CN219348394U - Full-automatic tissue dehydrator - Google Patents

Abstract

The utility model relates to the technical field of dehydration equipment, in particular to a full-automatic tissue dehydrator, which comprises: the dehydration device comprises a dehydration tank, wherein a dehydration mechanism is arranged in the dehydration tank, the dehydration mechanism comprises an installation pipe which is rotatably connected to the inner wall of the bottom of the dehydration tank, and a plurality of air outlet pipes are fixedly inserted on the outer wall of the circumference of the installation pipe; the first groups of nozzles are fixedly arranged on the circumferential outer walls of the air outlet pipes respectively, and the air outlet directions of the first groups of nozzles are close to each other; the hot air machine is fixedly arranged on the circumferential outer wall of the dewatering tank, a first pipeline is fixedly inserted on the outer wall of the bottom of the hot air machine, and one end of the first pipeline is fixedly inserted on the outer wall of the bottom of the dewatering tank and communicated with the mounting pipe.

Description

Full-automatic tissue dehydrator

Technical Field

The utility model relates to the technical field of dehydration equipment, in particular to a full-automatic tissue dehydrator.

Background

The pathological diagnosis of diseases is carried out by fixing, dehydrating, transparent and wax-immersing treatment of the tissue specimens to be examined to prepare paraffin block slices, and the tissue dehydrator automatically immerses human or animal and plant tissues into various solvents according to the program to carry out the pathological analysis pretreatment such as dehydration, transparency, wax immersion and the like.

Through retrieval, the utility model of Chinese patent publication No. CN211904857U discloses a full-automatic tissue dehydrator, which comprises a machine body, the lower part of organism is arranged and is equipped with the solvent jar, the upper portion of organism is equipped with the insulation can, the inside cavity of insulation can, the middle part of insulation can inner chamber is from left to right equipped with wax jar, baffle one, baffle two and working cylinder in proper order, the top of wax jar and working cylinder runs through and extends to the top of insulation can upper surface, form heating cavity one between the outside of wax jar, the left side of baffle one and the inner wall of insulation can, form heating cavity two between the right side of baffle two, the outside of working cylinder and the inner wall of insulation can, heating cavity one and heating cavity two inside all are equipped with temperature sensor.

The device is characterized in that hot air is led into the first heating chamber and the second heating chamber and then is discharged out of the device through the exhaust pipe, however, the pathogenic bacteria with strong pollution are attached to the individual pathological sections, and after the pathological sections are dehydrated, the tissue dehydrator directly discharges the gas with the pathogenic bacteria into the atmosphere, so that the problem of air pollution can be caused.

Disclosure of Invention

The utility model aims to provide a full-automatic tissue dehydrator to solve the problems in the prior art.

The technical scheme of the utility model is as follows: a fully automatic tissue dehydrator comprising:

the dehydration device comprises a dehydration tank, wherein a dehydration mechanism is arranged in the dehydration tank, the dehydration mechanism comprises an installation pipe which is rotatably connected to the inner wall of the bottom of the dehydration tank, and a plurality of air outlet pipes are fixedly inserted on the outer wall of the circumference of the installation pipe;

the first groups of nozzles are fixedly arranged on the circumferential outer walls of the air outlet pipes respectively, and the air outlet directions of the first groups of nozzles are close to each other;

the hot air blower is fixedly arranged on the circumferential outer wall of the dewatering tank, a first pipeline is fixedly inserted on the outer wall of the bottom of the hot air blower, and one end of the first pipeline is fixedly inserted on the outer wall of the bottom of the dewatering tank and is communicated with the mounting pipe;

and the second pipeline is fixedly inserted on the outer wall of the top of the air heater, and one end of the second pipeline is fixedly inserted on the outer wall of the top of the dehydration tank and is communicated with the dehydration tank.

Preferably, a group of nozzles II are fixedly arranged on one side of the circumferential outer wall of the air outlet pipes.

Preferably, the first nozzles and the second nozzles are vertically arranged on the air outlet pipe.

Preferably, the mounting frame is fixedly connected with on the inner wall of the top of the dehydration tank, a plurality of equidistantly distributed placing plates are fixedly connected with on the mounting frame, and the fixing mechanism is arranged on the mounting frame.

