CN115814114A - Quick degassing unit of medical instrument - Google Patents

Abstract

The invention discloses a quick disinfection device for medical instruments, and relates to the technical field of medical treatment, which comprises a bottom plate and a supporting table, wherein the top of the bottom plate is fixedly connected with a plurality of supporting rods, the tops of the supporting rods are fixedly connected with the supporting table, through holes are formed in the supporting table, an electric telescopic rod penetrates through the through holes and is connected with the bottom of the electric telescopic rod, the bottom of the driving motor is fixedly connected with the bottom plate, the top of the electric telescopic rod is provided with a plurality of transverse plates in an annular array, each transverse plate is fixedly connected with a vertical plate, the bottom of each vertical plate is slidably clamped with a charging assembly, the charging assemblies are used for loading the medical instruments, and the top of the supporting table is sequentially provided with a feeding assembly, a high-temperature sterilization assembly, a drying assembly and a discharging assembly in an annular array mode.

Description

Quick degassing unit of medical instrument

Technical Field

The invention relates to the technical field of medical treatment, in particular to a quick disinfection device for medical instruments.

Background

Medical instrument includes scalpel, medicine cotton ball and tweezers etc. that the operation in-process used, need carry out regularly high temperature disinfection to it after using the completion to guarantee safe in utilizationly.

Chinese patent publication No. CN112843287a discloses a rapid disinfection device for medical instruments, which comprises a disinfection box; an annular plate is fixedly connected inside the disinfection box, an opening is formed in the top end of the annular plate, a liquid inlet groove is formed in the side wall of the annular plate, a motor is installed on the side wall of the disinfection box, the end part of the motor is connected with a rotary column through a rotary shaft, rotary plates are connected to the side wall of the rotary column, and a disinfection cavity for storing medical instruments is formed between each two adjacent rotary plates and the inner wall of the annular plate and the side wall of the rotary column; the medical disinfection device can place various medical instruments in the disinfection cavity in a classified manner, so that the disinfection cavity can perform disinfection treatment for corresponding time according to different medical instruments, the instruments can be disinfected more sufficiently and efficiently, and the disinfection of other instruments in the disinfection cavity is not affected in the process of taking out a single instrument, so that the convenience and the practicability of the disinfection device in use are greatly improved.

However, the above patent also has the following problems: when the demand of medical instruments is large, the disinfection and updating rate of the medical instruments is high, but the traditional mode is to uniformly concentrate the medical instruments and then uniformly disinfect the medical instruments, obviously, the disinfection efficiency is too low, and in the two processes of entering and removing the medical instruments from the disinfection cavity, the operation of the medical instruments in the patent is complex, and the subsequent drying process of the medical instruments is not available, so that the medical instruments can not be quickly disinfected and updated.

Disclosure of Invention

The invention aims to provide a quick disinfection device for medical instruments, which aims to solve the problems in the background technology.

The technical scheme of the invention is as follows: the utility model provides a quick degassing unit of medical instrument, includes bottom plate, brace table, a plurality of bracing pieces of bottom plate top fixedly connected with, the bracing piece top with brace table fixed connection, the opening has been seted up on the brace table, through connection has electric telescopic handle in the opening, electric telescopic handle bottom fixedly connected with driving motor, the driving motor bottom with bottom plate fixed connection, the electric telescopic handle top is the annular array and is provided with a plurality of diaphragms, every equal fixedly connected with riser on the diaphragm, riser bottom slip joint has the subassembly of feeding, the subassembly of feeding is used for loading medical instrument, the brace table top is the annular array and has set gradually feeding subassembly, high temperature virus killing subassembly, stoving subassembly and unloading subassembly.

Preferably, the subassembly of feeding includes the shell, the slide has been seted up at the shell top, two sliders of riser bilateral symmetry fixedly connected with, two spouts have been seted up to the symmetry on the inside both sides wall of slide, slider sliding connection in the spout, fixedly connected with third spring in the spout, the third spring with slider fixed connection, a plurality of water holes have all been seted up on the wall all around of shell and the bottom wall, the feed inlet has been seted up on the shell lateral wall, be provided with the feed plate on the feed inlet, the feed plate with be provided with first elastic sliding assembly between the feed inlet, feed plate one side fixedly connected with feeding subassembly complex linkage plate.

Preferably, the outer wall of the other side of the feeding plate is fixedly connected with an arc-shaped block matched with the feeding assembly.

Preferably, first elastic sliding component includes two first connecting blocks and two first grooves that reset, two first groove symmetry that resets is seted up on the both sides wall of feed inlet, two first connecting block symmetry fixed connection is on the both sides wall of feed plate, the first spring of fixedly connected with in the first groove that resets, first connecting block sliding connection be in the first groove that resets, just first connecting block with first spring fixed connection.

