CN215575190U - Flip subassembly and sample analysis appearance - Google Patents

Abstract

The application discloses flip subassembly and sample analysis appearance, this flip subassembly includes: the inner side of the flip door is provided with a supporting slide way, a supporting slide rod is arranged in the supporting slide way, and the first end of the supporting slide rod is used for supporting the flip door when the flip door rotates; the hinge is arranged between the flip door and the host and is used for rotatably hinging the flip door and the host so as to enable the flip door to rotate along the hinge; and the damper is connected with the second end of the supporting slide rod and used for providing damping for the flip door so as to enable the included angle between the flip door and the host machine to be 0-180 degrees. Through the mode, the flip assembly can be provided, in the process of being turned over along with the flip door, through the matching operation among the supporting slide way, the supporting slide rod, the hinge and the damper, the fixing of the position, corresponding to any angle in 0-180 degrees, between the flip door and the host is achieved, and therefore better user experience is provided.

Description

Flip subassembly and sample analysis appearance

Technical Field

The present application relates to the field of medical devices, and more particularly, to a flip assembly and a sample analyzer.

Background

With the use of a wide variety of medical agents, there is an increasing demand for a medical device that operates smoothly, and the arrangement and planning of the components of the medical device assembly is therefore of increasing importance and interest.

In the existing market, because the flip door arranged on the medical instrument is usually fixedly connected to the host machine through the rotation of the rotating shaft, the flip door can be manually opened when an operator needs to operate the interior of the medical instrument.

Therefore, the inventor of the present application finds, through long-term research, that in the related art, when the flip door is operated manually, the hinge structure between the flip door and the host is unstable because the hinge only plays a role in connecting the host and the flip door, so that noise is easily generated and the flip door is easily shaken in the flipping process, the flipping angle cannot be compatible with flipping 180 degrees and stopping at any angle, and then the flip door touches the head of a user with a high height to cause influence.

SUMMERY OF THE UTILITY MODEL

The present application provides a flip assembly and a sample analyzer to solve the above-mentioned problems of flip assemblies in the prior art.

In order to solve the above technical problem, a first technical solution adopted by the present application provides a flip assembly, including: the inner side of the flip door is provided with a supporting slide way, a supporting slide rod is arranged in the supporting slide way, and the first end of the supporting slide rod is used for supporting the flip door when the flip door rotates; the hinge is arranged between the flip door and the host and is used for rotatably hinging the flip door and the host so as to enable the flip door to rotate along the hinge; and the damper is connected with the second end of the supporting slide rod and used for providing damping for the flip door so as to enable the included angle between the flip door and the host machine to be 0-180 degrees.

The flip door is provided with a first part and a second part which are connected in a sliding mode, the first part is provided with an accommodating cavity and an opening, and the second part slides into the accommodating cavity through the opening. By dividing the flap door into a first part and a second part which are linked in a sliding manner, the receiving space of the first part can receive the first part, so that the volume of the flap door is reduced, thereby providing the possibility for stabilizing the flap door.

The first part is provided with a guide rail, the guide rail comprises at least two mutually parallel slide rails, the at least two slide rails are respectively arranged on the inner side wall which is relatively far away from the first part, and the second part slides into the accommodating cavity through the guide rail. The sliding rails which are parallel to each other are arranged on the inner side wall which is far away from the first component relatively, so that the second component can slide into the accommodating cavity of the first component along the sliding rails which are parallel to each other in a relatively stable posture, and the probability of shaking of the flip door can be reduced as much as possible when the second component slides into the accommodating cavity of the first component.

The second component is provided with a plurality of guide grooves which are respectively matched with the guide rails in a one-to-one correspondence mode, and the second component slides into the guide rails through the guide grooves so that the second component slides into the accommodating cavity. Through set up the guide slot with the guide rail one-to-one on the second part, can be so that guide rail and guide slot carry out the relative slip through the relation that matches each other, be favorable to promoting the second part and slide into the realizability of the holding chamber scheme of first part.

Wherein, the guide rail sets up to the I shape guide rail, and the guide slot sets up to the draw-in groove formula guide slot with I shape guide rail complex. Through the cooperation between I shape guide rail and the draw-in groove formula guide slot, not only can simple to operate, it is easy to exchange, can also reduce the produced frictional force of relative slip by a wide margin to lubricating structure between I shape guide rail and the draw-in groove formula guide slot is simple, and the wearing and tearing between the two reduce, make and realize the motion steadily between first part and the second part, reduce impact and vibration and keep the slip sensitivity for a long time, dustproof and leakproofness is also better moreover.