Preferably, the fixed establishment is including rotating the gear of connection on mounting bracket bottom inner wall, coaxial fixed with the pivot on the gear top outer wall, the pivot runs through a plurality of boards of placing and rotates to be connected on mounting bracket top inner wall, fixed cover is equipped with a plurality of cams on the pivot circumference outer wall, and is a plurality of the cam contacts with placing board top outer wall respectively, sliding connection has the rack with gear engaged with on the mounting bracket bottom inner wall, threaded connection has the screw rod on mounting bracket one side outer wall, screw rod one end rotates to be connected on rack one side outer wall, a plurality of equal sliding connection has the stripper plate on placing board top outer wall.

Preferably, the dehydration tank is connected with a protective door through a hinge, and the protective door is made of transparent materials.

Preferably, an annular limiting groove is formed in the inner wall of the top of the dehydration tank, and one ends of the air outlet pipes are all in sliding connection with the annular limiting groove.

The utility model provides a full-automatic tissue dehydrator through improvement, which has the following improvements and advantages compared with the prior art:

the method comprises the following steps: according to the utility model, the dewatering mechanism is arranged, the flow path of hot air is designed to be in a closed loop state, so that generated hot air can not escape to outside polluted air, the effect of saving energy can be achieved by circulating the hot air, the hot air box is started to generate hot air, then the hot air enters the mounting pipe from the first pipeline and is dispersed into the plurality of air outlet pipes from the mounting pipe, finally the hot air is sprayed out by the first nozzles and the second nozzles, the first nozzles blow the hot air onto each dewatering box, and therefore, the specimens in the dewatering boxes can be ensured to be uniformly blown by the hot air, the second nozzles can generate oblique thrust when the air flow is sprayed out, and the air outlet pipes and the mounting pipe can be driven to rotate, so that the tissue is heated more uniformly, and finally the hot air can enter the hot air through the second pipeline again;

and two,: according to the utility model, the screw rod is rotated to enable the screw rod to move towards the inside of the mounting frame, the screw rod drives the rack to slide at the bottom of the mounting frame, the rack drives the gear to rotate through meshing, the gear drives the rotating shaft to rotate, the rotating shaft drives the cams to rotate, the cams can push the extrusion plate to be attached to the outer wall of one side of the dehydration box, and the dehydration box can be fixed above the placement plate, so that the device can dehydrate tissues in the dehydration plates at the same time, and the working efficiency is improved.

Drawings

The utility model is further explained below with reference to the drawings and examples:

FIG. 1 is a schematic overall perspective view of the present utility model;

FIG. 2 is a schematic view of the internal perspective structure of the dehydration tank of the present utility model;

FIG. 3 is a schematic diagram of the dewatering mechanism of the present utility model;

FIG. 4 is a schematic view of the structure of the fixing mechanism of the present utility model;

fig. 5 is a schematic perspective view of a gear and a rack of the present utility model.

Reference numerals illustrate:

1. a dehydration tank; 2. a protective door; 4. a mounting frame; 5. placing a plate; 6. a limit groove; 7. a dehydration mechanism; 8. a fixing mechanism; 701. an air heater; 702. a first pipeline; 703. a second pipeline; 704. installing a pipe; 705. an air outlet pipe; 706. a first nozzle; 707. a second nozzle; 801. a rotating shaft; 802. a cam; 803. a gear; 804. a rack; 805. a screw; 806. and extruding the plate.

Detailed Description

The following detailed description of the present utility model clearly and fully describes the technical solutions of the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides a full-automatic tissue dehydrator through improvement, and the technical scheme of the utility model is as follows:

as shown in fig. 1-5, a fully automatic tissue dehydrator comprising:

the dehydration device comprises a dehydration tank 1, wherein a dehydration mechanism 7 is arranged in the dehydration tank 1, the dehydration mechanism 7 comprises a mounting pipe 704 rotatably connected to the inner wall of the bottom of the dehydration tank 1, and a plurality of air outlet pipes 705 are fixedly inserted on the outer wall of the circumference of the mounting pipe 704;

the first groups of nozzles 706, the first groups of nozzles 706 are respectively and fixedly arranged on the circumferential outer walls of the air outlet pipes 705, and the air outlet directions of the first groups of nozzles 706 are mutually close;

the hot air blower 701, the hot air blower 701 is fixedly arranged on the circumferential outer wall of the dehydration tank 1, a first pipeline 702 is fixedly inserted on the outer wall of the bottom of the hot air blower 701, and one end of the first pipeline 702 is fixedly inserted on the outer wall of the bottom of the dehydration tank 1 and is communicated with the installation pipe 704;

the second pipeline 703, the second pipeline 703 is fixedly inserted on the top outer wall of the hot air blower 701, and one end of the second pipeline 703 is fixedly inserted on the top outer wall of the dehydration tank 1 and is communicated with the dehydration tank 1.