Preferably, the feeding assembly comprises a conveying belt supporting shell and a push plate, the conveying belt supporting shell is provided with a conveying belt, the conveying belt supports a plurality of supporting frames fixedly connected to the bottom of the supporting shell, the bottom of the supporting frames is fixedly connected with the bottom plate, a connecting plate is fixedly connected to the conveying belt supporting shell, the top of the connecting plate is fixedly connected with a lifting plate matched with a linkage plate, the bottom of the push plate is fixedly connected with a supporting table, and the push plate is matched with the arc-shaped block.

Preferably, the charging assembly further comprises a sealing plate, a discharge port is formed in the bottom of the shell, the sealing plate is connected with the discharge port through a second elastic sliding assembly, the second elastic sliding assembly comprises two second connecting blocks and two second reset grooves, the two second reset grooves are symmetrically formed in two side walls of the discharge port, a second spring is fixedly connected to the middle of each second reset groove, the two second connecting blocks are symmetrically fixed to two side walls of the sealing plate, the second connecting blocks are slidably connected to the middle of each second reset groove, the second connecting blocks are fixedly connected to the second springs, the bottom of the other side of the sealing plate is fixedly connected with abutting blocks, the discharging assembly comprises abutting plates and a discharging port, the bottoms of the abutting plates are fixedly connected to the supporting table, the abutting plates are matched with the abutting blocks, and the discharging port is formed in the supporting table.

Preferably, the sealing plate is further provided with a through opening.

Preferably, the high-temperature disinfection component comprises an ultrasonic cleaner, a rotating motor is fixedly connected to the bottom of an inner cavity of the ultrasonic cleaner, a connecting column is fixedly connected to the end of an output shaft of the rotating motor, a rotating opening is formed in the sealing plate, a rotating groove is formed in the inner peripheral wall of the rotating opening, a rotating ring is rotatably connected to the rotating groove, a connecting disc is fixedly connected to the inner peripheral wall of the rotating ring, a spline groove is formed in the bottom of the connecting disc, a spline bump is fixedly connected to the top of the connecting column, and the spline bump is connected with the spline groove in an embedded mode.

Preferably, an elastic sleeve rod is fixedly connected to the top wall of the rotary groove, a ball is fixedly connected to the bottom of the elastic sleeve rod, and the bottom of the ball is in abutting connection with the rotary ring.

Preferably, the stoving subassembly includes two annular walls, two form the stoving region between the annular wall, two annular wall bottom with brace table fixed connection, the air-out groove has been seted up on the brace table, brace table bottom fixedly connected with air heater, a plurality of air outlets have been seted up in the air-out groove, go back two vibrating motor of fixedly connected with in the air-out groove, a plurality of mounting grooves have still been seted up on the inner wall of annular wall, every equal fixedly connected with heating pipe in the mounting groove.

The invention provides a quick disinfection device for medical instruments through improvement, which has the following improvements and advantages compared with the prior art:

one is as follows: according to the invention, the driving motor is used for controlling the electric telescopic rod to intermittently rotate, the electric telescopic rod controls the plurality of charging assemblies to perform revolution motion along the circle center of the supporting table through the transverse plate and the vertical plate, so that up-down and revolution motion of the charging assemblies is realized, a plurality of medical instruments are loaded in the charging assemblies, when the charging assemblies move into the charging assemblies, the charging assemblies are used for feeding the medical instruments into the charging assemblies, and the charging assemblies loaded with the medical instruments sequentially pass through the high-temperature sterilization area, the drying area and the blanking area along with the revolution motion and the up-down motion, so that high-temperature sterilization, drying and automatic blanking operations are performed under the action of the high-temperature sterilization assembly, the drying assembly and the blanking assembly.

The second step is as follows: when the charging assembly is located in the feeding area, the driving motor stops rotating at the moment, the electric telescopic rod is started, the shell is driven to move downwards, when the shell moves downwards, the lifting plate can abut against the linkage plate, so that the linkage plate and the feeding plate cannot move downwards, the feeding hole is opened along with the continuous downward movement of the shell, and meanwhile, the pushing plate abuts against the arc-shaped block, so that the pushing plate can provide transverse thrust to the arc-shaped block in the downward movement process of the shell, the shell can move horizontally towards the conveying belt supporting shell, the conveying belt supporting shell can be inserted into the feeding hole, and therefore when medical instruments are conveyed in the conveying belt, the medical instruments can stably enter the shell, and the feeding stability of the medical instruments is guaranteed.