Wherein, the supporting slideway is arranged on the first part close to one side of the opening of the host. By providing the support slide on the side of the access door adjacent to the main unit, it is possible to keep the overall configuration of the flap door and the housing portion of the main unit more aesthetically pleasing.

The flip component comprises two hinges, and the damper is arranged between the two hinges and is positioned between the flip door and the host. Through setting up two hinges, can rotate articulated flip door and host computer, the drive power that two links provided is bigger to it is faster along the hinge rotation to make the flip door, is favorable to saving the time of flip door upset. And the damper is arranged between the two hinges, so that the driving force provided by the two hinges is more stable, the noise in the turnover process of the flip door is reduced, and the first part of the flip door can be fixed at will between 0 and 180 degrees, so that the position relation between the flip door and the host is determined.

When the included angle between the flip door and the host is larger than 90 degrees, the accommodating cavity of the first component is used for accommodating the second component which slides into the first component. The second component slides into the accommodating cavity of the first component through the angle relation between the flip door and the host machine in a specific scene, and the scheme is favorable for realizability.

Wherein, the one end that first part was kept away from to the second part is equipped with the covering, and covering and flip door are used for hiding the host computer. Through set up the covering on the second part, can increase the weight of second part, can make the flip door can be better cover the opening of host computer on the one hand, on the other hand can also make the second part when the holding chamber of first part is slided into, more steadily.

In order to solve the above technical problem, a second technical solution adopted by the present application is to provide a sample analyzer for detecting a sample, the sample analyzer including a flip assembly as in the first technical solution.

The beneficial effect of this application is: be different from prior art, this application can provide a flip subassembly, at the in-process that is overturned along with the flip door, through supporting slide and supporting slide bar, the cooperation between hinge and the attenuator operation, hinge rotation hinge flip door and host computer provide articulated power for the flip door upset, and carry out relative slip through supporting slide bar and supporting slide, make the supporting slide bar support the flip door more firmly, and the attenuator provides the damping for the flip door in the upset process, realize fixing in the position that is arbitrary angle in 0-180 and corresponds between flip door and the host computer, thereby provide better user experience.

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 perspective view of a flip member in an embodiment of the present application;

fig. 2 is a schematic front structural view of the flip member of fig. 1;

fig. 3 is a side view, partially schematic, component structure of the flip component of fig. 1;

fig. 4 is a side view of the flip assembly of fig. 1.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In the field of a plurality of medical instruments, a flip part is usually needed, however, the flip door has two defects at present, firstly, the flip door cannot be turned 180 degrees and stopped at any angle due to the fact that the flip angle cannot be compatible with the flip door, so that the flip door cannot meet the requirements of people with different heights when being opened, and a user with a high height is easy to bump; and the flip door is easy to rock, and the structural mode is unstable, so the application provides a flip subassembly.

Referring to fig. 1 to 4, fig. 1 is a schematic perspective view of a flip cover assembly in an embodiment of the present application; fig. 2 is a schematic front structural view of the flip member of fig. 1; fig. 3 is a side view, partially schematic, component structure of the flip component of fig. 1; fig. 4 is a side view of the flip assembly of fig. 1.

As shown in fig. 1, the flip member 100 may be attached to one side of the main body 200 for covering the main body 200, preventing dust from falling into the main body 200, keeping the main body 200 clean and tidy, and providing a stable and clean operating environment for various operations and working components in the main body 200.

A first technical solution adopted by the present application provides a flip member 100, where the flip member 100 includes: a flip door 10, a support member 20, a damper 30, and at least one hinge 40, wherein the support member 20 is disposed on the flip door 10 near a side of the main body 200 to make a support structure simpler, and the support member 20 includes at least a support slide 21 and a support slide 22. The hinge 40 rotatably hinges the flip door 10 and the main body 200 to provide a hinge power for the flip of the flip door 10, thereby rotating the flip door 10. The support member 20 is connected to the flip door 10 for supporting the flip door 10. The damper 30 provides damping to fix the position of the flip door 10 and the main body 200 at any angle of 0-180 degrees.

The inner side of the flip door 10 is provided with a supporting slide rail 21, and a supporting slide bar 22 is arranged in the supporting slide rail 21. The first end 221 of the support slide bar 22 is used to support the flip door 10 when the flip door 10 is rotated; specifically, when the supporting slide 21 and the supporting slide 22 are slidably engaged with each other, the supporting slide 22 can be made to more firmly support the flip door 10 to prevent the flip door 10 from shaking.

