CN113082241A - Quick disinfection device for yin ultrasonic probe - Google Patents

Abstract

The invention discloses an integrated rapid yin ultrasonic probe disinfection device, which comprises a disinfection barrel, wherein a cold light UV (ultraviolet) germicidal lamp is installed on the inner wall of the disinfection barrel, a charging power supply, a time control switch and the cold light UV germicidal lamp are connected in series to form a closed loop, and a power supply charging port is formed at the bottom of the right side wall of the disinfection barrel; the rotating mechanism drives the disinfection mechanism to rotate; when the tail part of the yin ultrasonic probe is positioned in the clamping hole, the left semicircular plate and the right semicircular plate are closed to clamp the yin ultrasonic probe and seal the disinfection barrel; this scheme, the wet piece of cloth of chlorine dioxide through 250mg/L wipes overcast super probe earlier, carries out preliminary disinfection, is carrying out comprehensive quick no dead angle disinfection, easy operation, and it is effectual to disinfect, under the effect on antibiotic layer, has improved the holistic antibiotic effect of this device.

Description

Quick disinfection device for yin ultrasonic probe

Technical Field

The invention belongs to the technical field of medical appliances, and particularly relates to a device for quickly disinfecting a yin ultrasonic probe.

Background

The current disinfection mode of the yin ultrasound probe disinfection is to insert paper to clean the couplant, then use a disinfection wet tissue to wipe, and then use a condom to disinfect the disinfection effect of the wet tissue, which has no way to control some viruses and has poor disinfection effect. But the method for achieving the thorough disinfection effect is high in cost and long in disinfection time. The cost of the ultrasonic probe is very low, so a quick and good disinfection method is wanted to be found.

The traditional disinfection device is difficult to carry out all-round disinfection to the yin ultrasonic probe, and has certain potential safety hazard.

It is therefore desirable to redesign a device for rapid hemocatharoscope sterilization.

Disclosure of Invention

The invention aims to provide a device for quickly disinfecting a yin ultrasonic probe, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention adopts the following technical scheme:

a device for rapid yin ultrasound probe disinfection, comprising:

the disinfection device comprises a disinfection mechanism, wherein the disinfection mechanism comprises a disinfection barrel, a cold light UV (ultraviolet) germicidal lamp is mounted on the inner wall of the disinfection barrel, a charging power supply is mounted at the bottom of the disinfection barrel, a time control switch is embedded in the side wall of the disinfection barrel, the charging power supply, the time control switch and the cold light UV germicidal lamp are connected in series to form a closed loop, and a power supply charging port is formed in the bottom of the right side wall of the disinfection barrel;

the rotating mechanism drives the disinfection mechanism to rotate and comprises a motor, the motor is mounted in the middle of the top of the lower circular plate through a bolt, the lower circular plate is mounted in the middle of the top of the rectangular bottom plate, the upper end of an output shaft of the motor is connected with the middle of the bottom of the upper circular plate through a bolt, and the disinfection barrel is adhered to the middle of the top of the upper circular plate;

a sealing clamping mechanism for clamping the cathode ultrasonic probe and sealing the disinfection barrel, wherein the sealing clamping mechanism comprises a rectangular transverse plate, the rectangular transverse plate is welded below the rectangular top plate through a round connecting rod, the rectangular top plate is welded above the rectangular bottom plate through a rectangular supporting plate, a rectangular connecting rod is welded at the right side of the bottom of the rectangular transverse plate, a right semicircular plate is welded at the bottom of the rectangular connecting rod, a slide block is movably arranged at the left side of the bottom of the rectangular transverse plate, a left semicircular plate is welded at the bottom of the slide block, a rubber band is sleeved between the rectangular connecting rod and the sliding block, clamping holes are formed in the middle parts of the left semicircular plate and the right semicircular plate, when the tail of the ultrasonic probe is positioned in the clamping hole, the left semicircular plate and the right semicircular plate are closed to clamp the ultrasonic probe and seal the disinfection barrel.