By the above structure or mechanism: the hot air blower 701 is started to generate hot air, then the hot air enters the installation pipe 704 from the first pipeline 702 and is then dispersed into the air outlet pipes 705 from the installation pipe 704, finally the hot air is sprayed out from the first nozzles 706 and the second nozzles 707, the first nozzles 706 blow the hot air onto the dehydration boxes, so that the specimens inside the dehydration boxes can be ensured to be uniformly blown by the hot air, finally the hot air can enter the hot air blower 701 again through the second pipeline 703, the generated hot air cannot escape into the outside polluted air, and the energy saving effect can be achieved by recycling the hot air.

Further, a group of nozzles two 707 are fixedly installed on one side of the circumferential outer wall of the plurality of air outlet pipes 705.

By the above structure or mechanism: the nozzles two 707 will generate an oblique thrust when ejecting the air flow, so as to drive the air outlet pipes 705 and the mounting pipe 704 to rotate, so that the tissue is heated more uniformly.

Further, a plurality of groups of first nozzles 706 and second nozzles 707 are vertically disposed on the air outlet pipe 705.

By the above structure or mechanism: the hot air blown out by the first nozzle 706 can be uniformly blown on the tissues on the dehydration plate, and the second nozzle 707 is vertically arranged, so that the generated thrust is more uniform.

Further, fixedly connected with mounting bracket 4 on the inner wall of dehydration jar 1 top, fixedly connected with a plurality of equidistance on the mounting bracket 4 place board 5, install fixed establishment 8 on the mounting bracket 4, fixed establishment 8 is including rotating the gear 803 of connecting on the inner wall of mounting bracket 4 bottom, coaxial being fixed with pivot 801 on the outer wall of gear 803 top, pivot 801 runs through a plurality of boards 5 of placing and rotates to be connected on the inner wall of mounting bracket 4 top, fixed cover is equipped with a plurality of cams 802 on the outer wall of pivot 801 circumference, a plurality of cams 802 contact with respectively with place board 5 top outer wall, sliding connection has rack 804 with gear 803 engaged with on the inner wall of mounting bracket 4 bottom, threaded connection has screw 805 on the outer wall of mounting bracket 4 one side, screw 805 one end rotates to be connected on rack 804 one side outer wall, equal sliding connection has extrusion plate 806 on the outer wall of 5 top of a plurality of placing boards.

By the above structure or mechanism: the screw 805 is rotated to enable the screw 805 to move towards the inside of the mounting frame 4, the screw 805 drives the rack 804 to slide at the bottom of the mounting frame 4, the rack 804 drives the gear 803 to rotate through meshing, the gear 803 drives the rotating shaft 801 to rotate, the rotating shaft 801 drives the cams 802 to rotate, the cams 802 can push the extrusion plate 806 to be attached to the outer wall of one side of the dehydration box, and the dehydration box can be fixed above the placement plate 5, so that the device can dehydrate tissues in the dehydration plates simultaneously, and the working efficiency is improved.

Further, the dewatering tank 1 is connected with a protective door 2 through a hinge, and the protective door 2 is made of transparent materials.

By the above structure or mechanism: the protective door 2 can prevent the leakage of harmful gas, and the dehydrated state of the tissue can be observed through the protective door 2.

Further, an annular limiting groove 6 is formed in the inner wall of the top of the dehydration tank 1, and one ends of a plurality of air outlet pipes 705 are all in sliding connection with the annular limiting groove 6.

By the above structure or mechanism: so that the plurality of outlet pipes 705 can be more stable during rotation.

