CN212780059U - Liquid sample detector - Google Patents

Abstract

The utility model provides a liquid sample detector, which comprises a liquid sample collecting cavity, a liquid sample collecting cavity and a cover body, wherein the liquid sample collecting cavity comprises an opening; be equipped with the annular on the lid and cave in, be equipped with the bellying region on the annular is sunken, when collecting chamber and lid and closing, the annular is sunken to enter into and is collected the chamber, the inner wall contact in bellying region and collection chamber to sealed collection chamber, annular sunken region is including being close to the wall closely of collecting the intracavity wall, keeping away from the remote wall of collecting the intracavity wall, wherein, the bellying region is located closely on the wall. The utility model discloses well lid adopts articulatedly with collection chamber one side, and one side adopts the joint, extrudees through the opening in collection chamber and the bellied region on the lid, makes the sunken elastic deformation that takes place of annular, lets the bellied region with collect chamber opening in close contact with and reach better sealed effect, simultaneously, the device is inside need not set up the sealing washer, has reduced manufacturing cost.

Description

Liquid sample detector

Technical Field

The utility model belongs to the technical field of sample collection device technique and specifically relates to a liquid sample detector, detection device is collected to urine for example.

Background

The following background description is merely an introduction to the general knowledge and is not intended to limit the invention in any way.

The liquid sample detector is a device for collecting liquid samples, and is generally used for detecting drugs, alcohol or similar items, and for this kind of detector, strict requirements are required for the sealing performance of the detector, so as to avoid the liquid leakage phenomenon of the liquid samples during transportation, and in addition, in order to avoid the occurrence of a plurality of different liquids in one liquid sample detector during item detection, the liquid sample detector mostly adopts the design standard of disposable products, so that enterprises are biased to select low-cost materials and processes convenient to manufacture in terms of materials and manufacturing processes.

Liquid sample detector among the prior art is most including lid, sealing washer, collection chamber, and lid assembly sealing washer is fixed in the collection chamber with the lid through the mode of spiral cover again on, adopts this kind of mode can play better sealed effect, but also has following technical problem:

1. the fixing mode of the screw cap is adopted: in the process of screwing the cover, one hand is required to hold the cover body, the other hand is used to hold the outer wall of the collecting cavity, and then the cover body is rotated to complete the covering, so that the situation that the hand shakes or the collecting cavity is held to be inclined is easily caused in the rotating process, and the liquid in the liquid sample detector leaks out to be stained with the outer side of the liquid sample detector, and the pollution is caused.

2. The fixing mode of the screw cap is relatively complex: the rotation takes a relatively large amount of time.

3. The production cost is high: each liquid sample detector all is equipped with a sealing washer, and the sealing washer cost is higher, and liquid sample detector still need install the sealing washer when the equipment in addition, and the manual assembly is with high costs.

The above technical problem raises the cost. Therefore, there is a need to redesign the structure of the urine cup, which needs to improve the conventional liquid sample detector and provide a simpler liquid sample detector without affecting the sealing effect of the product, so as to reduce the manufacturing cost.

Disclosure of Invention

An object of the present invention is to provide a liquid sample detector to solve the above problems in the prior art.

In order to achieve the above object, the present invention provides a liquid sample detector, which comprises a liquid sample collection chamber having an opening, and a cover for covering the opening of the collection chamber;

be equipped with the annular on the lid and cave in, be equipped with the bellying region on the annular is sunken, when collecting chamber and lid and closing, the annular is sunken to enter into and collects the chamber, the inner wall contact in bellying region and collection chamber to sealed collection chamber.

Further, the annular recessed region comprises a proximal wall proximal to the inner wall of the collection chamber, a distal wall distal to the inner wall of the collection chamber, wherein the raised region is located on the proximal wall.

Further, the thickness of the near wall is smaller than the thickness of the far wall, and the near wall is elastically deformed when the convex region comes into contact with the inner wall of the collection chamber.

Further, the annular recess is U-shaped.

Furthermore, the raised area surrounds the annular recess for a circle, and the section of the raised area is an arc surface with a smooth surface.

Furthermore, a cover edge used for wrapping the opening of the collecting cavity is arranged on the cover body.

Furthermore, the cover body is provided with a buckle structure, and when the cover body covers the opening of the collecting cavity, the buckle structure is clamped with the outer wall of the collecting cavity.

Furthermore, buckle structure is located and pulls and detains, pulls and detains and be the arc, pulls to detain and connects in the lid through connecting portion, and connecting portion take place elastic deformation easily.

Further, still include the body, there is liquid sample collection chamber in the body, and the body is articulated with the lid.

Furthermore, a first hinged connecting part is arranged on the bottle body, and a second hinged connecting part is arranged on the cover body;

the first hinge connecting part is a semi-enclosed circular groove with a downward opening, and the second hinge connecting part is a cylindrical pin.