By adopting the technical scheme, the yin ultrasonic probe is firstly wiped by using the mg/L chlorine dioxide wet tissue for preliminary disinfection, then the slide block is pulled leftwards, the left semicircular plate is pulled leftwards, then the tail part of the yin ultrasonic probe is placed between the left clamping hole and the right clamping hole, then the slide block is loosened, the left semicircle plate and the right semicircle plate are closed under the action of the elastic force of the rubber band, the tail part of the yin ultrasonic probe is clamped, the opening of the disinfection barrel is sealed at the same time, then the time control switch is switched on to supply power to the cold light UV germicidal lamp to disinfect the yin ultrasonic probe, and simultaneously the motor is started to drive the upper circular plate and the disinfection barrel to rotate, the yin ultrasound probe is sterilized and disinfected comprehensively, no dead angle exists, and ninety seconds after sterilization and disinfection, the operation is reversed to take out the yin ultrasonic probe, and the yin ultrasonic probe can be disinfected completely and rapidly without dead angles only by four simple operations.

Preferably, a right rubber layer is adhered to the left side wall of the right semicircular plate, and a left rubber layer is adhered to the right side wall of the left semicircular plate.

Through adopting above-mentioned technical scheme, through the elastic action on right rubber layer and left rubber layer, improved the protection effect to the overcast and super probe.

Preferably, a rectangular insertion block is integrally formed on the left side wall of the right rubber layer, and a rectangular slot for the rectangular insertion block to be inserted is formed in the right side wall of the left rubber layer.

By adopting the technical scheme, the rectangular insertion block is inserted into the rectangular slot, so that the sealing effect on the opening of the disinfection barrel is further improved.

Preferably, the top and the bottom of the left side wall of the rectangular insertion block are both provided with inclined notches.

By adopting the technical scheme, the rectangular insertion block can be conveniently inserted into the rectangular insertion slot under the action of the inclined notch.

Preferably, the slide block is a T-shaped slide block, and a T-shaped sliding groove for the slide block to slide is formed in the bottom of the rectangular transverse plate.

Through adopting above-mentioned technical scheme, slide in T shape spout through the top of T shape slider, effectual reduction slider when controlling rocking.

Preferably, the four corners of the top of the sliding block are provided with two idler wheels in a rolling mode through the mounting frame.

By adopting the technical scheme, the smooth left-right movement of the sliding block is facilitated under the action of the second roller.

Preferably, a circular cross rod is welded in the middle of the left side wall of the sliding block, and a hand-holding round rod is welded at the left end of the circular cross rod.

Through adopting above-mentioned technical scheme, conveniently stimulate the slider through holding the hand and holding the round bar.

Preferably, the left side wall of the sliding block and the right side wall of the rectangular connecting rod are both provided with clamping grooves for the rubber bands to be clamped in.

Through adopting above-mentioned technical scheme, the inside of draw-in groove is gone into to the rubber band card, has improved spacing to the rubber band.

Preferably, the bottom of going up the plectane has three rectangle branch of waiting the angle welding at least, the bottom of rectangle branch all has gyro wheel one through the mounting bracket roll installation, the confession has been seted up at the top of plectane down gyro wheel rolling gyro wheel groove.

Through adopting above-mentioned technical scheme, through the rolling effect of gyro wheel one, be favorable to going up the smooth and easy rotation of plectane.

Preferably, the four corners of the lower end face of the rectangular bottom plate are welded with supporting legs, and the lower ends of the supporting legs are provided with self-locking universal wheels in a rolling mode through mounting frames.

Through adopting above-mentioned technical scheme, through the effect of auto-lock universal wheel, make things convenient for this device's removal and location.