At least one hinge 40 is disposed between the flip door 10 and the main body 200, and is used for rotatably hinging the flip door 10 and the main body 200, so that the flip door 10 can be turned over. Hinge 40, also known as a hinge, is a mechanical device used to connect two solids and allow relative rotation between the two. The application may use gate hinges, spring hinges or other hinges, etc. The hinge 40 may be constructed of a movable component or may be constructed of a foldable material. Generally, the hinge is mainly installed on a door and a window, and the hinge 40 is more installed on a cabinet, and is mainly used for medical appliances in this application, and is mainly classified into a stainless steel hinge and an iron hinge according to the material.

The hinge 40 may also be a hydraulic hinge, also called a damping hinge 40, and is characterized in that a buffering function is provided when the flip door 10 is closed, so that the rotation axis of the flip door 10 is changed through the hinge 40, and noise generated by collision between the flip door 10 and the cabinet of the main machine 200 when the flip door 10 is closed can be reduced.

The damper 30 is connected to the second end 222 of the supporting slide rod 22, and may be disposed between the plurality of hinges 40, for providing damping for the flip door 10, such as providing uniform damping, so that the angle between the flip door 10 and the main body 200 is 0-180 °, and the position between the flip door 10 and the main body 200 corresponding to any angle of 0-180 ° is fixed.

In the process that the flip assembly 100 of the present embodiment is flipped along with the flip door 10, through the cooperation between the supporting slide 21 and the supporting slide 22, the hinge 40 and the damper 30, the hinge 40 pivotally connects the flip door 10 and the main frame 200 to provide a hinge power for flipping the flip door 10, and through the relative sliding between the supporting slide 22 and the supporting slide 21, the supporting slide 22 more stably supports the flip door 10, and the damper 30 provides a damping force for the flip door 10 during the flipping process, so that the flip door 10 and the main frame 200 are fixed at a position corresponding to any angle of 0-180 °, thereby providing better user experience.

As shown in fig. 1 and 2, the flip door 10 is provided with a first member 12 and a second member 11 which are slidably linked, the first member 12 is provided with a receiving chamber and an opening through which the second member 11 can slide into the receiving chamber.

Specifically, when the flip door 10 covers the main body 200, one side of the first part 12 close to the second part 11 may be provided with a one-way snap structure, by which the first part 12 and the second part 11 may be connected. When the flip door 10 is turned over by more than 90 °, the connection function of the one-way latch is lost, the second component 11 can slide relative to the first component 12, and the second component 11 can slide into the accommodating cavity of the first component 12 through the opening of the first component 12.

Therefore, by dividing the flip door 10 into the first part 12 and the second part 11 which are slidably linked, wherein the receiving cavity of the first part 12 can receive the first part 12, the volume of the flip door 10 is reduced, thereby providing the possibility of stabilizing the flip door 10.

In an embodiment, the first component 12 is provided with a guide rail 13, the guide rail 13 includes at least two mutually parallel slide rails, such as a first slide rail 131 and a second slide rail 132, the at least two slide rails are respectively disposed on the inner side walls of the first component 12 that are relatively far away from each other, and the second component 11 slides into the accommodating cavity through the guide rail 13. As shown in fig. 2, if the guide rail 13 includes a first slide rail 131 and a second slide rail 132, the first slide rail 131 and the second slide rail 132 may be respectively disposed on inner side walls of the first member 12 that are relatively far away from each other.

By arranging the mutually parallel slide rails on the inner side walls which are relatively far away from the first component 12, the second component 11 can slide into the accommodating cavity of the first component 12 along the relatively parallel slide rails in a relatively stable posture, and the probability of shaking of the flip door 10 can be reduced as much as possible when the second component 11 slides into the accommodating cavity of the first component 12.

The second member 11 is provided with a plurality of guide grooves 14, the guide grooves 14 are correspondingly arranged on the guide rails 13 one by one, and the second member 11 slides into the guide rails 13 through the guide grooves 14, so that the second member 11 slides into the accommodating cavity.

Therefore, by providing the guide grooves 14 corresponding to the guide rails 13 on the second component 11, the guide rails 13 and the guide grooves 14 can slide relatively in a mutually matching relationship, which is beneficial to improving the realizability of the scheme that the second component 11 slides into the accommodating cavity of the first component 12.