And thirdly: when the shell is located in a high-temperature disinfection area, the shell carries medical instruments to move downwards, when the shell moves into the ultrasonic cleaner, high-temperature cleaning liquid in the ultrasonic cleaner enters an inner cavity of the shell through a plurality of water holes formed in the shell, so that the medical instruments are disinfected at high temperature, the connecting disc can be abutted against the connecting column along with downward movement of the shell, at the moment, the rotating motor is started, the rotating motor drives the connecting column to rotate, the connecting column drives the spline lug to rotate, the orthographic projection of the spline lug in the spline groove can enter a cavity of the spline groove during rotation of the spline lug, the cavity space of the spline groove is larger than that of the spline lug, the spline lug can smoothly enter the spline groove, a clamping effect is formed, the connecting disc is driven to rotate, the top surface of the connecting disc faces the inner cavity of the shell, it can be understood that the top surface of the connecting disc can abut against most of the medical instruments, so that the rotation of the connecting disc can generate an interference effect on the medical instruments inside the shell, the positions and gaps between the medical instruments are changed, a circulation space is provided for high-temperature disinfection water, and the disinfection effect of the medical instruments is increased, and the uniformity of the high-temperature disinfection is guaranteed.

Fourthly, the method comprises the following steps: the elastic sleeve rod is composed of rod-shaped structures which are embedded into each other, and the rod-shaped structures are connected through the springs, so that the elastic sleeve rod can generate downward pressure on the rotating ring through the balls, the connecting disc has a stable downward pressing trend, the clamping effect of the spline bump in the spline groove is more stable, and the situation that the spline bump is separated from the spline groove due to the fact that the rotating speed of the spline bump is too high is avoided.

And fifthly: when the shell is located in the drying area, the heating pipes on the annular wall are used for increasing the temperature of the drying area, so that the medical instrument in the shell is dried, meanwhile, the hot air is blown out of the air outlet by the hot air blower, the hot air flows in the drying area and can enter the shell through the water holes, so that the medical instrument in the shell is dried, meanwhile, under the action of the electric telescopic rod, the shell moves downwards, the connecting disc at the bottom of the shell is abutted to the vibrating motor, the vibrating motor can drive the connecting disc to vibrate, the medical instrument in the shell vibrates, a flowing space is provided for the hot air, and the drying effect is enhanced.

And the sixth step: when the shell is located in a blanking area, the electric telescopic rod controls the shell to move downwards, the abutting plate can abut against the arc abutting block, at the moment, the shell cannot move leftwards due to the fact that the vertical plate is located on the rightmost side of the slide way, the sealing plate moves leftwards, the discharging hole is opened, medical instruments can fall freely and are discharged from the blanking hole, automatic discharging work is completed, then the electric telescopic rod controls the shell to move upwards to reset, at the moment, the sealing plate resets under the action of the second spring, the discharging hole is sealed again, and feeding work is guaranteed.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, it is obvious that the drawings in the following descriptions are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a perspective view of the overall structure of the present invention;

FIG. 2 is a schematic plan view of the overall structure of the present invention;

FIG. 3 is a first perspective view of the three-dimensional structure of the housing of the present invention;

FIG. 4 is a second perspective view of the three-dimensional structure of the housing of the present invention;

FIG. 5 is a schematic cross-sectional view of the housing of the present invention;

FIG. 6 is a schematic cross-sectional view of a feed inlet in the present invention;

FIG. 7 is a schematic view of the lift plate abutting against the linkage plate in the present invention;

FIG. 8 is a schematic view of the translation of the housing in the direction of the conveyor belt support housing in accordance with the present invention;

FIG. 9 is a schematic cross-sectional view of the housing of the present invention within an ultrasonic cleaner;

FIG. 10 is a perspective view of the annular wall of the present invention;

FIG. 11 is a schematic view showing the opening of the sealing plate in the present invention;

fig. 12 is an enlarged view of fig. 11 at a.