Preferably, the outer wall of the disinfection barrel is provided with an antibacterial layer, and the antibacterial layer is prepared by the following method:

weighing the following raw materials in parts by weight: 3-7 parts of isocyanate, 2-6 parts of silicone oil, 4-8 parts of lithium oxide, 6-11 parts of potassium oxide, 4-9 parts of strontium oxide, 2-9 parts of magnesium oxide, 5-10 parts of barium carbonate, 7-11 parts of sodium chloride, 3-7 parts of potassium dihydrogen phosphate, 5-12 parts of dipotassium hydrogen phosphate calcium carbonate, 6-13 parts of talcum powder, 7-12 parts of mica powder diethyl malonate, 8-16 parts of polyphenylene sulfide organic silicon defoamer, 10-20 parts of bentonite binder and 90-110 parts of deionized water;

s1, preparing materials: firstly, weighing the raw materials;

s2, primary mixing: adding deionized water into a digital display constant-temperature magnetic stirrer, and then sequentially pouring isocyanate, silicone oil, lithium oxide, potassium oxide, strontium oxide, magnesium oxide, barium carbonate and sodium chloride, stirring at the rotating speed of the stirrer of 155r/mi n and the temperature of 66 ℃ for 18 minutes;

s3, fusion: stopping the digital display constant-temperature magnetic stirrer, keeping the internal temperature of the digital display constant-temperature magnetic stirrer at 66 ℃, and standing for 10 minutes;

s4, mixing again: adding potassium dihydrogen phosphate, dipotassium hydrogen phosphate calcium carbonate, talcum powder and mica powder diethyl malonate into a digital display constant-temperature magnetic stirrer, and then starting the digital display constant-temperature magnetic stirrer to enable the rotating speed of the digital display constant-temperature magnetic stirrer to be 220r/mi n and the temperature to be 87 ℃ for stirring for 22 minutes;

s5, eliminating bubbles: pouring the organic silicon defoaming agent into a digital display constant-temperature magnetic stirrer, and stirring for 17 minutes;

s6, filtering: taking out the digital display constant-temperature magnetic stirrer, and filtering twice through a 100-mesh screen to obtain an antibacterial solution;

s7, spraying: then, uniformly spraying the antibacterial liquid prepared in the step S6 on the outer wall of the cleaned and dried disinfection barrel by using a high-pressure sprayer spray gun;

s8, drying: and (5) drying the disinfection barrel sprayed with the antibacterial liquid in the step (S7) in a drying box, namely preparing the antibacterial layer on the surface of the disinfection barrel.

The invention has the technical effects and advantages that:

according to the scheme, the yin ultrasonic probe is firstly wiped through the 250mg/L chlorine dioxide wet tissue for preliminary disinfection, comprehensive and rapid disinfection without dead angles is performed, the operation is simple, the disinfection effect is good, and the overall antibacterial effect of the device is improved under the action of the antibacterial layer;

left semicircle board and right semicircle board are closed, the opening to the disinfection cask is sealed when pressing from both sides tightly to the afterbody of cloudy super probe, then switch on time control switch and supply power to cold light UV bactericidal lamp and disinfect to cloudy super probe, starting motor drives simultaneously that the plectane is rotatory with the disinfection cask, surpass the probe to cloudy and carry out comprehensive sterilization, sterilization does not have the dead angle, ninety seconds back of sterilization, it can to take out cloudy super probe according to the opposite operation mentioned above, only need four simple operations just can surpass the probe to cloudy and carry out comprehensive quick no dead angle disinfection.

Drawings

FIG. 1 is a schematic view of the structure of the present invention in one state;

FIG. 2 is a schematic structural view of another embodiment of the present invention;

FIG. 3 is a front cut view of the sterilization drum of the present invention;

FIG. 4 is a schematic structural view of the rotary mechanism of the present invention;

FIG. 5 is a schematic view showing the structure of a lower circular plate according to the present invention;

FIG. 6 is an enlarged view of portion A of FIG. 1;

fig. 7 is a schematic structural diagram of the slider of the present invention.

In the figure: 1. a rectangular bottom plate; 11. a support leg; 12. a self-locking universal wheel; 2. a lower circular plate; 201. a roller groove; 21. a motor; 22. an upper circular plate; 221. a rectangular strut; 222. a first roller; 3. sterilizing the barrel; 31. a cold light UV germicidal lamp; 32. a charging power supply; 321. a power supply charging port; 33. a time control switch; 4. a rectangular top plate; 41. a rectangular support plate; 5. a rectangular transverse plate; 501. a T-shaped chute; 51. a circular connecting rod; 52. a rectangular connecting rod; 521. a right semicircular plate; 5211. a right rubber layer; 5212. a rectangular plug-in block; 52121. a bevel notch; 53. a slider; 531. a left semicircular plate; 5311. a left rubber layer; 5312. a rectangular slot; 532. a circular cross bar; 533. holding the round bar; 534. a second roller; 535. a card slot; 54. a rubber band; 55. and (6) clamping the hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to fig. 1 to 7 in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. The specific embodiments described herein are merely illustrative of the invention and do not delimit 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.

