CN220671083U - Dyeing container, dyeing device and push-piece dyeing machine - Google Patents

Abstract

The application provides a dyeing container, dyeing device and pushing piece dyeing machine, the dyeing container includes the container body and hangs the body, the container body is formed with the dyeing space, the dyeing space is used for holding the dyeing reagent, hang the body and be connected with the container body and be formed with the smear insertion opening with the dyeing space intercommunication, hang one side that the body is close to the container body and be equipped with first location portion that hangs, one side that hangs the body is kept away from to the container body is equipped with first location portion that ends, when so that the dyeing container installs on the dyeing support, hang location portion through the second and fix a position the dyeing container with first location portion that hangs, make the dyeing container be the state of hanging and can bear on the dyeing support, second ends location portion and first location portion cooperation setting that ends, it fixes a position the dyeing container through second location portion that ends location portion and first location portion, can avoid being in the dyeing container swing of hanging the state, do not need other fixed knot structures such as the bolt, make things convenient for the installation and the dismantlement of dyeing container.

Description

Dyeing container, dyeing device and push-piece dyeing machine

Technical Field

The application relates to the technical field of medical equipment, in particular to a dyeing container, a dyeing device and a push-piece dyeing machine.

Background

In disease diagnosis and treatment, a smear is formed by coating a sample on a glass slide through a smear pushing operation, then the smear is dyed to finish film making, finally a detection result is obtained through detecting the film-made sample, a reference basis is provided for a doctor to diagnose the disease, when the smear is dyed, a dyeing pool is generally placed on a bracket, then a dyeing reagent is injected into the dyeing pool, finally the smear is placed in the dyeing pool for dyeing, and the dyeing pool needs to be replaced or maintained after long-term use.

In the prior art, in order to facilitate replacement or maintenance of the dyeing tank, the dyeing tank is generally fixed with the support in a bolt connection mode, and the dyeing tank can be detached from the support only by detaching bolts, so that the process is complicated and not convenient enough.

Disclosure of Invention

The application mainly provides a dyeing container, dyeing device and pushing piece dyeing machine, can make things convenient for the installation and the dismantlement of dyeing container.

In order to solve the technical problems, one technical scheme adopted by the application is as follows: the utility model provides a dyeing container, dyeing container includes the container body and hangs the body, the container body is formed with the dyeing space, the dyeing space is used for holding dyeing reagent, hang the body with the container body is connected and be formed with the smear insertion opening of dyeing space intercommunication, hang the body be close to one side of container body is equipped with first location portion that hangs, the container body is kept away from one side of hanging the body is equipped with first location portion that ends.

In a specific embodiment, the first anti-swing positioning portion is a positioning groove, and the container body includes an inclined positioning surface disposed near the positioning groove and facing one side of the notch direction of the positioning groove.

In a specific embodiment, the suspension body is further formed with a reagent port communicating with the staining space, through which the staining reagent is injected into the staining space and/or through which the staining reagent is withdrawn from the staining space.

In a specific embodiment, the reagent port includes a liquid injection port and a liquid extraction port, the dyeing reagent is injected into the dyeing space through the liquid injection port, and the dyeing reagent is extracted from the dyeing space through the liquid extraction port.

In one embodiment, the staining reagent is drawn out from the staining space through the reagent port, and the container body includes an inclined drainage surface provided on a side facing the opening direction of the reagent port.

In a specific embodiment, a partition is disposed on a side of the container body, which is close to the staining space, so as to partition the staining space into a reagent channel and a staining channel, which are communicated with each other, the reagent port is communicated with the reagent channel, and the smear insertion opening is communicated with the staining channel.

In a specific embodiment, the suspension body is further formed with an overflow port communicating with the smear insertion opening, the overflow port being disposed downward.

In a specific embodiment, the number of the first hanging positioning parts is plural, and the plural first hanging positioning parts are disposed around the container body.

In order to solve the technical problems, another technical scheme adopted by the application is as follows: the dyeing device comprises a dyeing support and a dyeing container, wherein the dyeing support is provided with a second hanging positioning part and a second swinging-stopping positioning part, the second hanging positioning part is matched with the first hanging positioning part, and the second swinging-stopping positioning part is matched with the first swinging-stopping positioning part.

In order to solve the technical problem, another technical scheme adopted by the application is as follows: a slide staining machine is provided, which comprises a slide pushing device and a staining device, wherein the slide pushing device is used for coating a sample on a slide to form a smear.