Wherein the guide rail 13 is configured as an i-shaped guide rail 13, such as a linear i-shaped guide rail 13, and the guide groove 14 is configured as a snap-in groove type guide groove 14 matched with the i-shaped guide rail 13.

Due to the adoption of a precise processing technology, the straightness of the slide rail formed between the guide rail 13 and the guide groove 14 is high, the error of a mounting screw hole in the slide rail is small, the installation is convenient, the linear I-shaped guide rail 13 has interchangeability, and the slide block or the slide rail, even the linear I-shaped guide rail 13, can be respectively replaced, so that the diameters of the guide rail 13 and the guide groove 14 can be matched again at high precision.

Because the linear I-shaped guide rail 13 has very small friction force during movement, the first component 12 and the second component 11 can slide relatively only with small power, the abrasion loss caused by sliding is obviously greatly reduced, and the heat generated by friction is very small, so that the linear I-shaped guide rail is a moving component which is suitable for high-speed and frequent starting and reversing, such as the first component 12 and the second component 11 on the flap door 10 which often needs to be turned over.

The motion of the linear I-shaped guide rail 13 can be realized by the rolling of the steel ball, the friction coefficient is reduced to 1/50 of the sliding guide rail 13, the difference of dynamic and static friction resistance curves is also reduced, the motion is stable, the impact and vibration are reduced, and the blocking fault is not easy to generate, so the um grading positioning precision can be reached, and the response speed and the sensitivity of a sliding part can be improved.

The linear I-shaped guide rail 13 has good anti-biotic performance, the two ends of the sliding block are provided with the sealing end covers, the bottom of the sliding block can be selected as a sealing bottom sheet, and meanwhile, the fixing screw holes of the sliding rail are provided with anti-biotic screw hole covers to prevent dust accumulation, so that the service life and the performance of a sliding part are ensured.

The linear I-shaped guide rail 13 is provided with an oil filling hole on the sliding block, grease can be directly filled by an oil gun, and the linear I-shaped guide rail can also be connected with an oil supply pipe to lubricate an automatic oil supply machine, so that the abrasion of the linear I-shaped guide rail is reduced to a smaller extent, and the sliding part can keep the precision for a long time.

Therefore, through the matching between the I-shaped guide rail 13 and the slot type guide groove 14, the installation is convenient, the exchange is easy, the friction force generated by relative sliding can be greatly reduced, the lubricating structure between the I-shaped guide rail 13 and the slot type guide groove 14 is simple, the abrasion between the I-shaped guide rail 13 and the slot type guide groove 14 is reduced, the first component 12 and the second component 11 can stably move, the impact and the vibration are reduced, the sliding sensitivity is kept for a long time, and the dust prevention and the sealing performance are better.

Further, the end of the second part 11 away from the first part 12 is provided with a covering member 15, and the covering member 15 and the flip door 10 are used for covering the main body 200.

By arranging the covering member 15 on the second component 11, the weight of the second component 11 can be increased, on one hand, the flip door 10 can better cover the opening of the main machine 200, and on the other hand, the second component 11 can be more stably slid into the accommodating cavity of the first component 12.

Further, as shown in fig. 3, the support slide 21 is provided on the first member 12 on the side close to the host opening 201. By providing the support slide 21 on the side close to the access door of the main body 200, it is possible to keep the overall configuration of the flap door 10 and the housing portion of the main body 200 more beautiful.

Furthermore, a plurality of hinges 40, such as a first hinge 41 and a second hinge 42 shown in fig. 2, may be further disposed at intervals on the intersecting contact line between the flip door 10 and the main body 200, so that the plurality of hinges 40 hinge a plurality of positions on one side of the flip door 10 when providing power, thereby enabling the flip door 10 to flip more stably, and not to easily sway left and right, thereby providing better user experience.

For example, the flip assembly 100 may include two hinges 40, and the damper 30 is disposed between the two hinges 40 and between the flip door 10 and the main body 200. By arranging the two hinges 40, the rotation point of the flip door 10 can be changed, and the flip of the flip door 10 is realized; the combination of the damping shaft provides certain damping for the whole flip door 10, so that the flip door 10 can be stopped at any angle; the flip supporting slide 21 is added to ensure that the whole flip door 10 does not shake during the flip process, and the flip process is stable.

Therefore, by providing two hinges 40, the hinged. And the damper 30 is disposed between the two hinges 40, it is possible to make the driving force provided by the two hinges 40 more smooth, reduce noise during the turnover of the turnover door 10, and enable the first part 12 of the turnover door 10 to be arbitrarily fixed between 0-180 ° to determine the positional relationship between the turnover door 10 and the main body 200.