To sum up, the utility model has the advantages that: the lid adopts articulatedly with collection chamber one side, and one side adopts the joint, through the opening in collection chamber and the protruding regional extrusion on the lid, makes the annular sunken elastic deformation that takes place, lets protruding region and collection chamber opening in close contact with reach better sealed effect, passes through the sealed comparison of screw thread rotation mode with traditional lid and collection chamber, all has easy and simple to handle, under the prerequisite of advantages such as sealed effectual, but relatively speaking, in repeated many times sample collection in-process, the rotatory mode of screw thread compares the utility model provides a technical scheme is loaded down with trivial details many, is difficult to operate, the utility model discloses a sample detector is "fast" more "than traditional technique, convenient; meanwhile, from the production perspective, the bottle body and the cover body can be directly processed and formed through the mold, and the production is convenient; a sealing ring is not arranged in the sample detector, so that the production cost is reduced; the design of screw thread formula is replaced to the buckled, has also avoided the liquid in the liquid sample detector sealed in-process, spills because of the liquid sample that rocks and lead to, is infected with the outside of liquid sample detector.

Drawings

FIG. 1 is a schematic diagram of the overall construction of a liquid sample detector;

FIG. 2 is a schematic view of the cap and body of the liquid sample detector assembled;

FIG. 3 is a schematic view of the liquid sample detector in a state where the cover is opened;

FIG. 4 is a schematic view of a collection plate loaded with a liquid sample detector;

FIG. 5 is a schematic view of a cartridge loaded carrier liquid sample detector as it is collected;

FIG. 6 is an overall cross-sectional view of a liquid sample detector;

FIG. 7 is an exploded view of the liquid sample detector in cross-section;

FIG. 8 is an enlarged partial schematic view of region "A" in FIG. 7;

FIG. 9 is a schematic view of the structure of the cover;

FIG. 10 is an enlarged partial view of the areas "B" and "C" in FIG. 7;

FIG. 11 is a schematic view of the structure of the bottom direction of the liquid sample detector;

FIG. 12 is a schematic view of the detector of FIG. 11 after being installed in a spring assembly;

fig. 13 is a structural diagram of the annular concave and convex regions on the cover body.

Detailed Description

The structures referred to in the present invention or these terms of art used are further described below, and if not otherwise indicated, they are understood and explained by general terms commonly used in the art.

Detection of

Detection refers to assaying or testing for the presence of a substance or material, such as, but not limited to, a chemical, organic compound, inorganic compound, metabolic product, drug or drug metabolite, organic tissue or a metabolite of organic tissue, nucleic acid, protein, or polymer. In addition, detection indicates the amount of the test substance or material. Further, the assay means immunodetection, chemical detection, enzyme detection, and the like.

Sample(s)

The sample detector or collected sample of the present invention includes a biological fluid (e.g., a case fluid or a clinical sample). Liquid or liquid samples, or fluid samples, may be derived from solid or semi-solid samples, including fecal, biological tissue and food samples. The solid or semi-solid sample may be converted to a liquid sample by any suitable method, such as mixing, triturating, macerating, incubating, dissolving, or enzymatically digesting a solid sample in a suitable solution (e.g., water, phosphate solution, or other buffered solution). "biological samples" include samples derived from animals, plants and food, including, for example, urine, saliva, blood and components thereof, spinal fluid, vaginal secretions, sperm, feces, sweat, secretions, tissues, organs, tumors, cultures, cell cultures and media of tissues and organs derived from humans or animals. Preferably, the biological sample is urine and preferably, the biological sample is saliva. Food samples include food processing materials, end products, meat, cheese, wine, milk and drinking water. Plant samples include those derived from any plant, plant tissue, plant cell culture and medium. An "environmental sample" is derived from the environment (e.g., a liquid sample from a lake or other body of water, a sewage sample, a soil sample, groundwater, seawater, and a waste liquid sample). Environmental samples may also include sewage or other wastewater.

Utilize the utility model discloses suitable detecting element or test element can detect any analyte. Preferably utilizes the utility model discloses detect the drugs micromolecule in saliva, urine. Of course, any of the above forms of samples, whether initially solid or liquid, may be collected using the collection device of the present invention, provided that the liquid or liquid sample is absorbed by the absorbent member. Absorbent members herein are generally made of a water-absorbent material that is initially dry and capable of absorbing a liquid or fluid sample by capillary or other properties of the absorbent member material. The absorbent material may be any material capable of absorbing liquid, such as sponge, filter paper, polyester fiber, gel, nonwoven fabric, cotton, polyester film, yarn, and the like. Of course the absorbent member need not be made of absorbent material and may be made of non-absorbent material, but rather the absorbent member has holes, threads, cavities therein, and samples, typically solid or semi-solid samples, may be collected on such structures and filled between the threads, the holes, or the pores.

Downstream and upstream

Downstream or upstream is divided with respect to the direction of liquid flow, typically liquid flows from upstream to downstream regions. The downstream region receives liquid from the upstream region, and liquid may also flow along the upstream region to the downstream region. It is also generally divided in the direction of liquid flow, for example, on materials that use capillary forces to urge liquid flow, the liquid may flow by gravity in the opposite direction to gravity, and in this case, the upstream and downstream are also divided in the direction of liquid flow.