The beneficial effects of this application are: in the circumstances of prior art, the dyeing container that this application embodiment provided includes the container body and hangs the body, the container body is formed with the dyeing space, the dyeing space is used for holding the dyeing reagent, hang the body with container body coupling and be formed with the smear insertion opening of dyeing space intercommunication, hang the body and be close to one side of container body and be equipped with first location portion that hangs, the container body is kept away from one side of hanging the body is equipped with first location portion that hangs to make the dyeing container install on the dyeing support, on the one hand hang the location portion through the second and hang the location portion with first location portion and fix a position the dyeing container, on the other hand makes the dyeing container be the state of hanging and can bear on the dyeing support, and second location portion and first location portion cooperation that only stop to put down are located through second location portion and first location portion, on the other hand can avoid being in the dyeing container swing of state of hanging, thereby make the dyeing container can stable install on the dyeing support, and need not be like other fixed knot structures, make things convenient for the installation and dismantlement of dyeing container.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic perspective view of an embodiment of a dyeing apparatus provided herein;

FIG. 2 is a schematic perspective view of the staining module of FIG. 1;

FIG. 3 is a schematic perspective view of the dyeing vessel of FIG. 2;

FIG. 4 is a schematic cross-sectional view of the staining container of FIG. 3 in the F-F direction;

FIG. 5 is a schematic perspective view of the reagent module of FIG. 1;

FIG. 6 is a schematic diagram of the motion trace of the liquid adding mechanism and the liquid pumping mechanism in FIG. 5;

FIG. 7 is an enlarged schematic view of portion M of FIG. 5;

FIG. 8 is a schematic view of the movement process of the liquid adding mechanism in FIG. 7 from the liquid adding position to the cleaning position;

FIG. 9 is a schematic view of the liquid feeding mechanism of FIG. 8 moved to a cleaning position;

FIG. 10 is a schematic view showing the movement of the liquid adding mechanism from the liquid adding position to the cleaning position in another embodiment in FIG. 7;

FIG. 11 is an exploded view of the liquid feeding mechanism of FIG. 7;

FIG. 12 is a schematic perspective view of the cleaning unit of FIG. 5;

fig. 13 is a schematic perspective view of a push-piece dyeing machine embodiment provided herein.

Detailed Description

The present application is described in further detail below with reference to the drawings and the embodiments. It is specifically noted that the following embodiments are merely for illustrating the present application, but do not limit the scope of the present application. Likewise, the following embodiments are only some, but not all, of the embodiments of the present application, and all other embodiments obtained by one of ordinary skill in the art without inventive effort are within the scope of the present application.

The terms "first," "second," "third," and the like in this application are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", and "a third" may explicitly or implicitly include at least one such feature. In the description of the present application, the meaning of "plurality" means at least two, such as two, three, etc., unless explicitly specified otherwise. All directional indications (such as up, down, left, right, front, back … …) in this embodiment are merely used to explain the relative positional relationship, movement, etc. between the components in a particular gesture (as shown in the drawings), and if the particular gesture changes, the directional indication changes accordingly. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion. A process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those listed but may optionally include other steps or elements not listed or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the present application. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those skilled in the art will explicitly and implicitly understand that the embodiments described herein may be combined with other embodiments.

Referring to fig. 1, fig. 1 is a schematic perspective view of an embodiment of a dyeing apparatus 10 provided in the present application, where the dyeing apparatus 10 includes a dyeing module 11 and a reagent module 12.

Referring to fig. 2, fig. 2 is a schematic perspective view of the staining module 11 in fig. 1, where the staining module 11 is configured to receive a smear 110, and it is understood that the smear 110 is a slide coated with a sample.

The staining module 11 includes a staining container 111 and a staining rack 112, the staining container 111 is used for receiving the smear 110 and staining the smear 110, and the staining rack 112 is used for carrying the staining container 111 and detachably connected with the staining container 111, so that when the staining container 111 needs to be replaced or maintained, the staining container 111 can be detached from the staining rack 112, and convenience in replacement or maintenance is improved.

Referring to fig. 3 and 4 together, fig. 3 is a schematic perspective view of the dyeing container 111 in fig. 2, fig. 4 is a schematic cross-sectional view of the dyeing container 111 in the F-F direction in fig. 3, the dyeing container 111 is formed with a first hanging location portion 1111 and a first anti-swing location portion 1112, the dyeing support 112 is provided with a second hanging location portion (not shown) and a second anti-swing location portion (not shown) which are arranged in cooperation with the first hanging location portion 1111, so that when the dyeing container 111 is mounted on the dyeing support 112, the dyeing container 111 can be positioned on the dyeing support 112 through the second hanging location portion and the first hanging location portion 1111, on the other hand, the dyeing container 111 can be carried on the dyeing support 112 in a hanging state, the second anti-swing location portion is arranged in cooperation with the first anti-swing location portion 1112, on the other hand, the dyeing container 111 in a hanging state can be prevented from swinging, thereby enabling the dyeing container 111 to be stably mounted on the dyeing support 112, and the dyeing container 111 does not need to be dismounted by fixing bolts or the like.