When the included angle α between the flip door 10 and the main unit 200 is greater than 90 degrees, the accommodating cavity of the first component 12 is used for accommodating the second component 11 sliding into the first component 12. The second component 11 is slid into the accommodating cavity of the first component 12 through the angle relationship between the flip door 10 and the main unit 200 under a specific scene, which is beneficial to the realizability of the scheme.

Therefore, the flip cover assembly 100 adopted by the present application can achieve the following two beneficial effects:

1: the large-angle turnover of the flap door 10 is realized, the flap door is suitable for people with different heights, and the risk of head collision is avoided;

2: the flip door 10 can be stopped at any position corresponding to 0-180 degrees, and when an operator uses the flip door 10, the flip door 10 cannot naturally fall down and collide the operator due to the action of gravity or the flip door 10 can be closed to generate harsh sound to influence the user experience.

In order to solve the above technical problem, a second technical solution adopted by the present application is a sample analyzer, which includes at least the flip member 100 as in the first technical solution.

Specifically, for example, the sample analyzer is an immunoassay analyzer, which can perform immunoassay analysis on a human body by detecting serum of a patient, and the immunoassay analyzer includes the flip assembly 100 according to the first technical solution, when a serum sample of a patient needs to be put into the sample analyzer, so that the hinge 40 rotatably hinges the flip door 10 and the main frame 200 by the cooperation operation between the support slide rail 21 and the support slide rail 22, the hinge 40 and the damper 30 during the flip of the flip door 10 in the flip assembly 100, so as to provide hinge power for the flip door 10 to flip, and the support slide rail 22 slides relative to the support slide rail 21 so as to more stably support the flip door 10 by the support slide rail 22, and the damper 30 provides damping for the flip door 10 during the flip process, so as to fix a position between the flip door 10 and the main frame 200 corresponding to an arbitrary angle of 0 to 180 degrees, thereby placing the patient serum sample into the sample analyzer and further providing a better user experience.

The above embodiments are merely examples, and not intended to limit the scope of the present application, and all modifications, equivalents, and flow charts using the contents of the specification and drawings of the present application, or those directly or indirectly applied to other related arts, are included in the scope of the present application.

Claims (10)

1. A flip assembly, comprising:

the inner side of the flip door is provided with a supporting slide way, a supporting slide rod is arranged in the supporting slide way, and when the flip door rotates, the first end of the supporting slide rod is used for supporting the flip door;

the hinge is arranged between the flip door and the host and is used for rotatably hinging the flip door and the host so as to enable the flip door to rotate along the hinge;

the damper is connected with the second end of the supporting sliding rod and used for providing damping for the flip door so that the included angle between the flip door and the host is 0-180 degrees.

2. The flip assembly of claim 1,

the flip door is provided with a first part and a second part which are connected in a sliding mode, the first part is provided with an accommodating cavity and an opening, and the second part slides into the accommodating cavity through the opening.

3. The flip assembly of claim 2,

the first part is provided with a guide rail, the guide rail comprises at least two mutually parallel slide rails, the at least two slide rails are respectively arranged on the inner side wall, far away from the first part relatively, of the first part, and the second part slides into the accommodating cavity through the guide rail.

4. The flip assembly of claim 3,

the second component is provided with a plurality of guide grooves which are respectively arranged in the guide rails in a one-to-one corresponding matching manner, and the second component slides into the guide rails through the guide grooves so as to slide the second component into the accommodating cavity.

5. The flip assembly of claim 4,

the guide rail sets up to the I shape guide rail, the guide slot sets up to the draw-in groove formula guide slot with I shape guide rail complex.

6. The flip assembly of claim 5,

the supporting slide is arranged on the first part close to one side of the opening of the host.

7. The flip assembly of claim 1,

the flip assembly comprises two hinges, and the damper is arranged between the two hinges and positioned between the flip door and the host.

8. The flip assembly of claim 2,

when the included angle between the flip door and the host is larger than 90 degrees, the accommodating cavity of the first component is used for accommodating the second component which slides into the first component.

9. The flip assembly of claim 2,

one end of the second component, which is far away from the first component, is provided with a covering piece, and the covering piece and the flip door are used for covering the host.

10. A sample analyzer for testing a sample, comprising a flip assembly according to any one of claims 1-9.

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