In the figure: 1. a base plate; 101. a support bar; 2. a support table; 201. a port; 202. an electric telescopic rod; 203. a drive motor; 204. a transverse plate; 205. a vertical plate; 3. a housing; 301. a slideway; 302. a slider; 303. a chute; 304. a third spring; 305. a water pore; 306. a feed inlet; 307. a feeding plate; 308. a linkage plate; 309. an arc-shaped block; 310. a first connection block; 311. a first reset groove; 312. a first spring; 4. a conveyor belt support housing; 401. pushing the plate; 402. a support frame; 403. a connecting plate; 404. lifting the plate; 5. sealing plates; 501. a discharge port; 502. a second connecting block; 503. a second reset groove; 504. a second spring; 505. a resisting block; 506. a resisting plate; 507. a feed opening; 508. a through opening; 6. an ultrasonic cleaner; 601. connecting columns; 602. rotating the groove; 603. rotating the ring; 604. a connecting disc; 605. a spline groove; 606. a spline projection; 607. an elastic loop bar; 608. a ball bearing; 7. an annular wall; 701. an air outlet groove; 702. a hot air blower; 703. an air outlet; 704. a vibration motor; 705. mounting grooves; 8. a rotating electric machine.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention.

The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

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 invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 12, an embodiment of the invention provides a rapid disinfection device for medical instruments, which comprises a bottom plate 1 and a support table 2, wherein a plurality of support rods 101 are fixedly connected to the top of the bottom plate 1, the tops of the support rods 101 are fixedly connected to the support table 2, a through opening 201 is formed in the support table 2, an electric telescopic rod 202 is connected to the through opening 201 in a penetrating manner, a driving motor 203 is fixedly connected to the bottom of the electric telescopic rod 202, the bottom of the driving motor 203 is fixedly connected to the bottom plate 1, a plurality of transverse plates 204 are arranged on the top of the electric telescopic rod 202 in an annular array, a vertical plate 205 is fixedly connected to each transverse plate 204, a charging component is slidably clamped to the bottom of each vertical plate 205 and used for loading the medical instruments, and a feeding component, a high-temperature sterilization component, a drying component and a discharging component are sequentially arranged on the top of the support table 2 in an annular array.

Specifically, the method comprises the following steps: the driving motor 203 is used for controlling the electric telescopic rod 202 to intermittently rotate, the electric telescopic rod 202 controls the plurality of charging assemblies to perform revolution motion along the circle center of the supporting table 2 through the transverse plate 204 and the vertical plate 205, so that up-down and revolution motion of the charging assemblies is realized, a plurality of medical instruments are loaded in the charging assemblies, when the charging assemblies move into the charging assemblies, the charging assemblies are used for sending the medical instruments into the charging assemblies, and along with the revolution motion and the up-down motion, the charging assemblies loaded with the medical instruments sequentially pass through the high-temperature sterilization area, the drying area and the blanking area, so that high-temperature sterilization, drying and automatic blanking operations are performed under the action of the high-temperature sterilization assembly, the drying assembly and the blanking assembly.

The subassembly of feeding includes shell 3, slide 301 has been seted up at 3 tops of shell, two sliders 302 of the symmetrical fixedly connected with in riser 205 both sides, two spout 303 have been seted up to the symmetry on the inside both sides wall of slide 301, slider 302 sliding connection is in spout 303, fixedly connected with third spring 304 in the spout 303, third spring 304 and slider 302 fixed connection, a plurality of water holes 305 have all been seted up on the wall all around of shell 3 and the bottom wall, feed inlet 306 has been seted up on the 3 lateral wall of shell, be provided with feed plate 307 on the feed inlet 306, be provided with first elastic sliding component between feed plate 307 and the feed inlet 306, feed plate 307 one side fixedly connected with and feed component complex linkage board 308.

An arc block 309 matched with the feeding assembly is fixedly connected to the outer wall of the other side of the feeding plate 307.

The first elastic sliding assembly comprises two first connecting blocks 310 and two first reset grooves 311, the two first reset grooves 311 are symmetrically formed in two side walls of the feeding hole 306, the two first connecting blocks 310 are symmetrically and fixedly connected to two side walls of the feeding plate 307, first springs 312 are fixedly connected to the first reset grooves 311, the first connecting blocks 310 are slidably connected to the first reset grooves 311, and the first connecting blocks 310 are fixedly connected to the first springs 312.

The feeding assembly comprises a conveying belt supporting shell 4 and a push plate 401, the conveying belt supporting shell 4 is assembled with a conveying belt, the conveying belt supporting shell 4 is fixedly connected with a plurality of supporting frames 402 at the bottom, the bottom of each supporting frame 402 is fixedly connected with a bottom plate 1, a connecting plate 403 is fixedly connected to the conveying belt supporting shell 4, the top of the connecting plate 403 is fixedly connected with a lifting plate 404 matched with a linkage plate 308, the bottom of the push plate 401 is fixedly connected with a supporting table 2, and the push plate 401 is matched with an arc-shaped block 309.