Specifically, the staining container 111 includes a container body 11a and a hanging body 11b, the container body 11a is formed with a staining space 101, the staining space 101 is used for accommodating a staining reagent, the hanging body 11b is connected with the container body 11a and is formed with a smear insertion opening 102 communicated with the staining space 101, a first hanging positioning portion 1111 is arranged on one side of the hanging body 11b close to the container body 11a, a first anti-swing positioning portion 1112 is arranged on one side of the container body 11a far away from the hanging body 11b, and when the staining container 111 is hung on a staining rack 112, the smear 110 is inserted into the staining space 101 through the smear insertion opening 102 for staining.

Optionally, the number of the first hanging positioning portions 1111 is multiple, the multiple first hanging positioning portions 1111 are disposed around the container body 11a, so as to further improve the stability of the dyeing container 111 installed on the dyeing support 112, for example, in this embodiment, the number of the first hanging positioning portions 1111 is two, and the two first hanging positioning portions 1111 are disposed on two opposite sides of the container body 11a respectively, so that the two first hanging positioning portions 1111 and the first anti-swing positioning portion 1112 cooperate together to implement triangular positioning on the dyeing container 111.

In the present embodiment, each of the dyeing racks 112 may carry a plurality of dyeing containers 111, and the plurality of dyeing containers 111 are provided independently of each other and mounted on the dyeing rack 111 in the above-described suspended state.

In a specific application scenario, the first suspension positioning portion 1111 and the first anti-swing positioning portion 1112 may be structures such as a positioning hole and a positioning groove, and then the second suspension positioning portion and the second anti-swing positioning portion are positioning protrusions matching with the structures such as the positioning hole and the positioning groove, and of course, the first suspension positioning portion 1111 and the first anti-swing positioning portion 1112 may be positioning protrusions, and then the second suspension positioning portion and the second anti-swing positioning portion are structures such as a positioning hole and a positioning groove matching with the positioning protrusions.

In the present embodiment, the first anti-swing positioning portion 1112 is a positioning groove, and the container body 11a includes an inclined positioning surface 1113 disposed close to the positioning groove and facing the notch direction of the positioning groove, that is, facing the side of E1 shown in fig. 3.

It can be appreciated that when the first anti-swing positioning portion 1112 is a positioning groove, the second anti-swing positioning portion is a positioning protrusion matched with the positioning groove, so that by setting the inclined positioning surface 1113, when the dyeing container 111 is placed on the dyeing support 112 upwards at E1 shown in fig. 3, the inclined positioning surface 1113 can guide the positioning protrusion of the second anti-swing positioning portion to move into the positioning groove of the first anti-swing positioning portion 1112, so as to improve the accuracy of the matching positioning of the first anti-swing positioning portion 1112 and the second anti-swing positioning portion.

In another specific application scenario, the second anti-swing positioning portion is an adjustable anti-swing positioning portion, the adjustable anti-swing positioning portion is used for adjusting a bearing state of the dyeing container 111 on the dyeing support 112, for example, because the dyeing container 111 is thinner and has certain toughness, errors are likely to occur when the dyeing container 111 is installed, so that the dyeing container 111 is inclined, in this case, the adjustable anti-swing positioning portion is used for adjusting the bearing state of the dyeing container 111 on the dyeing support 112, so that the dyeing container 111 is in an alignment state, in an actual application, a specific adjusting mode can be that a stud is arranged on the dyeing support 112, a nut is installed on the stud, the nut is propped against the dyeing container 111, the bearing state of the dyeing container 111 is adjusted by adjusting the screwing position of the stud, a limit hole or a limit groove is also arranged at the bottom of the dyeing container 111, the stud is inserted into the limit hole or the limit groove, and the bottom position of the dyeing container 111 is limited by the nut, so that the contact area of the nut and the dyeing container 111 is increased, and the reliability of the limit is increased.