Example 1:

as shown in fig. 1, 2 and 3, the present invention provides a device for rapid disinfection of a sonotrode, comprising:

the disinfection mechanism comprises a disinfection barrel 3, a cold light UV (ultraviolet) sterilization lamp 31 is mounted on the inner wall of the disinfection barrel 3, a charging power supply 32 is mounted at the bottom of the disinfection barrel 3, a time control switch 33 is embedded in the side wall of the disinfection barrel 3, the charging power supply 32, the time control switch 33 and the cold light UV sterilization lamp 31 are connected in series to form a closed loop, and a power supply charging port 321 is formed in the bottom of the right side wall of the disinfection barrel 3;

as shown in fig. 2, 4 and 5, the rotating mechanism for driving the disinfection mechanism to rotate comprises a motor 21, the motor 21 is mounted in the middle of the top of a lower circular plate 2 through a bolt, the lower circular plate 2 is mounted in the middle of the top of a rectangular bottom plate 1, the upper end of an output shaft of the motor 21 is connected with the middle of the bottom of an upper circular plate 22 through a bolt, and a disinfection barrel 3 is adhered to the middle of the top of the upper circular plate 22;

as shown in fig. 2 and 6, the sealing clamping mechanism for clamping the yin ultrasound probe and sealing the disinfection barrel 3 comprises a rectangular transverse plate 5, the rectangular transverse plate 5 is welded below a rectangular top plate 4 through a circular connecting rod 51, the rectangular top plate 4 is welded above a rectangular bottom plate 1 through a rectangular supporting plate 41, a rectangular connecting rod 52 is welded on the right side of the bottom of the rectangular transverse plate 5, a right semicircular plate 521 is welded on the bottom of the rectangular connecting rod 52, a sliding block 53 is movably installed on the left side of the bottom of the rectangular transverse plate 5, a left semicircular plate 531 is welded on the bottom of the sliding block 53, a rubber band 54 is sleeved between the rectangular connecting rod 52 and the sliding block 53, clamping holes 55 are respectively formed in the middle parts of the left semicircular plate 531 and the right semicircular plate 521, when the tail part of the ultrasonic probe is positioned in the clamping hole 55, the left semicircular plate 531 and the right semicircular plate 521 are closed to clamp the ultrasonic probe and seal the disinfection barrel 3.

By adopting the technical scheme, the ultra-negative probe is firstly wiped by using 250mg/L of chlorine dioxide wet tissue for preliminary disinfection, then, the slider 53 is pulled leftward, the left half-round plate 531 is pulled leftward, then the tail of the yin super probe is placed between the left and right two clamping holes 55, then the slider 53 is released, under the elastic force of the rubber band 54, the left semicircular plate 531 and the right semicircular plate 521 are closed, the tail part of the yin ultrasonic probe is clamped, the opening of the disinfection barrel 3 is sealed at the same time, then the time control switch 33 is switched on to supply power to the cold light UV germicidal lamp 31 to disinfect the yin ultrasonic probe, the motor 21 is started to drive the upper circular plate 22 and the disinfection barrel 3 to rotate at the same time, the yin ultrasound probe is sterilized and disinfected comprehensively, no dead angle exists, and ninety seconds after sterilization and disinfection, the operation is reversed to take out the yin ultrasonic probe, and the yin ultrasonic probe can be disinfected completely and rapidly without dead angles only by four simple operations.

As shown in fig. 2 and 6, a right rubber layer 5211 is attached to the left side wall of the right semicircular plate 521, and a left rubber layer 5311 is attached to the right side wall of the left semicircular plate 531.