Gas or liquid communication

By gas or liquid communication is meant that liquid or gas can flow from one place to another, possibly guided by some physical structure during the flow. By physical structures is generally meant that the liquid flows passively or actively to another place through the surface of the physical structures or the space inside the physical structures, and passively is generally a flow caused by external force, such as a flow under capillary action. The flow here can also be a liquid or a gas, because of its own effect (gravity or pressure), or a passive flow. Communication herein does not necessarily mean that a liquid or gas is required to be present, but merely that in some cases a connection or condition between two objects, if any, may flow from one object to the other. This refers to a state in which two objects are connected, and conversely, if there is no liquid communication or gas communication between the two objects, if there is liquid in or on one object, the liquid cannot flow into or on the other object, and such a state is a state of non-communication, non-liquid or gas communication.

Test element

The term "test element" as used herein refers to an element that can detect whether a sample or specimen contains an analyte of interest, and the detection can be based on any technical principles, such as immunology, chemistry, electricity, optics, molecular, nucleic acid, physics, etc. The test element may be a lateral flow test strip which detects a plurality of analytes. Of course, other suitable test elements may be used with the present invention.

Various test elements may be combined and used in the present invention. One form is a test strip. Test strips for the analysis of analytes, such as drugs or metabolites indicative of a physical condition, in a sample may be in various forms, such as immunoassay or chemical assay forms. The test strip may be used in a non-competitive or competitive assay format. The test strip generally comprises a bibulous material having a sample application area, a reagent area, and a test area. The sample is added to the sample application zone and flows by capillary action to the reagent zone. In the reagent zone, the sample binds to the reagent if the analyte is present. The sample then continues to flow to the detection zone. Other reagents, such as molecules that specifically bind to the analyte, are immobilized at the detection zone. These reagents react with the analyte (if present) in the sample and bind the analyte to the zone, or to one of the reagents of the reagent zone. The label for indicating the detection signal is present in the reagent zone or in a separate label zone.

A typical non-competitive assay format is one in which a signal is generated if the sample contains the analyte and no signal is generated if the analyte is not present. In a competition method, a signal is generated if the analyte is not present in the sample and no signal is generated if the analyte is present.

The test element can be a test paper, and can be made of water-absorbing or non-water-absorbing materials. The test strip may include a variety of materials for liquid sample delivery. One of the test strips may be coated with another material, such as a nitrocellulose membrane coated with filter paper. One region of the test strip may be selected from one or more materials and another region may be selected from a different one or more materials. The test strip may be adhered to some support or hard surface for improved strength when the test strip is held in place.

The analyte is detected by a signal producing system, such as one or more enzymes that specifically react with the analyte, and one or more compositions of the signal producing system are immobilized on the analyte detection zone of the test strip by a method such as that described above for the immobilization of a specific binding substance on the test strip. The signal-producing substance can be on the sample addition zone, reagent zone, or detection zone, or the entire test strip, and the substance can be impregnated on one or more materials of the test strip. A solution containing the signal is applied to the surface of the strip or one or more materials of the strip are immersed in the solution containing the signal. The strip to which the solution containing the signal substance was added was dried.

The various regions of the test strip may be arranged as follows: the device comprises a sample adding area, a reagent area, a detection area, a control area, a sample adulteration area and a liquid sample absorption area. The control zone is located behind the detection zone. All zones may be arranged on a strip of test paper using only one material. It is also possible to use different materials for the different zones. The zones may be in direct contact with the liquid sample, or different zones may be arranged according to the direction of flow of the liquid sample, with the ends of each zone being contiguous with and overlapping the ends of the other zone. The material used can be a material with good water absorption such as filter paper, glass fiber or nitrocellulose membrane. The test strip may take other forms.

A commonly used reagent strip is a nitrocellulose membrane reagent strip, i.e., a detection area comprises a nitrocellulose membrane, and a specific binding molecule is fixed on the nitrocellulose membrane to display the detection result; and may be a cellulose acetate film, a nylon film, or the like. Such as the reagent strips or devices containing the reagent strips described in some of the following patents: US 4857453; US 5073484; US 5119831; US 5185127; US 5275785; US 5416000; US 5504013; US 5602040; US 5622871; US 5654162; US 5656503; US 5686315; US 5766961; US 5770460; US 5916815; US 5976895; US 6248598; US 6140136; US 6187269; US 6187598; US 6228660; US 6235241; US 6306642; US 6352862; US 6372515; US 6379620; and US 6403383. The test strip disclosed in the above patent documents and similar devices with test strips can be applied to the test element or the test device of the present invention for detecting an analyte, such as an analyte in a sample.