Further, the hanging body 11b is also formed with a reagent port 103 communicating with the staining space 101, and the staining reagent is injected into the staining space 101 through the reagent port 103 and/or the staining reagent is withdrawn from the staining space 101 through the reagent port 103, by such arrangement that the smear insertion opening 102 and the reagent port 103 are independent of each other, the injection operation of the staining reagent and/or the withdrawal operation of the staining reagent and the insertion operation of the smear 110 can be performed independent of each other, increasing the selectivity of the operation.

In the present embodiment, the reagent port 103 includes a liquid injection port 1031 and a liquid extraction port 1032, and the dyeing reagent is injected into the dyeing space 101 through the liquid injection port 1031 and the dyeing reagent is extracted from the dyeing space 101 through the liquid extraction port 1032, that is, in the present embodiment, both the injection operation of the dyeing reagent and the extraction operation of the dyeing reagent are completed through the reagent port 103.

Referring to fig. 5 and 6 together, fig. 5 is a schematic perspective view of the reagent module 12 in fig. 1, fig. 6 is a schematic view of a movement track of the liquid adding mechanism 121b and the liquid extracting mechanism 121d in fig. 5, the reagent module 12 includes a liquid adding module 12a moving along a first path L1 and a liquid extracting module 12b moving along a second path L2, the second path L2 is different from the first path L1, a liquid adding level P1 is disposed below the first path L1, the liquid adding module 12a is used for injecting a dyeing reagent into the dyeing module 11 at the liquid adding level P1, a liquid extracting level P2 is disposed below the second path L2, and the liquid extracting module 12b is used for extracting the dyeing reagent after dyeing in the dyeing module 11 at the liquid extracting level P2.

Specifically, the filling module 12a includes a filling unit 121, the filling unit 121 moves along a first path L1 and is used for injecting a dyeing reagent into the dyeing module 11 at a filling level P1, wherein the filling unit 121 includes a mechanism 121a and a filling mechanism 121b, the mechanism 121a is connected with the filling mechanism 121b to drive the movement of the filling mechanism 121b, the filling mechanism 121b is used for injecting the dyeing reagent into the dyeing module 11 at the filling level P1, the drawing module 12b includes a power mechanism 121c and a drawing mechanism 121d, the power mechanism 121c is connected with the drawing mechanism 121d to drive the drawing mechanism 121d to move, and the drawing mechanism 121d is used for drawing the dyeing reagent after dyeing in the dyeing module 11 at a drawing level P2.

It should be understood that when the number of the dyeing containers 111 is plural, the liquid filling positions P1 are plural, the liquid filling mechanism 121b may be moved to each liquid filling position P1 to complete the liquid filling operation, and the liquid extracting positions P2 are plural, and the liquid extracting mechanism 121d may be moved to each liquid extracting position P2 to complete the liquid extracting operation.

Further, the dyeing module 11 includes a dyeing region R1, a liquid adding region R2 and a liquid extracting region R3, the dyeing region R1 is used for receiving a smear, the liquid adding module 12a is used for injecting a dyeing reagent into the dyeing region R1 through the liquid adding region R2, the liquid extracting module 12b is used for extracting the dyeing reagent after the dyeing in the dyeing region R1 is completed through the liquid extracting region R3, in this embodiment, the smear 110 is inserted into the dyeing space 101 through the smear insertion opening 102, the liquid adding mechanism 121b injects the dyeing reagent into the dyeing space 101 through the liquid injecting sub-opening 1031, and the liquid extracting mechanism 121d extracts the dyeing reagent after the dyeing is completed in the dyeing space 101 through the liquid extracting sub-opening 1032.

Further, the power mechanism 121c includes a first power component 1211 and a second power component 1212, the second power component 1212 is respectively connected to the first power component 1211 and the liquid suction mechanism 121d, the first power component 1211 is used for driving the liquid suction mechanism 121d to move in the first direction a, a liquid suction level P2 is provided along a motion track of the liquid suction mechanism 121d in the first direction a, the second power component 1212 is used for driving the liquid suction mechanism 121d to move away from or close to the dyeing module 11 in the second direction B, that is, during practical application, the first power component 1211 drives the liquid suction mechanism 121d to move to the liquid suction level P2 in the first direction a, then the second power component 1212 drives the liquid suction mechanism 121d to approach and insert into the dyeing module 11 in the second direction B, that is, approaches the dyeing container 111 and inserts into the dyeing space 101, and after the liquid suction mechanism 121d is completely sucked, the second power component 1212 drives the liquid suction mechanism 121d to move away from and move out of the dyeing module 11 in the second direction B.