Specifically, the method comprises the following steps: referring to fig. 5, 6, 7 and 8, when the charging assembly is in the charging area, the driving motor 203 stops rotating, the electric telescopic rod 202 is started to drive the housing 3 to move downwards, when the housing 3 moves downwards, the lifting plate 404 abuts against the linkage plate 308, so that the linkage plate 308 and the feeding plate 307 cannot move downwards, and along with the continued downward movement of the housing 3, the feeding port 306 is opened, meanwhile, the pushing plate 401 abuts against the arc-shaped block 309, so that the arc-shaped block 309 can give a transverse pushing force to the arc-shaped block 309 in the downward movement process of the housing 3, so that the housing 3 moves towards the conveying belt supporting shell 4, so that the conveying belt supporting shell 4 can be inserted into the feeding port 306, and therefore, when the medical instrument is conveyed in the conveying belt, the medical instrument can stably enter the housing 3, the stability of the medical instrument feeding is guaranteed, after the feeding work is completed, the electric telescopic rod 202 resets upwards, and then the driving motor 203 is started, so that the charging assembly carries the medical instrument to enter the high-temperature sterilization area;

wherein the sliding block 302 enables the vertical plate 205 to move horizontally in the slide way 301 through the elastic sliding connection of the third spring 304 in the sliding groove 303, so as to adapt to the translation of the casing 3, and the third spring 304 is used for the return of the vertical plate 205 in the slide way 301, similarly, the first elastic sliding assembly is used for feeding the feeding plate 307 with a downward pulling force, so that after the feeding of the casing 3 is completed, the feeding plate 307 can stably seal the feeding hole 306.

High temperature sterilization subassembly includes ultrasonic cleaner 6, 6 inner chamber bottom fixedly connected with rotating electrical machines 8 of ultrasonic cleaner, the tip fixedly connected with spliced pole 601 of 8 output shafts of rotating electrical machines, set up the rotation mouth on the closing plate 5, the rotating groove 602 has been seted up on the inner peripheral wall of rotation mouth, it has swivel 603 to rotate in the rotating groove 602, fixedly connected with connection pad 604 on the internal perisporium of swivel 603, spline recess 605 has been seted up to connection pad 604 bottom, spliced pole 601 top fixedly connected with spline lug 606, spline lug 606 is connected with spline recess 605 embedding.

An elastic sleeve rod 607 is fixedly connected to the top wall of the rotating groove 602, a ball 608 is fixedly connected to the bottom of the elastic sleeve rod 607, and the bottom of the ball 608 is connected to the rotating ring 603 in an abutting manner.

Specifically, the method comprises the following steps: referring to fig. 9, when the housing 3 is located in a high-temperature sterilization area, the housing 3 carries a medical apparatus to move downward, when the housing 3 moves into the ultrasonic cleaner 6, a high-temperature cleaning solution in the ultrasonic cleaner 6 enters an inner cavity of the housing 3 through the plurality of water holes 305 formed in the housing 3, so that the medical apparatus is sterilized at a high temperature, and as the housing 3 moves downward, the connection pad 604 collides with the connection post 601, at this time, the rotating motor 8 is started, the rotating motor 8 drives the connection post 601 to rotate, the connection post 601 drives the spline bump 606 to rotate, during the rotation of the spline bump 606, an orthographic projection of the spline bump 606 in the spline groove 605 enters a cavity of the spline groove 605, and a cavity space of the spline groove 605 is larger than the spline bump 606, so that the spline bump 606 can smoothly enter the spline groove 605, thereby forming a clamping effect, so as to drive the connection pad 604 to rotate, and a top surface of the connection pad 604 faces the inner cavity of the housing 3;

it can be understood that the top surface of the connecting disc 604 can abut against most medical instruments, so that the rotation of the connecting disc 604 can generate an interference effect on the medical instruments in the shell 3, the positions and gaps between the medical instruments are changed, a circulation space is provided for high-temperature disinfection water, and the disinfection surface of the medical instruments is increased, so that the high-temperature disinfection effect is enhanced, and the uniformity of high-temperature disinfection is guaranteed;

referring to fig. 12, the elastic sleeve rod 607 is composed of rod-shaped structures embedded into each other, and the rod-shaped structures are connected by a spring, so that the elastic sleeve rod 607 can generate downward pressure on the rotating ring 603 through the balls 608, and the connecting disc 604 has a stable downward pressure tendency, so that the clamping effect of the spline protrusion 606 in the spline groove 605 is more stable, and the situation that the spline protrusion 606 is disengaged from the spline groove 605 due to too fast rotation speed of the spline protrusion 606 is avoided.