The test strips used in the present invention may be so-called Lateral flow test strips (Lateral flow test strips), and the specific structure and detection principle of these test strips are well known in the art. A typical test strip comprises a sample collection area or application area, a labeling area comprising a label pad, a detection area comprising a bibulous pad, and a bibulous area comprising the necessary chemicals to detect the presence of the analyte, such as immunological or enzymatic reagents. A commonly used detection reagent strip is a nitrocellulose membrane reagent strip, that is, a detection area comprises a nitrocellulose membrane, and a specific binding molecule is fixed on the nitrocellulose membrane to display a detection result; it may be a cellulose acetate film, a nylon film, etc., and it may also include a detection result control region downstream of the detection region, and usually, the control region and the detection region are in the form of a transverse line, which is a detection line or a control line. Such test strips are conventional, but other types of test strips that utilize capillary action for testing are also contemplated. In addition, typically, the test strip has a dry chemical reagent component, such as an immobilized antibody or other reagent, which when exposed to a liquid, flows along the test strip by capillary action, and as it flows, the dry reagent component is dissolved in the liquid, and the next zone is processed to react the dry reagent in that zone, thereby performing the necessary test. The liquid flow is mainly by capillary action. The present invention can be applied to a detecting device, or can be disposed in a detecting chamber to contact with a liquid sample, or can be used to detect whether an analyte exists or the amount of the analyte exists in the liquid sample entering the detecting chamber.

In addition to the test strips described above or the lateral flow test strip itself being used to contact a liquid sample to test for the presence of an analyte. In some preferred forms, the test element may also be provided on a carrier having a plurality of recesses in which the test element is located. In some embodiments, the carrier includes a recessed area for receiving the test elements, and a plurality of recesses are provided in the recessed area, each of which can receive a test strip, and each of which can detect an analyte. In some embodiments, after the test elements are disposed in the recesses of the carrier, the carrier is covered with a transparent film, which seals the recess area of the carrier and facilitates viewing of the test results on the final test area. The transparent film may also be a transparent plastic sheet, transparent only in the test area.

Typically, the test strip includes a sample application region, a labeling region and a detection region, the sample application region being positioned adjacent to the bottom of the carrier and slightly exposing the recess, for example 2-3 mm, when the test strip is placed, with a portion of the sample application region reserved to absorb fluid sample flowing into the bottom of the collection chamber. Typically, the sample application zone is located upstream of the labeling zone, which is located upstream of the detection zone.

Such carriers are useful for carrying test strips in the following applications, and these particular carriers may be used in the collection chamber of the present invention as part of the assay, such as described in the following patents: DE19780221T1, JP1999506213A, US6702988, US7244392, US20040133128A, US20070065339a 1.

Analyte substance

Examples of analytes that can be used in the present invention include small molecule substances, including drugs of abuse (e.g., drugs of abuse). By "drug of abuse" (DOA) is meant the use of a drug (usually acting to paralyze nerves) at a non-medical destination. Abuse of these drugs can result in physical and mental damage, dependence, addiction and/or death. Examples of drug abuse include cocaine; amphetamine AMP (e.g., black americane, white amphetamine tablets, dextroamphetamine tablets, Beans); methamphetamine MET (crank, methamphetamine, crystal, speed); barbiturate BAR (e.g., Valium, Roche Pharmaceuticals, Nutley, New Jersey); sedatives (i.e., sleep-aid drugs); lysergic acid diethylamide (LSD); inhibitors (downs, goofballs, barbs, blue devils, yellow jacks, hypnones); tricyclic antidepressants (TCAs, i.e., imipramine, amitriptyline and doxepin); dimethyldioxymethylaniline MDMA; phencyclidine (PCP); tetrahydrocannabinol (THC, pot, dope, hash, weed, etc.); opiates (i.e., morphine, or opiates, cocaine, COC; heroin, dihydrocodeinone); anxiolytic and sedative hypnotic, anxiolytic is a kind of mainly used for relieving anxiety, stress, fear, stabilize mood, have hypnotic sedative effects at the same time, including benzodiazepine BZO (benzodiazepines), atypical BZ, fuse dinitrogen NB23C, benzodiazepine, BZ receptor ligand, ring-opening BZ, diphenylmethane derivatives, piperazine carboxylate, piperidine carboxylate, quinazolone, thiazine and thiazole derivatives, other heterocycles, imidazole type sedative/analgesic (such as dihydrocodeinone OXY, methadone MTD), propylene glycol derivative-carbamate, aliphatic compound, anthracene derivatives, etc.. The detection device of the utility model can also be used for detecting the detection which belongs to the medical purpose and is easy to take excessive medicine, such as tricyclic antidepressants (imipramine or analogues) and acetaminophen, etc. After being absorbed by human body, the medicines are metabolized into small molecular substances, and the small molecular substances exist in body fluids such as blood, urine, saliva, sweat and the like or exist in partial body fluids.

For example, analytes detected by the present invention include, but are not limited to, creatinine, bilirubin, nitrite, protein (non-specific), hormones (e.g., human chorionic gonadotropin, progesterone hormone, follicle stimulating hormone, etc.), blood, leukocytes, sugars, heavy metals or toxins, bacterial material (e.g., proteins or carbohydrate material directed against specific bacteria, such as, for example, Escherichia coli 0157: H7, staphylococci, Salmonella, Clostridium, Campylobacter, L.monocytogenes, Vibrio, or Cactus), and substances associated with physiological characteristics in urine samples, such as pH and specific gravity. Any other clinical urine chemical analysis can all utilize the cooperation of side direction crossing current detection form the utility model discloses the device detects.