In this embodiment, the driving mechanism 121a is used for driving the liquid feeding mechanism 121b to move in the first direction a, that is, the liquid feeding mechanism 121b and the liquid extracting mechanism 121d are arranged side by side along the moving path in the first direction a, and in this arrangement, in the process that the liquid feeding mechanism 121b injects the dyeing reagent into the dyeing space 101 through the liquid injection port 1031 and the liquid extracting mechanism 121d extracts the dyeing reagent in the dyeing space 101 through the liquid extracting port 1032, the movement process of the liquid feeding mechanism 121b and the liquid extracting mechanism 121d will not interfere, for example: when the liquid pumping mechanism 121d pumps liquid from one of the dyeing containers 111, the liquid adding mechanism 121b can move to the position above any one of the dyeing containers 111 to fill the dyeing container 111, and no interference occurs between the liquid pumping mechanism 121d and the path of the liquid adding mechanism 121 b. Since the dyeing container 111 is fixedly arranged, the idle dyeing container 111 may exist at any position, and thus, the liquid pumping mechanism 121d and the liquid adding mechanism 121b are independently arranged, so that waiting time of the liquid pumping mechanism and the liquid adding mechanism can be avoided, and liquid pumping and liquid adding efficiency can be accelerated. .

Referring further to fig. 4, a partition 11c is disposed on a side of the container body 11a near the dyeing space 101 to partition the dyeing space 101 to form a reagent channel 1011 and a dyeing channel 1012 which are communicated with each other, the reagent port 103 is communicated with the reagent channel 1011, and the smear insertion opening 102 is communicated with the dyeing channel 1012, in this embodiment, that is, the smear 110 is inserted into the dyeing channel 1012 through the smear insertion opening 102, the filling mechanism 121b sequentially injects the dyeing reagent into the reagent channel 1011 and the dyeing channel 1012 through the filling port 1031, and the drawing mechanism 121d sequentially draws the dyeing reagent after the dyeing is completed in the dyeing channel 1012 through the drawing port 1032 and the reagent channel 1011, so that the dyeing position of the smear 110 is limited, and the contact between the filling mechanism 121b and the drawing mechanism 121d and the smear 110 is avoided, resulting in the damage of the filling mechanism 121b and the drawing mechanism 121d and the smear 110.

The container body 11a includes an inclined flow guide surface 1114 provided on the side facing the opening direction E2 of the reagent port 103.

Specifically, when the dyeing reagent is drawn from the dyeing space 101 through the reagent port 103, for example, as described above, the drawing mechanism 121d sequentially draws the dyeing reagent after the dyeing is completed in the dyeing channel 1012 through the drawing port 1032 and the reagent channel 1011, as shown in fig. 4, the drawing mechanism 121d is inserted into the reagent channel 1011 through the drawing port 1032, and by setting the inclined drainage surface 1114, during the drawing process of the dyeing reagent in the dyeing channel 1012 by the drawing mechanism 121d, the dyeing reagent can be continuously drained to the reagent channel 1011 by the inclined drainage surface 1114 in the direction E3 shown in fig. 4 until the drawing is completed, so that the drawing effect can be improved, and the situation that the dyeing reagent cannot be completely drawn and remains in the dyeing channel 1012 can be avoided.

Further, the hanging body 11b is further formed with an overflow port 104 communicating with the smear insertion opening 102 so that, during the filling process, if the amount of the staining reagent in the staining space 101 is excessive, the excessive staining reagent can flow out from the overflow port 104.

Wherein, the overflow port 104 is disposed downward, which may be vertically downward or inclined downward, and in practical application, the overflow port 104 may be connected with a liquid drain pipe, so that the dyeing reagent flowing out from the overflow port 104 is intensively discharged, or the dyeing reagent flows into a downward receiving mechanism from the overflow port 104 under the action of self gravity, such as an overflow groove disposed on the dyeing support 112, and the overflow groove is used for receiving the dyeing reagent overflowed from the dyeing container 111, without additional installation of a pipe, thereby avoiding the situation that the dyeing reagent in the dyeing space 101 flows out and causes pollution due to excessive dyeing reagent.

Alternatively, in the present embodiment, the overflow port 104 is disposed between the first hanging and positioning portion 1111 and the dyeing space 101, and this arrangement does not affect the installation of the first hanging and positioning portion 1111 and the second hanging and positioning portion, that is, the installation of the dyeing container 111 and the dyeing bracket 112 in practical application.

Further, the hanging body 11b in the present embodiment is also formed with an overflow chamber 104a communicating with the smear insertion opening 102 and the overflow port 104, respectively, and when the staining reagent in the staining space 101 is excessive, the staining reagent overflows into the overflow chamber 104a through the smear insertion opening 102 and then flows out from the overflow port 104.

