembly 70 detects the intensity of light penetrating through the medicine bottle to be detected, so that the purpose of detecting the light shielding property of the medicine bottle to be detected is achieved.

That is to say, through the shading detection device that this application embodiment provided, can detect the light proofness of blood peptide oral liquid medicine bottle to avoid not meeting the requirements because of the light proofness of medicine bottle, and lead to the shelf life of blood peptide oral liquid to receive the influence.

In this embodiment, the illumination assembly 60 is used for providing a light source, the holding assembly 50 is used for holding a vial to be tested, and the light detection assembly 70 is used for detecting the intensity of light passing through the vial to be tested. Through the cooperation of illumination subassembly 60, centre gripping subassembly 50 and light detection subassembly 70 three, can be fast and effectual the light-proofness to the medicine bottle that awaits measuring detects.

The illumination assembly 60, the holding assembly 50 and the light detection assembly 70 will be described below.

Fig. 2 is a schematic structural diagram of the clamping assembly 50, and in the embodiment, with reference to fig. 2, the clamping assembly 50 includes a first platform 51, a receptacle 52, and a light shield 53.

The first platform 51 is connected to the first elevating mechanism 30 and is perpendicular to the pillar 20. The insertion hole 52 is located on the first platform 51 and penetrates through two opposite plate surfaces of the first platform 51, and the axial direction of the insertion hole 52 is parallel to the pillar 20. The light shield 53 is located on a side of the first platform 51 facing the illumination assembly 60, the light shield 53 has a light inlet hole 53a and a light outlet hole 53b, the light inlet hole 53a faces the illumination assembly 60, and the light outlet hole 53b is connected to the first platform 51 and communicated with the insertion hole 52.

In the above implementation manner, the first platform 51 is a carrier, the insertion hole 52 is used for inserting the medicine bottle to be tested, and the light shield 53 is used for preventing the light emitted by the illumination assembly 60 from diffusing outwards, so that the light irradiates the medicine bottle to be tested as much as possible, and the detection accuracy is further improved.

When the medicine bottle to be tested is mounted through the clamping assembly 50, the bottleneck of the medicine bottle to be tested is directed toward the insertion hole 52, so that the bottleneck of the medicine bottle passes through the light shield 53 and is inserted into the insertion hole 52. In this state, the bottle neck of the medicine bottle to be tested is located in the insertion hole 52, and the bottle body of the medicine bottle to be tested is located in the light shield 53. In this way, when the illumination assembly 60 is aligned with the light shield 53, the light emitted by the illumination assembly 60 can be irradiated onto the vial to be tested as much as possible due to the influence of the light shield 53, thereby improving the accuracy of the detection.

In order to further avoid light leakage of the light shield 53, the clamping assembly 50 optionally further includes a reflective layer 54, and the reflective layer 54 is attached to the inner wall of the light shield 53. By such design, the light emitted from the illumination assembly 60 can be reflected by the reflective layer 54, thereby further avoiding the problem of light leakage.

In addition, the light can be reflected by the reflective layer 54, so that part of the light is reflected by the reflective layer 54 and then irradiates on the medicine bottle to be tested. In this way, the illumination assembly 60 with low power can be used to achieve the test effect, and the energy saving effect is achieved.

Illustratively, the light shield 53 is made of plastic, and the reflective layer 54 is chrome-plated on the inner wall of the light shield 53.

With continued reference to fig. 2, in the present embodiment, the light shield 53 is a truncated cone-shaped structure, the light inlet hole 53a is located at the end of the light shield 53 with the larger diameter, and the light outlet hole 53b is located at the end of the light shield 53 with the smaller diameter.

Because the light inlet hole 53a is located at the end of the light shield 53 with the larger diameter, light emitted by the illumination assembly 60 can enter the light shield 53 more, the insertion of the medicine bottle to be detected can be more convenient, and the detection efficiency is improved.