The stoving subassembly includes two annular walls 7, it is regional to form the stoving between two annular walls 7, two annular wall 7 bottoms and a supporting bench 2 fixed connection, air-out groove 701 has been seted up on a supporting bench 2, supporting bench 2 bottom fixedly connected with air heater 702, it has a plurality of air outlets 703 to open in the air-out groove 701, go back two vibrating motor 704 of fixedly connected with in the air-out groove 701, a plurality of mounting grooves 705 have still been seted up on the inner wall of annular wall 7, equal fixedly connected with heating pipe in every mounting groove 705.

Specifically, the method comprises the following steps: referring to fig. 10 and 12, when the housing 3 is located in the drying region, the heating pipes on the annular wall 7 are used to raise the temperature of the drying region, so as to dry the medical device in the housing 3, and at the same time, the hot air blower 702 blows hot air out of the air outlet 703, so that the hot air flows in the drying region, and the hot air can enter the interior of the housing 3 through the water hole 305, so as to dry the medical device in the interior of the housing 3;

meanwhile, under the action of the electric telescopic rod 202, the shell 3 moves downwards, so that the connecting disc 604 at the bottom of the shell 3 is abutted against the vibration motor 704, and the vibration motor 704 can drive the connecting disc 604 to vibrate, so that medical equipment in the shell 3 vibrates, a flowing space is provided for hot air, and the drying effect is enhanced;

due to the existence of the elastic loop bar 607, the rotating ring 603 can have a space moving up and down in the rotating groove 602, so that the vibration effect of the connecting disc 604 is adapted, and the normal operation of the vibration work of the connecting disc 604 is ensured.

The charging assembly further comprises a sealing plate 5, a discharge port 501 is formed in the bottom of the shell 3, the sealing plate 5 is connected with the discharge port 501 through a second elastic sliding assembly, the second elastic sliding assembly comprises two second connecting blocks 502 and two second reset grooves 503, the two second reset grooves 503 are symmetrically formed in two side walls of the discharge port 501, a second spring 504 is fixedly connected to the second reset grooves 503, the two second connecting blocks 502 are symmetrically fixed to two side walls of the sealing plate 5, the second connecting blocks 502 are slidably connected to the second reset grooves 503, the second connecting blocks 502 are fixedly connected to the second spring 504, a supporting block 505 is fixedly connected to the bottom of the other side of the sealing plate 5, the discharging assembly comprises a supporting plate 506 and a discharging port 507, the bottom of the supporting plate 506 is fixedly connected with the supporting table 2, the supporting plate 506 is matched with the supporting block 505, and the discharging port 507 is formed in the supporting table 2.

Specifically, the method comprises the following steps: referring to fig. 11, when the housing 3 is located in the blanking area, the electric telescopic rod 202 controls the housing 3 to move downward, the abutting plate 506 abuts against the arc abutting block 505, at this time, the vertical plate 205 is located at the rightmost side of the slide 301, so that the housing 3 cannot move leftward, the sealing plate 5 moves leftward, the discharge port 501 is opened, the medical instrument can fall freely and is discharged from the blanking port 507, the automatic discharging operation is completed, then the electric telescopic rod 202 controls the housing 3 to move upward and return, at this time, the sealing plate 5 returns under the action of the second spring 504, so that the discharge port 501 is sealed again, and a guarantee is provided for the feeding operation;

wherein, a sterile storage box can be arranged below the feed opening 507 for timely receiving the falling medical instruments.

The sealing plate 5 is further provided with a through hole 508, and the through hole 508 provides a through space for the push plate 401 during feeding.

The working principle is as follows: the driving motor 203 is used for controlling the electric telescopic rod 202 to intermittently rotate, the electric telescopic rod 202 controls a plurality of charging components to perform revolution motion along the circle center of the support table 2 through the transverse plate 204 and the vertical plate 205, so that up-down and revolution motion of the charging components is realized, a plurality of medical instruments are loaded in the charging components, when the charging components are located in a charging area, the driving motor 203 stops rotating, the electric telescopic rod 202 is started, so that the shell 3 is driven to move downwards, when the shell 3 moves downwards, the lifting plate 404 can abut against the linkage plate 308, so that the linkage plate 308 and the charging plate 307 cannot move downwards, and along with continuous downward movement of the shell 3, the feeding port 306 is opened, meanwhile, the pushing plate 401 abuts against the arc-shaped block 309, so that the arc-shaped block 309 can give a transverse pushing force to the arc-shaped block 309 in the downward movement process along with the shell 3, so that the shell 3 can translate towards the direction of the conveying belt support shell 4, so that the conveying belt support shell 4 can be inserted into the feeding port 306, when the medical instruments are conveyed in a conveying belt, the medical instrument can stably enter the shell 3, the charging area after the charging components are started, and the electric telescopic rod 202 is reset, and then the electric telescopic rod 202 drives the high-temperature medical instruments to carry the toxic materials;