Referring further to fig. 1 and 6, the staining apparatus 10 further includes a smear transfer module 13 moving along a third path L3, and a staining site P3 is disposed below the third path, and the smear transfer module 13 is configured to clamp the smear 110 and place the smear 110 on the stained area R1 at the staining site P3.

Specifically, the smear transfer module 13 includes a transfer driving unit 131 and a clamping unit 132, where the transfer driving unit 131 is connected to the clamping unit 132 to drive the clamping unit 132 to move along the third path L3, and the clamping unit 132 is used to clamp the smear 110 and place the smear 110 in the dye region R1 at the dye position P3, and in this embodiment, the clamping unit 132 inserts the smear 110 into the dye space 101 from the smear insertion opening 102.

The first path L1, the second path L2, and the third path L3 are sequentially arranged side by side, and in this arrangement, the clamping unit 132, the liquid pumping mechanism 121d, and the liquid adding mechanism 121b do not interfere with each other during the movement process, so that the liquid adding efficiency, the liquid pumping efficiency, and the smear transferring efficiency can be improved.

It will be appreciated that in the present embodiment, when the dyeing rack 112 is used to carry a plurality of dyeing containers 111, the plurality of dyeing containers 111 are arranged in a line along the third path L1 in the same direction.

Referring to fig. 5, 6 and 7, fig. 7 is an enlarged schematic view of the portion M in fig. 5, the filling unit 121 in this embodiment further includes a connection mechanism 121e, and the connection mechanism 121e is connected to the driving mechanism 121a and the filling mechanism 121b, respectively, such that the driving mechanism 121a drives the filling mechanism 121a to move in the first direction a through the connection mechanism 121e, and a cleaning position P4 is further provided along a movement track of the filling mechanism 121a in the first direction a.

Further, the charging module 12a in the present embodiment further includes a cleaning unit 122 and a guiding unit 123, the cleaning unit 122 is configured to clean the charging unit 121 at a cleaning position P4, in this embodiment, i.e. after the charging mechanism 121b completes the charging operation at the charging position P1, the driving mechanism 121a drives the charging mechanism 121b to move from the charging position P1 to the cleaning position P4, and then the cleaning unit 122 cleans the charging mechanism 121b at the cleaning position P4.

Wherein, the guiding unit 123 is disposed on the first path L1, the liquid adding unit 121 is slidably connected with the connecting mechanism 121e, so that the liquid adding unit 121 approaches and moves into the cleaning unit 122 under the guiding action of the guiding unit 123 in the moving process of the liquid adding unit 121 from the liquid adding position P1 to the cleaning position P4, compared with the prior art, a driving mechanism is omitted, the cost is saved, and the liquid adding unit 121 moves near the cleaning unit 122 while moving toward the cleaning position P4, i.e. the liquid adding unit 121 moves into the cleaning unit 122 while moving to the cleaning position, thereby saving time and improving efficiency.

Referring to fig. 7, fig. 8 and fig. 9 together, fig. 8 is a schematic diagram illustrating a movement process of the liquid adding mechanism 121b in fig. 7 from the liquid adding position P1 to the cleaning position P4, and fig. 9 is a schematic diagram illustrating a state of the liquid adding mechanism 121b in fig. 8 moving to the cleaning position P4, wherein the guiding mechanism 123 includes a first guiding surface 1231, and the first guiding surface 1231 is disposed obliquely with respect to the first direction a, so that the liquid adding mechanism 121b approaches and moves into the cleaning unit 122 under the guiding action of the first guiding surface 1231.

Specifically, during the movement of the driving mechanism 121a from the filling position P1 to the cleaning position P4 by driving the filling mechanism 121b through the connection structure 121e, when the filling mechanism 121b abuts against the first guiding surface 1231 as shown in fig. 8, the driving mechanism 121a continues to drive the filling mechanism 121b to move toward the cleaning position P4, at this time, the filling mechanism 121b moves toward the cleaning unit 122 along the first guiding surface 1231 and upward at N1 as shown in fig. 8 under the abutting force with the first guiding surface 1231 until the filling mechanism 121b moves to the cleaning position P4 as shown in fig. 9, and at this time, the filling mechanism 121b moves into the cleaning unit 122, so that the cleaning unit 122 cleans the filling mechanism 121 b.