In addition, the light shield 53 is designed to be a truncated cone-shaped structural member, and can be matched with the reflective layer 54, so that more light is reflected to the medicine bottle to be measured.

Because the bottleneck of the medicine bottle to be tested is inserted in the insertion hole 52, in order to improve the insertion stability of the medicine bottle to be tested in the insertion hole 52, in this embodiment, the inner peripheral wall of the insertion hole 52 is provided with the clamping ring 55, the clamping ring 55 is coaxial with the insertion hole 52, and the inner peripheral wall of the clamping ring 55 is in a circular arc shape.

After the medicine bottle that will await measuring is inserted to in the jack 52, under the effect of joint ring 55, the joint that the bottleneck of the medicine bottle that awaits measuring can be stable is in jack 52 to avoid the medicine bottle that awaits measuring to be qualified for the next round of competitions and empty in the in-process that detects. Moreover, the clamping ring 55 can also play a role in shading light, so that light is prevented from leaking out of a gap between the medicine bottle to be detected and the jack 52.

Illustratively, the snap ring 55 is a rubber structural member and the snap ring 55 is black.

The clamping assembly 50 is described above and the illumination assembly 60 is described next.

Fig. 3 is a schematic structural diagram of the illumination assembly 60, and in combination with fig. 3, in this embodiment, the illumination assembly 60 includes a second platform 61 and a lamp bead 62.

The second platform 61 is connected to the second elevating mechanism 40 and is perpendicular to the pillar 20. The lamp bead 62 is located on one side of the second platform 61 facing the first platform 51, and is connected with the second platform 61, and the lamp bead 62 is opposite to the light inlet 53 a.

In the above implementation manner, the second platform 61 is a carrier, and the lamp bead 62 is opposite to the light inlet 53a, so that light can be emitted to the light inlet 53a, and then the light passes through the light inlet 53a and irradiates on the medicine bottle to be measured.

Illustratively, the lamp beads 62 are light-emitting diodes (LEDs), so that the lamp beads 62 have the characteristics of high brightness and energy saving.

The clamping assembly 50 and the illumination assembly 60 are described above, followed by the light detection assembly 70.

Fig. 4 is a schematic structural diagram of the light detection assembly 70, and in conjunction with fig. 4, in the present embodiment, the light detection assembly 70 includes a bracket 71 and a light intensity sensor 72.

The bracket 71 is connected to the base 10, and the light intensity sensor 72 is located on a side of the bracket 71 away from the base 10 and connected to the bracket 71, the light intensity sensor 72 being opposite to the insertion hole 52.

In the above implementation, the support 71 is a carrier, and the light intensity sensor 72 is opposite to the insertion hole 52, and can detect the light intensity of the light transmitted from the to-be-detected medicine bottle, so as to determine whether the light-shielding property of the to-be-detected medicine bottle meets the requirement.

In order to ensure that the light sensed by the light intensity sensor 72 is the light transmitted from the medicine bottle to be tested, optionally, the light detecting assembly 70 further comprises an inserting rod 73, the inserting rod 73 is parallel to the supporting column 20, a first end of the inserting rod 73 is connected with the bracket 71, a second end of the inserting rod 73 is movably inserted into the inserting hole 52, and a second end of the inserting rod 73 is connected with the light intensity sensor 72.

Because the light intensity sensor 72 is located at the second end of the insertion rod 73, and the second end of the insertion rod 73 is movably inserted into the insertion hole 52, the light intensity sensor 72 can be located in the insertion hole 52 under the support of the insertion rod 73, so as to ensure that the light rays sensed by the light intensity sensor 72 are all the light rays transmitted from the medicine bottle to be tested as far as possible. It will be readily appreciated that the light intensity sensor 72 could also extend directly into the vial to be tested. In this case, in order to avoid interference collision of the light intensity sensor 72 and the plunger 73 with the medicine bottle to be tested, the size of the plunger 73 and the light intensity sensor 72 should be ensured to be as smaller as possible than the bottleneck size of the medicine bottle to be tested.