By adopting the technical scheme, the protection effect on the ultrasonic probe is improved through the elastic action of the right rubber layer 5211 and the left rubber layer 5311.

As shown in fig. 2 and 6, a rectangular plug block 5212 is integrally formed on the left sidewall of the right rubber layer 5211, and a rectangular slot 5312 for the plug block 5212 to plug into is formed on the right sidewall of the left rubber layer 5311.

By adopting the technical scheme, the rectangular insertion block 5212 is inserted into the rectangular insertion groove 5312, so that the sealing effect on the opening of the disinfection barrel 3 is further improved.

As shown in fig. 2 and 6, the top and the bottom of the left side wall of the rectangular insertion block 5212 are both provided with chamfered notches 52121.

By adopting the technical scheme, the rectangular plug block 5212 can be conveniently inserted into the rectangular slot 5312 under the action of the inclined notch 52121.

As shown in fig. 2 and 7, the sliding block 53 is a T-shaped sliding block, and a T-shaped sliding slot 501 for the sliding block 53 to slide is formed at the bottom of the rectangular transverse plate 5.

By adopting the technical scheme, the top of the T-shaped sliding block slides in the T-shaped sliding groove 501, so that the shaking of the sliding block in the left-right movement process is effectively reduced.

As shown in fig. 2 and 7, two rollers 534 are mounted at four corners of the top of the sliding block 53 through the mounting frame in a rolling manner.

By adopting the technical scheme, smooth left-right movement of the sliding block 53 is facilitated through the action of the second roller 534.

As shown in fig. 2 and 7, a circular cross bar 532 is welded to the middle of the left side wall of the slider 53, and a hand-held round bar 533 is welded to the left end of the circular cross bar 532.

By adopting the above technical scheme, the slider 53 is conveniently pulled by holding the hand-holding round rod 533.

As shown in fig. 2 and 7, the left side wall of the slider 53 and the right side wall of the rectangular connecting rod 52 are both provided with a clamping groove 535 for the rubber band 54 to be clamped into.

By adopting the above technical scheme, the rubber band 54 is clamped into the clamping groove 535, so that the limit of the rubber band 54 is improved.

As shown in fig. 4 and 5, at least three rectangular supporting rods 221 are welded at the bottom of the upper circular plate 22 at equal angles, rollers 222 are respectively installed at the bottoms of the rectangular supporting rods 221 in a rolling manner through mounting frames, and a roller groove 201 for the rollers 222 to roll is formed at the top of the lower circular plate 2.

By adopting the technical scheme, the smooth rotation of the upper circular plate 22 is facilitated through the rolling action of the first roller 222.

As shown in fig. 1, four corners of the lower end surface of the rectangular bottom plate 1 are welded with supporting legs 11, and the lower ends of the supporting legs 11 are provided with self-locking universal wheels 12 in a rolling manner through a mounting frame.

By adopting the technical scheme, the device is convenient to move and position under the action of the self-locking universal wheel 12.

Example 2

The difference from the example 1 is that the outer wall of the disinfection round barrel 3 is provided with an antibacterial layer, and the antibacterial layer is prepared by the following method:

weighing the following raw materials in parts by weight: 3 parts of isocyanate, 2 parts of silicone oil, 4 parts of lithium oxide, 6 parts of potassium oxide, 4 parts of strontium oxide, 2 parts of magnesium oxide, 5 parts of barium carbonate, 7 parts of sodium chloride, 3 parts of potassium dihydrogen phosphate, 5 parts of dipotassium hydrogen phosphate calcium carbonate, 6 parts of talcum powder, 7 parts of mica powder diethyl malonate, 8 parts of polyphenylene sulfide organic silicon defoamer, 10 parts of bentonite binder and 90 parts of deionized water;

s1, preparing materials: firstly, weighing the raw materials;

s2, primary mixing: adding deionized water into a digital display constant-temperature magnetic stirrer, and then sequentially pouring isocyanate, silicone oil, lithium oxide, potassium oxide, strontium oxide, magnesium oxide, barium carbonate and sodium chloride, stirring at the rotating speed of the stirrer of 155r/mi n and the temperature of 66 ℃ for 18 minutes;