Referring to fig. 7, 8 and 10, fig. 10 is a schematic diagram illustrating a movement process of the liquid adding mechanism 121b from the liquid adding position P1 to the cleaning position P4 in fig. 7, in an embodiment shown in fig. 8, the liquid adding mechanism 121b includes a liquid adding component 1213 and a rolling member 1214, the liquid adding component 1213 is slidably connected to the connecting mechanism 121e, the rolling member 1214 is rotatably connected to the liquid adding component 1213, so that the rolling member 1214 moves along the first guiding surface 1231 and rotates relative to the liquid adding component 1213 during the process of moving the liquid adding component 1213 to the cleaning unit 122, and in this way, friction between the liquid adding mechanism 121b and the first guiding surface 1231 is rolling friction during the process of moving along the first guiding surface 1231, so as to reduce a movement obstruction between the two during the process of moving.

In this embodiment, the charging assembly 1213 includes a charging member 1213a and a mounting member 1213b, where the charging member 1213a is mounted on the mounting member 1213b, the mounting member 1213b is slidably connected to the connecting mechanism 121e, and the rolling member 1214 is rotatably connected to the mounting member 1213b, and in practical applications, one or more charging members 1213a may be mounted on the mounting member 1213b, which is not limited thereto.

In another embodiment shown in fig. 10, the filling mechanism 121b includes a second guiding surface 1215, where the second guiding surface 1215 is opposite to the first guiding surface 1231, so that the filling mechanism 121b approaches and moves into the cleaning unit 122 under the combined action of the first guiding surface 1231 and the second guiding surface 1215, and the principle is the same as that described in fig. 8 and 9, and is not repeated herein.

Referring to fig. 8, 9 and 11, fig. 11 is an exploded structure schematic diagram of the liquid adding mechanism 121b in fig. 7, wherein the liquid adding unit 121 further includes an elastic mechanism 121f, the elastic mechanism 121f is respectively connected with the connecting mechanism 121e and the liquid adding mechanism 121b, in this embodiment, the elastic mechanism 121f is respectively connected with the connecting mechanism 121e and the mounting member 1213b, so that the liquid adding mechanism 121b is far away from the cleaning unit 122 under the elastic force of the elastic mechanism 121f during the movement of the liquid adding mechanism 121b from the cleaning position P4 toward the liquid adding level P1.

Specifically, when the charging mechanism 121b approaches and moves into the cleaning unit 122 under the guiding action of the guiding unit 123, the charging mechanism 121b overcomes the elastic action of the elastic mechanism 121f, so as to generate elastic force, and when the cleaning unit 122 cleans the charging mechanism 121b, as shown in fig. 9, the driving mechanism 121a drives the charging mechanism 121b to move from the cleaning position P4 toward the charging level P1, at this time, the charging mechanism 121b moves toward the direction N2 as shown in fig. 9 under the elastic force of the elastic mechanism 121f until the charging mechanism 121b is in an abutting state with the first guiding surface 1231 as shown in fig. 8, and when moving toward the charging level P1, the charging mechanism 121b is separated from the first guiding surface 1231, so as to return to the charging state, and the elastic mechanism 121f may be a tension spring, a compression spring or a tension spring, which is exemplified in the present embodiment.

In the present embodiment, the filling mechanism 121b is provided with the mounting cavity 105, and the elastic mechanism 121f is disposed in the mounting cavity 105, so that the deformation of the elastic mechanism 121f can be guided.

Further, the guiding mechanism 123 further includes a stop surface 1232, the stop surface 1232 is disposed towards the direction of movement of the charging mechanism 121b near the cleaning unit 122, that is, N1 is disposed towards as shown in fig. 9, and by the arrangement of the stop surface 1232, when the charging mechanism 121b moves to the cleaning position P4, the charging mechanism 121b is separated from the first guiding surface 1231, so that, on one hand, the charging mechanism 121b is no longer moved towards the direction near the cleaning unit 122, and the situation that the charging mechanism 121b collides with the cleaning unit 122 to cause damage is avoided when the charging mechanism 121b continues to move, and on the other hand, the charging mechanism 121b is prevented from moving towards the direction far away from the cleaning unit 122 under the action of the elastic force of the elastic mechanism 121f, so that the charging mechanism 121b is removed from the cleaning unit 122 without cleaning.

Further, the filling mechanism 121b is slidably connected to the connecting mechanism 121e via a guiding mechanism 121g, and the guiding mechanism 121g is a hard lifting guiding mechanism, for example, the hard lifting guiding mechanism is a guide rail or a guide rod, so that the elastic mechanism 121f is prevented from tilting when being stressed.