In order to improve the detection efficiency, in this embodiment, the first platform 51 is a long strip-shaped structural member, the insertion holes 52 are plural, the plural insertion holes 52 are arranged at equal intervals along the length direction of the first platform 51, the light shields 53 correspond to the insertion holes 52 one by one, and the light shields 53 communicate with the corresponding insertion holes 52. The second platform 61 is a strip-shaped structural member, the lamp beads 62 correspond to the light shield 53 one by one, and the lamp beads 62 are opposite to the corresponding light inlet holes 53 a. The support 71 is a strip-shaped structural member, the light intensity sensors 72 correspond to the insertion holes 52 one by one, and the light intensity sensors 72 are opposite to the corresponding insertion holes 52.

That is to say, first platform 51, second platform 61 and support 71 are all parallel, and a plurality of jacks 52 and a plurality of lens hood 53 are arranged along the length direction equidistance interval of first platform 51, and a plurality of lamp pearl 62 are arranged along the length direction equidistance interval of second platform 61, and a plurality of light intensity sensors 72 are arranged along the length direction equidistance interval of support 71, and jack 52, lens hood 53, lamp pearl 62 and light intensity sensors 72 are all the one-to-one. Therefore, a plurality of medicine bottles to be detected can be detected simultaneously, and the detection efficiency is effectively improved.

In order to avoid the influence of the process of the light-shielding detection device on the packaging efficiency of the blood peptide oral liquid, the blood peptide oral liquid medicine bottle can be subjected to sampling inspection only through the light-shielding detection device. If the poor light shielding performance of the medicine bottles is found in the process of sampling inspection, other medicine bottles in the same batch are detected. Therefore, the influence of the shading detection device on the packaging efficiency of the blood peptide oral liquid can be reduced as much as possible.

The first elevating mechanism 30 and the second elevating mechanism 40 will be described below.

Fig. 5 is an assembly view of the first elevating mechanism 30, and the view of fig. 5 is a top view of fig. 1. Referring to fig. 5, in the present embodiment, the outer wall of the pillar 20 has a rack 21, and the rack 21 extends in the length direction of the pillar 20. The first lifting mechanism 30 comprises a lifting seat 31, a motor 32 and a driving gear 33, the lifting seat 31 is movably sleeved on the support column 20, the motor 32 is connected with the lifting seat 31, the driving gear 33 is coaxially connected with an output shaft of the motor 32, and the driving gear 33 is meshed with the rack 21.

In the above implementation manner, the driving gear 33 is engaged with the rack 21, so when the motor 32 drives the driving gear 33 to rotate, the lifting seat 31 can be driven to move along the length direction of the pillar 20, so as to drive the first platform 51 to move along the length direction of the pillar 20, thereby realizing that the clamping assembly 50 is lifted along the length direction of the pillar 20 as a whole.

Optionally, the pillar 20 has two racks 21 thereon, and the two racks 21 are symmetrically arranged. Accordingly, the first lifting mechanism 30 includes two motors 32 and two driving gears 33, and the two driving gears 33 are respectively engaged with the corresponding racks 21. By such a design, the first lifting mechanism 30 can lift more stably, and the reliability of the shading detection device is further improved.

Optionally, the pillar 20 further has two guide grooves 22, and the two guide grooves 22 are respectively located at two sides of the rack 21 and extend along the length direction of the pillar 20. The elevating base 31 has a through hole 34, the inner edge of the through hole 34 has two guide protrusions 35, the guide protrusions 35 are movably inserted into the corresponding guide grooves 22, respectively, and the support posts 20 are movably inserted into the through hole 34.