Collection cavity

The collection chamber is the location where the sample is contained and typically has test elements disposed within recesses in the carrier or within a plurality of elongated cavities formed in the carrier, typically with the sample application area of the test element near the bottom of the collection chamber, contacting the liquid sample, e.g., urine, which flows up the test strip by capillary force, through the detection zone on the test strip.

As shown in fig. 1-3, a collection chamber 21 is disposed in the bottle body 20, the collection chamber 21 includes an opening at the upper side of the bottle body 20, and a sample can be added into the collection chamber 21 from the opening at the upper side of the bottle body 20.

In some embodiments, the body 20 is transparent, or a transparent area is provided on the body 20, and the transparent area is provided with a scale mark 22, and the scale mark 22 can be provided on the inner wall or the outer wall of the collection chamber 21.

In some modes, the annular boss 23 is arranged on the outer wall of the collection cavity 21, as shown in fig. 4-5, the annular boss 23 can be erected in the hole on the collection plate and the collection box, and meanwhile, the position of the annular boss 23 is located above 1/2 of the bottle body 20, so that the liquid sample detector is not prone to side turning during transportation, and liquid leakage is avoided.

In some embodiments, the label holding area 24 is provided on the body 20, and preferably, the label holding area 24 and the scale mark 22 are located on the same side of the collection chamber 21.

Cover and collection cavity

The cover 10 can cover the collection chamber 21 for sealing the collection chamber 21 and preventing the liquid sample in the collection chamber 21 from leaking out. As shown in fig. 6-9 and 13, the cover 10 is provided with an annular recess 11, and when the collecting cavity 21 is covered with the cover 10, the annular recess 11 is embedded into the collecting cavity 21. In traditional liquid detector, the form that sets up the elasticity sealing washer in the adoption lid lets the cup of elasticity sealing washer and collection chamber 21 open position along 211 contacts, thereby along with the rotation of lid, the sealing washer lets lid 10 and cup along 211 in close contact with and reach sealed effect, adopts the form of sealing washer to increase production and assembly cost. In this design, the cover 10 is not provided with a sealing ring to seal the opening of the collection chamber 21, but the cover 10 seals the opening of the collection chamber 21 by means of the cooperation between the annular recess 11 and the inner wall of the collection chamber 21. As will be described in detail below, with reference to fig. 8, the annular recess 11 is provided with a raised area 12, the raised area 12 being located on the side of the annular recess 11 that contacts the inner wall near the opening of the collection chamber 21, and with reference to fig. 13, the raised area 12 surrounds the annular recess 11 by one turn. Referring to fig. 6 and 8, when the collection chamber 21 and the cover body 10 are closed, the inner wall near the opening of the collection chamber 21 contacts with the convex region 12 to seal the collection chamber 21, in the mutual contact process, the inner wall near the opening of the collection chamber 21 presses the annular recess 11 through the convex region 12 to cause the annular recess 11 to generate elastic deformation, the annular recess 11 after the elastic deformation has a reaction force for recovering the original state, and the reaction force firmly abuts the convex region 12 with the inner wall of the collection chamber 21 to enable the sealing to be tight. In some preferred forms, in fig. 8, the annular recess 11 has a U-shape, and the annular recess 11 includes a short-distance wall 40 (with respect to the inner wall of the collection chamber), a long-distance wall 41 and a bottom 42, the short-distance wall 40 being a portion of the annular recess 11 close to the opening of the collection chamber 21, the long-distance wall 41 being a portion of the annular recess 11 far from the opening of the collection chamber 21, and the bottom 42 being a portion of the annular recess 11 connecting the short-distance wall 40 and the long-distance wall 41. The raised region 12 is located on the proximal wall 40. The U-shaped annular recess 11 enables the short-distance wall 40 to be approximately parallel to the inner wall near the opening of the collecting cavity 21, and at the moment, if the depth of some short-distance walls 40 (the length of the short-distance walls 40 in the vertical direction) is increased, the contact area between the annular recess 11 and the opening of the collecting cavity 21 