Referring to fig. 12, fig. 12 is a schematic perspective view of the cleaning unit 122 in fig. 5, where the cleaning unit 122 is provided with a first cleaning chamber 106 and a second cleaning chamber 107, the first cleaning chamber 106 is used for cleaning a liquid feeding mechanism 121b, and the second cleaning chamber 107 is used for cleaning a coated sample slide, that is, the stained smear 110, so that the cleaning unit 122 in this embodiment can clean the liquid feeding mechanism 121b and the smear 110, and improve the cleaning function of the cleaning unit 122.

Alternatively, in the present embodiment, the number of the second washing chambers 107 is plural, so that the washing unit 122 of the present embodiment can wash a plurality of smears 110 at the same time.

Referring to fig. 13, fig. 13 is a schematic perspective view of an embodiment of a blade dyeing machine 20 provided in the present application, where the blade dyeing machine 20 in the present embodiment includes a blade pushing device 21 and the dyeing device 10 in the foregoing embodiment.

Wherein the slide pushing device 10 is used to apply a sample to a slide to form a smear 110.

In the circumstances of prior art, the dyeing container that this application embodiment provided includes the container body and hangs the body, the container body is formed with the dyeing space, the dyeing space is used for holding the dyeing reagent, hang the body with container body coupling and be formed with the smear insertion opening of dyeing space intercommunication, hang the body and be close to one side of container body and be equipped with first location portion that hangs, the container body is kept away from one side of hanging the body is equipped with first location portion that hangs to make the dyeing container install on the dyeing support, on the one hand hang the location portion through the second and hang the location portion with first location portion and fix a position the dyeing container, on the other hand makes the dyeing container be the state of hanging and can bear on the dyeing support, and second location portion and first location portion cooperation that only stop to put down are located through second location portion and first location portion, on the other hand can avoid being in the dyeing container swing of state of hanging, thereby make the dyeing container can stable install on the dyeing support, and need not be like other fixed knot structures, make things convenient for the installation and dismantlement of dyeing container.

The foregoing is only a part of the embodiments of the present application, and is not intended to limit the scope of the present application, and all equivalent devices or equivalent process transformations made by using the descriptions and the contents of the present application, or direct or indirect application to other related technical fields, are included in the scope of patent protection of the present application.

Claims (10)

1. The utility model provides a dyeing container, its characterized in that, dyeing container includes the container body and hangs the body, the container body is formed with the dyeing space, the dyeing space is used for holding dyeing reagent, hang the body with the container body is connected and be formed with the smear of dyeing space intercommunication inserts the opening, hang the body be close to one side of container body is equipped with first location portion that hangs, the container body is kept away from one side of hanging the body is equipped with first location portion that stops to swing.

2. The dyeing vessel according to claim 1, wherein the first swing-stopping positioning portion is a positioning groove, and the vessel body includes an inclined positioning surface provided near the positioning groove and facing a side of a notch direction of the positioning groove.

3. Dyeing vessel according to claim 1, characterized in that the suspension body is further formed with a reagent port communicating with the dyeing space, through which the dyeing reagent is injected into the dyeing space and/or through which the dyeing reagent is withdrawn from the dyeing space.

4. A staining container according to claim 3 wherein the reagent port comprises a liquid injection port through which the staining reagent is injected into the staining space and a liquid extraction port through which the staining reagent is extracted from the staining space.

5. A staining container according to claim 3 wherein the staining reagent is withdrawn from the staining space through the reagent port, and the container body comprises an inclined drainage surface provided to face the opening direction side of the reagent port.

6. A staining container according to claim 3 wherein a partition is provided on a side of the container body adjacent to the staining space to partition the staining space into a reagent channel and a staining channel communicating with each other, the reagent port communicates with the reagent channel, and the smear insertion opening communicates with the staining channel.

7. Dyeing vessel according to claim 1, characterized in that the suspension body is further formed with an overflow opening communicating with the smear insertion opening, the overflow opening being arranged downwards.

8. The dyeing vessel of claim 1, wherein the number of first hanging locations is a plurality, the plurality of first hanging locations being disposed around the vessel body.

9. The dyeing device is characterized by comprising a dyeing support and the dyeing container according to any one of claims 1-8, wherein the dyeing support is provided with a second hanging positioning part and a second anti-swing positioning part, the second hanging positioning part is matched with the first hanging positioning part, and the second anti-swing positioning part is matched with the first anti-swing positioning part.

10. A slide staining machine comprising a slide apparatus for applying a sample to a slide to form a smear, and a staining apparatus according to claim 9.