s3, fusion: stopping the digital display constant-temperature magnetic stirrer, keeping the internal temperature of the digital display constant-temperature magnetic stirrer at 66 ℃, and standing for 10 minutes;

s4, mixing again: adding potassium dihydrogen phosphate, dipotassium hydrogen phosphate calcium carbonate, talcum powder and mica powder diethyl malonate into a digital display constant-temperature magnetic stirrer, and then starting the digital display constant-temperature magnetic stirrer to enable the rotating speed of the digital display constant-temperature magnetic stirrer to be 220r/mi n and the temperature to be 87 ℃ for stirring for 22 minutes;

s5, eliminating bubbles: pouring the organic silicon defoaming agent into a digital display constant-temperature magnetic stirrer, and stirring for 17 minutes;

s6, filtering: taking out the digital display constant-temperature magnetic stirrer, and filtering twice through a 100-mesh screen to obtain an antibacterial solution;

s7, spraying: then, uniformly spraying the antibacterial liquid prepared in the step S6 on the outer wall of the cleaned and dried disinfection barrel 3 by using a high-pressure sprayer spray gun;

s8, drying: and (5) drying the disinfection barrel 3 sprayed with the antibacterial liquid in the step (S7) in a drying box, namely preparing an antibacterial layer on the surface of the disinfection barrel 3.

Example 3

The difference from example 2 lies in the preparation of the antibacterial layer, which is specifically prepared as follows:

weighing the following raw materials in parts by weight: 7 parts of isocyanate, 6 parts of silicone oil, 8 parts of lithium oxide, 11 parts of potassium oxide, 9 parts of strontium oxide, 9 parts of magnesium oxide, 10 parts of barium carbonate, 11 parts of sodium chloride, 7 parts of potassium dihydrogen phosphate, 12 parts of dipotassium hydrogen phosphate calcium carbonate, 13 parts of talcum powder, 12 parts of mica powder diethyl malonate, 16 parts of polyphenylene sulfide organic silicon defoamer, 20 parts of bentonite binder and 110 parts of deionized water;

s1, preparing materials: firstly, weighing the raw materials;

s2, primary mixing: adding deionized water into a digital display constant-temperature magnetic stirrer, and then sequentially pouring isocyanate, silicone oil, lithium oxide, potassium oxide, strontium oxide, magnesium oxide, barium carbonate and sodium chloride, stirring at the rotating speed of the stirrer of 155r/mi n and the temperature of 66 ℃ for 18 minutes;

s3, fusion: stopping the digital display constant-temperature magnetic stirrer, keeping the internal temperature of the digital display constant-temperature magnetic stirrer at 66 ℃, and standing for 10 minutes;

s4, mixing again: adding potassium dihydrogen phosphate, dipotassium hydrogen phosphate calcium carbonate, talcum powder and mica powder diethyl malonate into a digital display constant-temperature magnetic stirrer, and then starting the digital display constant-temperature magnetic stirrer to enable the rotating speed of the digital display constant-temperature magnetic stirrer to be 220r/mi n and the temperature to be 87 ℃ for stirring for 22 minutes;

s5, eliminating bubbles: pouring the organic silicon defoaming agent into a digital display constant-temperature magnetic stirrer, and stirring for 17 minutes;

s6, filtering: taking out the digital display constant-temperature magnetic stirrer, and filtering twice through a 100-mesh screen to obtain an antibacterial solution;

s7, spraying: then, uniformly spraying the antibacterial liquid prepared in the step S6 on the outer wall of the cleaned and dried disinfection barrel 3 by using a high-pressure sprayer spray gun;

s8, drying: and (5) drying the disinfection barrel 3 sprayed with the antibacterial liquid in the step (S7) in a drying box, namely preparing an antibacterial layer on the surface of the disinfection barrel 3.