can be increased, so that the annular recess 11 is embedded into the collecting cavity 21 after the cover is closed, and the cover body 10 is not easy to fall off. Meanwhile, the thickness of the short-distance wall 40 (the length of the short-distance wall 40 in the horizontal direction) is smaller than that of the long-distance wall 41 (the length of the long-distance wall 41 in the horizontal direction), because the raised area 12 on the short-distance wall 40 on the annular recess 11 contacts with the inner wall near the opening of the collecting cavity 21 during the covering process, so that when the raised area 12 contacts with the inner wall of the collecting cavity 21 and then interacts with each other, the short-distance wall 40 where the raised area 12 is located is more easily deformed, and thus a reaction force is provided, so that the raised area closely contacts with the inner wall of the collecting cavity to realize sealing. Conversely, if the thickness of the short distance wall 40 is too large, the position of the short distance wall 40 on the annular recess 11 is not easily deformed, which is embodied as: the cover body 10 and the collection cavity 21 are difficult to cover; the long-distance wall 41 and the bottom 42 of the annular recess 11 do not contact with the opening of the collecting cavity 21, and the two positions have larger thicknesses, which help the short-distance wall 40 of the annular recess 11 to restore to the original shape after deformation, and make the annular recess 11 not easy to break during the deformation process. In some preferred modes, the cross section of the convex area 12 is a cambered surface with a smooth surface, so that the covering process of the collection cavity 21 and the cover body 10 can be gentle, and the sudden change similar to a snap-in type can not be generated. In some embodiments, raised area 12 and proximal wall 40 are formed of the same material and may be formed in one step by a mold, which is more convenient and less costly to manufacture. In another embodiment, the thickness of the short-distance wall 40 is not as small as possible on the condition that the thickness of the short-distance wall 40 is smaller than the thickness of the long-distance wall 41, but the thickness of the short-distance wall 40 is smaller than the thickness of the long-distance wall 41, because the short-distance wall 40 itself is more easily elastically deformed after the thickness of the short-distance wall 40 is small, and the cover body 10 and the collection chamber 21 can be easily closed, but the thickness of the short-distance wall 40 is smaller than the thickness of the long-distance wall 41, but the thickness of the short-distance wall 40 should not be too small. Through a plurality of tests, when the opening diameter of the collecting cavity 21 is 55-65mm, the thickness of the far wall 41 is preferably 1.2-1.3mm, the thickness of the near wall 40 is preferably 0.7-0.8mm, the thickness of the thickest part of the convex region 12 (the maximum length of the convex region 12 in the horizontal direction) is preferably 0.3-0.4mm, the width of the annular recess 11 (the maximum distance between the far wall 41 and the near wall 40) is preferably 5.0-5.2mm, the depth of the annular recess 11 (the maximum distance between the lowest part of the bottom 42 and the upper surface of the cover body 10) is preferably 5.6-5.8mm, and the thickness of the bottom 42 (the maximum length of the bottom 42 in the vertical direction) is preferably 1.2-1.3mm, so that a good sealing effect can be achieved. In a test experiment in which vacuum negative pressure (-0.03MPa or-0.02 MPa) was performed, the urine cup was tilted by 45 degrees, and if there was no liquid leakage from the device for 10 minutes (-0.02MPa) or 2-3 minutes (-0.03MPa), the device or the urine cup would not cause leakage in a later use. The test mode is that the collection cavity is filled with urine, the cover body is covered, the detector is placed in the collection box shown in figure 5, the collection box is inclined by 45 degrees, then the collection box is moved to the test environment with the environment of-0.03 MPa or-0.02 MPa to carry out a test experiment for a certain time (10 minutes or 2-3 minutes corresponding to the pressure environment), and if no urine leaks out of the device, the sealing effect is good. To the utility model discloses a sample detector has carried out 120 sample detectors and is-0.02 MPa at pressure, and the duration is 10 minutes's test experiment, discovers that all sample detectors can all maintain 10 minutes and do not have revealing of urine, explains the utility model discloses a seal structure can effectively obtain sealed effect, avoids leaking at the in-process of transportation or storage after the sample is collected.