In the above-described embodiment, the engagement between the guide groove 22 and the guide projection 35 can ensure that the lifter base 31 always moves in the longitudinal direction of the pillar 20. In addition, the contact area between the supporting column 20 and the lifting seat 31 can be increased through the matching between the guide groove 22 and the guide protrusion 35, so that the lifting seat 31 is more stably sleeved on the supporting column 20.

In this embodiment, the structure of the second lifting mechanism 40 is the same as that of the first lifting mechanism 30, that is, the second lifting mechanism 40 and the first lifting mechanism 30 are movably sleeved on the support post 20 together, and the driving gear is driven by the motor to rotate, so that the lifting seat can be driven to move along the length direction of the support post, the second platform moves along the length direction of the support post, and the illumination assembly is lifted along the length direction of the support post as a whole. The rest of the structure will not be described in detail herein.

In other embodiments, the second elevating mechanism 40 may also have a different structure from the first elevating mechanism 30. Alternatively, the second lifting mechanism 40 includes a cylinder and a lifting platform, the cylinder is parallel to the pillar, a cylinder body of the cylinder is connected to the top end of the pillar, and a piston rod of the cylinder is connected to the lifting platform.

In the implementation mode, the lifting platform is directly driven to move along the length direction of the support column through the air cylinder, so that the second platform moves along the length direction of the support column, and the illumination assembly is integrally lifted along the length direction of the support column.

In this case, the lift table may not be directly connected to the pillar, so that the lift table and the lift base 31 may be staggered from each other, thereby preventing the first lift mechanism 30 and the second lift mechanism 40 from interfering with each other and colliding with each other during operation, and improving the reliability of the light shielding detection device.

The operation of the shading detection device will be described below.

First, the clamping assembly 50 and the illumination assembly 60 are adjusted to appropriate positions by the first elevating mechanism 30 and the second elevating mechanism 40 so as to mount the medicine bottle to be tested.

Then, the bottleneck of the to-be-tested medicine bottle is inserted into the insertion hole 52, so that the bottleneck of the to-be-tested medicine bottle is clamped in the clamping ring 55, and the body of the to-be-tested medicine bottle is located in the light shield 53.

Then, the clamping assembly 50 and the illumination assembly 60 are adjusted to the proper positions by the first elevating mechanism 30 and the second elevating mechanism 40, so that the light intensity sensor 72 is positioned in the insertion hole 52 to be aligned with the light exit hole 53b, and the lamp bead 62 is aligned with the light entrance hole 53 a.

Finally, the lamp beads 62 are lightened, so that the light emitted by the lamp beads 62 directly illuminates the medicine bottle to be detected. After the light penetrates through the medicine bottle to be detected, the light is sensed by the light intensity sensor 72, so that the intensity of the light penetrating through the medicine bottle to be detected is detected, and the purpose of detecting the light shielding property of the medicine bottle to be detected is achieved.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A shading detection device for a blood peptide oral liquid medicine bottle is characterized by comprising a base (10), a support column (20), a first lifting mechanism (30), a second lifting mechanism (40), a clamping assembly (50), an illumination assembly (60) and a light detection assembly (70);

the bottom end of the strut (20) is connected with the base (10);

the first lifting mechanism (30) and the second lifting mechanism (40) are connected with the strut (20) and can move relative to the strut (20) along the length direction of the strut (20), and the first lifting mechanism (30) is positioned on one side of the second lifting mechanism (40) facing the base (10);

the clamping assembly (50) is connected with the first lifting mechanism (30) and is used for clamping a blood peptide oral liquid medicine bottle;

the illumination assembly (60) is connected with the second lifting mechanism (40), and the illumination assembly (60) is opposite to the clamping assembly (50);

the light detection component (70) is connected with the base (10), and the light detection component (70) is opposite to the clamping component (50);

the first and second elevating mechanisms (30, 40) are configured to drive the clamping assembly (50) and the light-detecting assembly (60) to move toward the light-detecting assembly (70), respectively, such that the light-detecting assembly (60) and the light-detecting assembly (70) are located at both sides of the blood peptide oral liquid medicine bottle, respectively.