Working principle: firstly, a dehydration box filled with a specimen is placed above a placement plate 5, then a screw 805 is rotated to enable the dehydration box to move towards the inside of a mounting frame 4, the screw 805 drives a rack 804 to slide at the bottom of the mounting frame 4, the rack 804 drives a gear 803 to rotate through meshing, the gear 803 drives a rotating shaft 801 to rotate, the rotating shaft 801 drives a plurality of cams 802 to rotate, the cams 802 push a squeezing plate 806 to be attached to the outer wall of one side of the dehydration box, the dehydration box can be fixed above the placement plate 5, then a hot air blower 701 is started to generate hot air, then the hot air enters a mounting pipe 704 from a first pipeline 702 and is blocked, then the hot air is dispersed into a plurality of air outlet pipes 705 from the mounting pipe 704, finally the first nozzles 706 and the second nozzles 706 jet out, the hot air is blown onto each dehydration box, so that the specimen in the rack can be guaranteed to be uniformly blown by the hot air, the second nozzles 707 can generate an oblique thrust when the hot air is jetted, the hot air is driven to rotate by the plurality of air outlet pipes 705 and the mounting pipe 704, so that the tissues can be more uniformly heated, finally the hot air can enter the second pipeline 701 again, the generated hot air can not enter the mounting pipe 704, and the air can be circulated and the outside can not pollute the environment.

Claims (7)

1. A full-automatic tissue dehydrator, which is characterized in that: comprising the following steps:

the dehydration device comprises a dehydration tank (1), wherein a dehydration mechanism (7) is arranged in the dehydration tank (1), the dehydration mechanism (7) comprises an installation pipe (704) rotatably connected to the inner wall of the bottom of the dehydration tank (1), and a plurality of air outlet pipes (705) are fixedly inserted on the outer wall of the circumference of the installation pipe (704);

a plurality of groups of first nozzles (706), wherein the first nozzles (706) are respectively and fixedly arranged on the circumferential outer walls of the air outlet pipes (705), and the air outlet directions of the first nozzles (706) are mutually close;

the hot air blower (701), the hot air blower (701) is fixedly arranged on the circumferential outer wall of the dehydration tank (1), a first pipeline (702) is fixedly inserted on the outer wall of the bottom of the hot air blower (701), and one end of the first pipeline (702) is fixedly inserted on the outer wall of the bottom of the dehydration tank (1) and communicated with the installation pipe (704);

the second pipeline (703), the second pipeline (703) is fixedly inserted on the top outer wall of the hot air blower (701), and one end of the second pipeline (703) is fixedly inserted on the top outer wall of the dehydration tank (1) and is communicated with the dehydration tank (1).

2. A fully automatic tissue dehydrator according to claim 1, wherein: a group of nozzles II (707) are fixedly arranged on one side of the circumferential outer wall of the air outlet pipes (705).

3. A fully automatic tissue dehydrator according to claim 2, wherein: and a plurality of groups of first nozzles (706) and second nozzles (707) are vertically arranged on the air outlet pipe (705).

4. A fully automatic tissue dehydrator according to claim 1, wherein: the novel dewatering device is characterized in that an installation frame (4) is fixedly connected to the inner wall of the top of the dewatering tank (1), a plurality of equidistant placement plates (5) are fixedly connected to the installation frame (4), and a fixing mechanism (8) is installed on the installation frame (4).

5. A fully automatic tissue dehydrator according to claim 4, wherein: fixed establishment (8) are including rotating gear (803) of connection on mounting bracket (4) bottom inner wall, coaxial pivot (801) that are fixed with on gear (803) top outer wall, pivot (801) run through a plurality of boards (5) of placing and rotate to be connected on mounting bracket (4) top inner wall, fixed cover is equipped with a plurality of cams (802) on pivot (801) circumference outer wall, a plurality of cams (802) contact with board (5) top outer wall of placing respectively, sliding connection has rack (804) with gear (803) engaged with on mounting bracket (4) bottom inner wall, threaded connection has screw rod (805) on mounting bracket (4) one side outer wall, screw rod (805) one end rotation is connected on rack (804) one side outer wall, a plurality of equal sliding connection has extrusion board (806) on board (5) top outer wall of placing.

6. A fully automatic tissue dehydrator according to claim 1, wherein: the dewatering tank (1) is connected with a protective door (2) through a hinge, and the protective door (2) is made of transparent materials.

7. A fully automatic tissue dehydrator according to claim 1, wherein: an annular limiting groove (6) is formed in the inner wall of the top of the dehydration tank (1), and one ends of a plurality of air outlet pipes (705) are all connected in the annular limiting groove (6) in a sliding mode.

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