In some aspects, referring to fig. 1 and 8, the cover rim 13 for covering the opening of the collection cavity 21 is provided on the cover body 10, in case the cover body 10 does not have the cover rim 13, when the cover body 10 is covered with the collection cavity 21, since the opening of the collection cavity 21 presses the short distance wall 40 on the annular recess 11 through the raised area 12 to generate elastic deformation, at this time, the outer ring portion 14 of the cover body 10 located on the annular recess 11 is affected by the short distance wall 40 to tilt outwards, which is very disadvantageous for the sealing of the collection cavity 21, since the cover rim 13 is used for covering the opening of the collection cavity 21, and has a curvature and is in fit with the opening of the collection cavity 21, the arrangement of the cover rim 13 can avoid the outer ring portion 14 from tilting outwards, that is, during the covering process of the cover body 10 with the collection cavity 21, the outer ring portion 14 is not significantly deformed (the outer ring portion 14 is pulled by the short distance wall 40 and, slight deformation is still present but cannot be seen by naked eyes without affecting the sealing effect), the sealing effect of the cover body 10 can be greatly improved.

In some modes, the cover 10 is provided with a fastening structure 15, when the cover 10 covers the opening of the collection cavity 21, the fastening structure 15 is fastened to the outer wall of the collection cavity 21 (the bottle body 20), specifically, the outer wall of the collection cavity 21 includes a protruding structure 16, and the fastening structure 15 is fastened to the protruding structure 16. The snap-in means here means that the cap 10 cooperates with the collection chamber 21 in a similar "plug-in" or "piston" manner, by means of a snap-in connection. The manner of clamping is opposite to the manner of screw rotation. The thread pattern requires relative rotation and then the cap and collection chamber are brought together. In some preferred forms, referring to fig. 10, the snap feature 15 includes a first upper snap surface 17 and a first lower snap surface 18, the projection feature 16 includes a second upper snap surface 25 and a second lower snap surface 19, in the process of closing the cover body 10 and the collection cavity 21, the first lower fastening surface 18 contacts with the second upper fastening surface 25 to cause the elastic deformation of the fastening structure 15, then the first upper fastening surface 17 contacts with the second lower fastening surface 19 to realize clamping, in the process, the covering process is easy, the cover body and the collecting cavity are not easy to separate after covering, therefore, the planes of the first lower buckling surface 18 and the second upper buckling surface 25 are inclined, the inclined planes can decompose the covering force in the vertical direction into a force in the horizontal direction when the buckling structure 15 and the protruding structure 16 are contacted, so that the buckling structure 15 is subjected to elastic deformation and is temporarily staggered with the protruding structure 16, and the buckling structure 15 is restored to the original state after being staggered and is clamped with the protruding structure 16; the plane of the first upper fastening surface 17 and the second lower fastening surface 19 is horizontal, when the fastening structure 15 is fastened with the protruding structure 16, the covering force in the vertical direction cannot be resolved into a force in the horizontal direction, so that it is very difficult to separate the cover body 10 from the collecting cavity 21 only by the force in the vertical direction. In some preferred modes, referring to fig. 1, the fastening structure 15 is located on the pulling buckle 26, the pulling buckle 26 is arc-shaped, which facilitates pulling of fingers, when the pulling buckle 26 is pulled by fingers, the elastic deformation of the fastening structure 15 and the temporary staggering of the protruding structure 16 occur, the fastening structure 15 and the protruding structure 16 are no longer clamped, in addition, two connecting portions 27 for connecting the cover body 10 are arranged on the fastening structure 15, in the clamping and separating processes of the fastening structure 15 and the protruding structure 16, mainly, the connecting portions 27 are elastically deformed, and meanwhile, in order to vacate positions for the protruding structure 16, a certain distance needs to be kept between the two connecting portions 27.

In some ways, in order to facilitate the protrusion 16 on the outer wall of the collection cavity 21 to be easily buckled with the buckling structure 15 on the cover 10, the first lower buckling surface 18 and the second upper buckling surface 25 have smooth surfaces, and the two smooth surfaces reduce friction in sliding fit, so that the cover 10 can be matched with the collection cavity 21 with little effort.

In some embodiments, at least two, or more than three snap structures 15 are provided on the cap body 10, and the snap structures 15 are provided on the cap body 10 in an array, in which the cap body 10 is separated from the bottle body 20.

In some preferred modes, the cover 10 and the bottle body 20 can be assembled together, the cover 10 is hinged to the bottle body 20, so as to avoid that the cover 10 cannot be found when the liquid sample is collected, as shown in fig. 1-3 and 11, fig. 1 shows the state when the detector is covered, fig. 2 and 3 show how the detector cover 10 is hinged to the bottle body 20, fig. 11 shows the specific structure of the connecting position of the cover 10 and the bottle body 20 more clearly from the bottom direction of the detector, the bottle body 20 is provided with a first hinge connecting part 28, the cover 10 is provided with a second hinge connecting part 29, the first hinge connecting part 28 comprises a semi-enclosed circular groove 31 with a downward opening, the second hinge connecting part 29 comprises a cylindrical pin 32, the second hinge connecting part 29 can be installed in the first hinge connecting part 28, so that the cylindrical pin 32 is hinged to the circular groove 31 and can rotate freely, as a further technical solution, in the actual use process, when the semi-enclosed circular groove 31 is directly connected with the bottle body 20, there is a problem that the strength of the connection position 33 is insufficient, the first hinge connection portion 28 is easily broken, and in addition, after the second hinge connection portion 29 is rotated in the first hinge connection portion 28 for a plurality of times, the semi-enclosed circular groove 31 of the first hinge connection portion 28 is easily loosened, the cylindrical pin 32 on the second hinge connection portion 29 is easily separated from the opening of the semi-enclosed circular groove 31, in order to solve the two technical problems, the first hinge connection portion 28 further includes a structural reinforcing rib 30, the structural reinforcing rib 30 is connected with the inside of the semi-enclosed circular groove 31, so that the opening size of the lower end of the circular groove 31 is kept constant, the cylindrical pin 32 is not loosened after being loaded and rotated for a plurality of times, and the structural reinforcing rib 30 is also connected to the bottle body 20, thereby enhancing the strength of the connection position of the first hinge connection portion 28 on the bottle body, it is to be noted that the structural reinforcement 30 connects the interior of the semi-enclosed circular groove 31, dividing the circular groove 31 into two symmetrical parts, which are no longer through, and correspondingly, the second hinge connection 29 is also divided into two short cylindrical pins 32, which are hinged to the two circular grooves 31 in the first hinge connection 28. Lid 10 and body 20 articulated back, can only set up a buckle structure 15 on the body 20, lid 10 adopts articulatedly with collection chamber 21 one side, one side adopts the joint, annular on the deuterogamy lid 10 is sunken 11, can play fabulous sealed effect, pass through the sealed comparison of screw thread rotation mode with traditional lid 10 and collection chamber 21, both all have easy and simple to handle, sealed effectual characteristics, but relatively speaking, in repeated many times sample collection in-process, the rotatory mode of screw thread compares the utility model provides a technical scheme is loaded down with trivial details many, is difficult to operate. The utility model discloses a sample detection ware aim at accomplishes sealed fast, "fast", "convenient" is the utility model discloses a required primary requirement that reaches of sample detection ware. Meanwhile, from the production angle, the bottle body 20 and the cover body 10 can be directly processed and formed through a die, the production is convenient, no sealing ring is arranged inside the sample detector, and the production cost is reduced. The design of screw thread formula is replaced to the buckled, has also avoided the liquid in the liquid sample detector sealed in-process, spills because of the liquid sample that rocks and lead to, is infected with the outside of liquid sample detector.