2. The shading detection apparatus according to claim 1, wherein the clamping assembly (50) comprises a first platform (51), a receptacle (52) and a light shield (53);

the first platform (51) is connected with the first lifting mechanism (30) and is vertical to the support column (20);

the insertion hole (52) is positioned on the first platform (51) and penetrates through two opposite plate surfaces of the first platform (51), and the axial direction of the insertion hole (52) is parallel to the support column (20);

the light shield (53) is located on one side, facing the illumination assembly (60), of the first platform (51), the light shield (53) is provided with a light inlet hole (53 a) and a light outlet hole (53 b), the light inlet hole (53 a) faces the illumination assembly (60), and the light outlet hole (53 b) is connected with the first platform (51) and communicated with the jack (52).

3. The shading detection device according to claim 2, wherein the light shield (53) is a truncated cone-shaped structure, the light inlet hole (53 a) is located at the end of the light shield (53) with the larger diameter, and the light outlet hole (53 b) is located at the end of the light shield (53) with the smaller diameter.

4. The occlusion detection device of claim 2, wherein the clamping assembly (50) further comprises a light reflective layer (54);

the light reflecting layer (54) is attached to the inner wall of the light shield (53).

5. The shading detection device according to claim 2, wherein an inner peripheral wall of the insertion hole (52) has a snap ring (55);

the clamping ring (55) is coaxial with the jack (52), and the inner peripheral wall of the clamping ring (55) is arc-shaped.

6. The shading detection apparatus according to claim 2, wherein the light detection assembly (70) comprises a bracket (71) and a light intensity sensor (72);

the bracket (71) is connected with the base (10);

the light intensity sensor (72) is located on one side, far away from the base (10), of the support (71) and connected with the support (71), and the light intensity sensor (72) is opposite to the insertion hole (52).

7. The shading detection apparatus according to claim 6, wherein the light detection assembly (70) further comprises an insert rod (73);

the insert rod (73) is parallel to the support column (20), a first end of the insert rod (73) is connected with the support (71), a second end of the insert rod (73) is movably inserted into the insertion hole (52), and the second end of the insert rod (73) is connected with the light intensity sensor (72).

8. The shading detection apparatus according to claim 6, wherein the illumination assembly (60) comprises a second platform (61) and a lamp bead (62);

the second platform (61) is connected with the second lifting mechanism (40) and is vertical to the support column (20);

the lamp beads (62) are located on one side, facing the first platform (51), of the second platform (61) and connected with the second platform (61), and the lamp beads (62) are opposite to the light inlet holes (53 a).

9. The shading detection device according to claim 8, wherein the first platform (51) is an elongated structural member, the number of the insertion holes (52) is plural, the plural insertion holes (52) are arranged at equal intervals along the length direction of the first platform (51), the light shields (53) are in one-to-one correspondence with the insertion holes (52), and the light shields (53) are communicated with the corresponding insertion holes (52);

the second platform (61) is a strip-shaped structural member, the lamp beads (62) correspond to the light shield (53) one by one, and the lamp beads (62) are opposite to the corresponding light inlet holes (53 a);

the support (71) is a long strip-shaped structural member, the light intensity sensors (72) correspond to the jacks (52) one by one, and the light intensity sensors (72) are opposite to the corresponding jacks (52).

10. The shading detection apparatus according to any one of claims 1 to 9, wherein an outer wall of the pillar (20) has a rack (21), the rack (21) extending in a length direction of the pillar (20);

first elevating system (30) are including going up and down seat (31), motor (32) and drive gear (33), the movably cover of going up and down seat (31) is established pillar (20), motor (32) with go up and down seat (31) and link to each other, drive gear (33) with the output shaft of motor (32) is coaxial to be linked to each other, drive gear (33) with rack (21) mesh mutually.

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