when the shell 3 is located in a high-temperature disinfection area, the shell 3 carries medical instruments to move downwards, when the shell 3 moves into the ultrasonic cleaner 6, high-temperature cleaning liquid in the ultrasonic cleaner 6 enters an inner cavity of the shell 3 through a plurality of water holes 305 formed in the shell 3, so that the medical instruments are disinfected at high temperature, and along with the downward movement of the shell 3, the connecting disc 604 abuts against the connecting column 601, at the moment, the rotating motor 8 is started, the rotating motor 8 drives the connecting column 601 to rotate, the connecting column 601 drives the spline bump 606 to rotate, during the rotation of the spline bump 606, the orthographic projection of the spline bump 606 in the spline groove 605 enters a cavity of the spline groove 605, the cavity space of the spline groove 605 is larger than the spline bump 606, so that the spline bump 606 can smoothly enter the spline groove 605, a clamping effect is formed, the connecting disc 604 is driven to rotate, the top surface of the connecting disc 604 faces towards the inner cavity of the shell 3, the surface of the connecting disc 604 abuts against most of the medical instruments, so that the rotation of the connecting disc 604 can generate an interference effect on the medical instruments inside the shell 3, the high-temperature disinfection space between the medical instruments is changed, and the disinfection effect is enhanced for the disinfection of the high-temperature disinfection water is provided, and the high-temperature disinfection effect is enhanced;

when the outer shell 3 is located in the drying area, the plurality of heating pipes on the annular wall 7 are used for increasing the temperature of the drying area, so that medical instruments in the outer shell 3 are dried, meanwhile, the hot air is blown out from the air outlet 703 by the hot air blower 702, so that the hot air flows in the drying area, and the hot air can enter the outer shell 3 through the water hole 305, so that the medical instruments in the outer shell 3 are dried, meanwhile, under the action of the electric telescopic rod 202, the outer shell 3 moves downwards, so that the connecting disc 604 at the bottom of the outer shell 3 is abutted against the vibrating motor 704, so that the vibrating motor 704 can drive the connecting disc 604 to vibrate, so that the medical instruments in the outer shell 3 vibrate, a flowing space is provided for the hot air, and the drying effect is enhanced;

finally, the shell 3 moves to the blanking area, the electric telescopic rod 202 controls the shell 3 to move downwards, the resisting plate 506 can abut against the arc-shaped resisting block 505, at the moment, the vertical plate 205 is located on the rightmost side of the slide 301, the shell 3 cannot move leftwards, the sealing plate 5 moves leftwards, the discharge hole 501 is opened, medical instruments can fall freely and are discharged from the discharge hole 507, automatic discharging work is completed, then the electric telescopic rod 202 controls the shell 3 to move upwards and reset, at the moment, the sealing plate 5 resets under the action of the second spring 504, the discharge hole 501 is sealed again, guarantee is provided for feeding work, and it can be understood that a plurality of charging assemblies can simultaneously and respectively perform feeding, high-temperature sterilization, drying and blanking operations, and the efficiency of sterilization of the medical instruments is improved.

The previous description is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The utility model provides a quick degassing unit of medical instrument, includes bottom plate (1), brace table (2), its characterized in that: bottom plate (1) top a plurality of bracing pieces of fixedly connected with (101), bracing piece (101) top with brace table (2) fixed connection, open (201) have been seted up on brace table (2), through connection has electric telescopic handle (202) in open (201), electric telescopic handle (202) bottom fixedly connected with driving motor (203), driving motor (203) bottom with bottom plate (1) fixed connection, electric telescopic handle (202) top is that ring array is provided with a plurality of diaphragms (204), every equal fixedly connected with riser (205) on diaphragm (204), riser (205) bottom slip joint has the subassembly of feeding, the subassembly of feeding is used for loading medical instrument, brace table (2) top is ring array and has set gradually feeding subassembly, high temperature virus killing subassembly, stoving subassembly and unloading subassembly.

2. The medical instrument rapid disinfection device according to claim 1, wherein: the subassembly of feeding includes shell (3), slide (301) have been seted up at shell (3) top, two sliders (302) of riser (205) bilateral symmetry fixedly connected with, two spout (303) have been seted up to the symmetry on the inside both sides wall of slide (301), slider (302) sliding connection in spout (303), fixedly connected with third spring (304) in spout (303), third spring (304) with slider (302) fixed connection, all seted up on wall and the bottom wall all around of shell (3) a plurality of water holes (305), feed inlet (306) have been seted up on shell (3) a lateral wall, be provided with feed plate (307) on feed inlet (306), feed plate (307) with be provided with first elastic sliding component between feed inlet (306), feed plate (307) one side fixedly connected with feed component complex linkage board (308).