In some preferred manners, an elastic device is disposed between the first hinge connection portion 28 and the second hinge connection portion 29, when the cover body 10 and the collection cavity 21 are out of the clamping state, the elastic device is used for automatically overturning the cover body 10 to achieve automatic opening of the collection cavity 21, specifically, as shown in fig. 12, the elastic device may be a torsion spring 34, the torsion spring 34 is located in the circular groove 31, the torsion spring 34 connects the structural reinforcing rib 30 and the cylindrical pin 32, when an operator pushes down the cover body 10 to cover the collection cavity 21, the torsion spring 34 stores elastic potential energy, when the operator pulls the pull buckle 26, the cover body 10 and the collection cavity 21 are out of the clamping state, the torsion spring 34 releases the elastic potential energy, and the cover body 10 is automatically opened. Meanwhile, when the cover body 10 and the collection chamber 21 are in the covering state, the elastic potential energy of the torsion spring 34 can make the buckle structure 15 and the protrusion structure 16 contact more tightly, and at this time, the trigger 26 is not easy to pull outwards, so that the covering state of the cover body 10 and the collection chamber 21 is more firm.

The above description is only the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions that are not thought of through creative work should be covered within the protection scope of the present invention, and therefore, the protection scope of the present invention should be subject to the protection scope defined by the claims.

The utility model shown and described herein may be implemented in the absence of any element, limitation, or limitations specifically disclosed herein. The terms and expressions which have been employed are used as terms of description and not of limitation, and there is no intention in the use of such terms and expressions of excluding any equivalents of the features shown and described or portions thereof, and it is recognized that various modifications are possible within the scope of the invention. It should therefore be understood that although the present invention has been specifically disclosed by various embodiments and optional features, modification and variation of the concepts herein described may be resorted to by those skilled in the art, and that such modifications and variations are considered to be within the scope of this invention as defined by the appended claims.

The contents of the articles, patents, patent applications, and all other documents and electronically available information described or cited herein are hereby incorporated by reference in their entirety to the same extent as if each individual publication was specifically and individually indicated to be incorporated by reference. Applicants reserve the right to incorporate into this application any and all materials and information from any such articles, patents, patent applications, or other documents.

Claims (10)

1. The liquid sample detector is characterized by comprising a liquid sample collecting cavity, a sample collecting cavity and a cover body, wherein the liquid sample collecting cavity comprises an opening;

be equipped with the annular on the lid and cave in, be equipped with the bellying region on the annular is sunken, when collecting chamber and lid and closing, the annular is sunken to enter into and collects the chamber, the inner wall contact in bellying region and collection chamber to sealed collection chamber.

2. The liquid sample detector of claim 1, wherein the annular recessed region comprises a proximal wall proximate the inner wall of the collection chamber and a distal wall distal from the inner wall of the collection chamber, and wherein the raised region is located on the proximal wall.

3. The liquid sample detector of claim 2, wherein the thickness of the proximal wall is less than the thickness of the distal wall, and wherein the proximal wall is elastically deformed when the raised region contacts the inner wall of the collection chamber.

4. The liquid sample detector of claim 1, wherein the annular recess is U-shaped.

5. The liquid sample detector of claim 1, wherein the raised area surrounds the annular recess, and the cross-section of the raised area is a smooth-surfaced arc.

6. The liquid sample detector of claim 1, wherein the cover has a cover rim for covering the opening of the collection chamber.

7. The liquid sample detector of claim 1, wherein the cover has a snap structure that engages an outer wall of the collection chamber when the cover closes the opening of the collection chamber.

8. The liquid sample detector of claim 7, wherein the latch is located on a trigger, the trigger is curved, the trigger is connected to the cover through a connecting portion, and the connecting portion is easily elastically deformed.

9. The liquid sample detector of claim 1, further comprising a body, wherein the body defines a liquid sample collection well, and the body is hinged to the cover.

10. The liquid sample detector of claim 9, wherein the bottle body has a first hinge connection portion, the cover has a second hinge connection portion, and the first hinge connection portion is rotatably coupled to the second hinge connection portion;

the first hinge connecting part is a semi-enclosed circular groove with a downward opening, and the second hinge connecting part is a cylindrical pin.

Images