3. The medical instrument rapid disinfection device according to claim 2, wherein: and an arc-shaped block (309) matched with the feeding assembly is fixedly connected to the outer wall of the other side of the feeding plate (307).

4. A medical instrument rapid disinfecting device as claimed in claim 3, characterized in that: first elasticity slip subassembly includes two first linkage blocks (310) and two first grooves (311) that reset, two first groove (311) symmetry of resetting is seted up on the both sides wall of feed inlet (306), two first linkage block (310) symmetry fixed connection is on the both sides wall of feed plate (307), first spring (312) of fixedly connected with in the first groove (311) that resets, first linkage block (310) sliding connection be in first groove (311) that resets, just first linkage block (310) with first spring (312) fixed connection.

5. A medical instrument rapid disinfecting device as claimed in claim 3, characterized in that: the feeding assembly comprises a conveying belt supporting shell (4), a push plate (401), wherein the conveying belt supporting shell (4) is assembled with a conveying belt, the conveying belt supports a plurality of supporting frames (402) fixedly connected to the bottom of the conveying belt supporting shell (4), the bottom of each supporting frame (402) is fixedly connected with a bottom plate (1), the conveying belt supports a connecting plate (403) fixedly connected to the upper portion of the conveying belt supporting shell (4), the top of the connecting plate (403) is fixedly connected with a linkage plate (308) matched lifting plate (404), the bottom of the push plate (401) is fixedly connected with a supporting table (2), and the push plate (401) is matched with an arc-shaped block (309).

6. The medical instrument rapid disinfection device according to claim 2, wherein: the charging assembly further comprises a sealing plate (5), a discharge hole (501) is formed in the bottom of the shell (3), the sealing plate (5) is connected with the discharge hole (501) through a second elastic sliding assembly, the second elastic sliding assembly comprises two second connecting blocks (502) and two second reset grooves (503), the two second reset grooves (503) are symmetrically formed in two side walls of the discharge hole (501), a second spring (504) is fixedly connected to the second reset grooves (503), the two second connecting blocks (502) are symmetrically fixed to two side walls of the sealing plate (5), the second connecting blocks (502) are slidably connected to the second reset grooves (503), the second connecting blocks (502) are fixedly connected with the second spring (504), the bottom of the other side of the sealing plate (5) is fixedly connected with a supporting block (505), the discharging assembly comprises a supporting plate (506) and a discharging port (507), the bottom of the supporting plate (506) is fixedly connected with the supporting table (2), the supporting plate (506) is matched with the supporting block (505), and the discharging port (507) is formed in the supporting table (2).

7. The medical instrument rapid disinfection device of claim 6, wherein: the sealing plate (5) is also provided with a through hole (508).

8. The medical instrument rapid disinfection device of claim 6, wherein: high temperature sterilization subassembly includes ultrasonic cleaner (6), ultrasonic cleaner (6) inner chamber bottom fixedly connected with rotating electrical machines (8), tip fixedly connected with spliced pole (601) of rotating electrical machines (8) output shaft, set up the mouth of rotation on closing plate (5), runner (602) have been seted up on the perisporium in the runner, it is connected with swivel (603) to rotate in runner (602), fixedly connected with connection pad (604) on swivel (603) internal perisporium, spline recess (605) have been seted up to connection pad (604) bottom, spliced pole (601) top fixedly connected with spline lug (606), spline lug (606) with spline recess (605) embedding is connected.

9. The medical instrument rapid disinfection device of claim 8, wherein: an elastic sleeve rod (607) is fixedly connected to the top wall of the rotating groove (602), a ball (608) is fixedly connected to the bottom of the elastic sleeve rod (607), and the bottom of the ball (608) is in abutting connection with the rotating ring (603).

10. The medical instrument rapid disinfection device according to claim 1, wherein: the stoving subassembly includes two annular walls (7), two it is regional, two to form the stoving between annular wall (7) bottom with brace table (2) fixed connection, air-out groove (701) have been seted up on brace table (2), brace table (2) bottom fixedly connected with air heater (702), it has a plurality of air outlets (703) to open in air-out groove (701), go back two shock dynamo (704) of fixedly connected with in air-out groove (701), a plurality of mounting grooves (705), every have still been seted up on the inner wall of annular wall (7) equal fixedly connected with heating pipe in mounting groove (705).

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