Example 4

The difference from example 2 lies in the preparation of the antibacterial layer, which is specifically prepared as follows:

weighing the following raw materials in parts by weight: 4 parts of isocyanate, 5 parts of silicone oil, 6 parts of lithium oxide, 8 parts of potassium oxide, 7 parts of strontium oxide, 6 parts of magnesium oxide, 9 parts of barium carbonate, 8 parts of sodium chloride, 5 parts of potassium dihydrogen phosphate, 10 parts of dipotassium hydrogen phosphate calcium carbonate, 11 parts of talcum powder, 8 parts of mica powder diethyl malonate, 12 parts of polyphenylene sulfide organic silicon defoamer, 15 parts of bentonite binder and 100 parts of deionized water;

s1, preparing materials: firstly, weighing the raw materials;

s2, primary mixing: adding deionized water into a digital display constant-temperature magnetic stirrer, and then sequentially pouring isocyanate, silicone oil, lithium oxide, potassium oxide, strontium oxide, magnesium oxide, barium carbonate and sodium chloride, stirring at the rotating speed of the stirrer of 155r/mi n and the temperature of 66 ℃ for 18 minutes;

s3, fusion: stopping the digital display constant-temperature magnetic stirrer, keeping the internal temperature of the digital display constant-temperature magnetic stirrer at 66 ℃, and standing for 10 minutes;

s4, mixing again: adding potassium dihydrogen phosphate, dipotassium hydrogen phosphate calcium carbonate, talcum powder and mica powder diethyl malonate into a digital display constant-temperature magnetic stirrer, and then starting the digital display constant-temperature magnetic stirrer to enable the rotating speed of the digital display constant-temperature magnetic stirrer to be 220r/mi n and the temperature to be 87 ℃ for stirring for 22 minutes;

s5, eliminating bubbles: pouring the organic silicon defoaming agent into a digital display constant-temperature magnetic stirrer, and stirring for 17 minutes;

s6, filtering: taking out the digital display constant-temperature magnetic stirrer, and filtering twice through a 100-mesh screen to obtain an antibacterial solution;

s7, spraying: then, uniformly spraying the antibacterial liquid prepared in the step S6 on the outer wall of the cleaned and dried disinfection barrel 3 by using a high-pressure sprayer spray gun;

s8, drying: and (5) drying the disinfection barrel 3 sprayed with the antibacterial liquid in the step (S7) in a drying box, namely preparing an antibacterial layer on the surface of the disinfection barrel 3.

The disinfection drums 3 of examples 1 to 4 were tested for antimicrobial properties under the same conditions in actual operation and the results are shown in the following table:

	test results after 10 days of use
		Example 1	The surface of the disinfection drum 3 shows a lot of signs of bacterial activity
Example 2	The surface of the disinfection cylinder 3 shows a small amount of activity of bacteria
		Example 3	The surface of the disinfection cylinder 3 shows a small amount of activity of bacteria
Example 4	The surface of the sterilizing drum 3 shows little evidence of bacterial activity

The comparative analysis of the test results in the above table shows that the embodiment 4 is the most preferred embodiment, and by adopting the above technical scheme, the antibacterial liquid with good antibacterial effect is prepared, the antibacterial property of the disinfection barrel 3 is effectively improved through the action of the antibacterial layer, the service life of the disinfection barrel 3 is prolonged, the antibacterial effect is good, the antibacterial liquid is cleaned, dried, sprayed and sprayed on the disinfection barrel 3, and finally dried, so that the antibacterial performance of the disinfection barrel 3 is greatly improved, the process steps for preparing the antibacterial liquid are simple and easy to implement, the prepared antibacterial liquid has moderate viscosity, is not easy to delaminate, is convenient to spray, does not generate bubbles, fully combines all components, and has good comprehensive performance, so that the antibacterial liquid can form a good coating film after being sprayed, is not easy to generate cracks, and has good film forming effect, and the prepared antibacterial liquid has good antibacterial performance, good adhesion and is not easy to fall off.

The working principle is as follows: firstly, the ultra-negative probe is wiped by using 250mg/L of chlorine dioxide wet tissue for preliminary disinfection, then, the slider 53 is pulled leftward, the left half-round plate 531 is pulled leftward, then the tail of the yin super probe is placed between the left and right two clamping holes 55, then the slider 53 is released, under the elastic force of the rubber band 54, the left semicircular plate 531 and the right semicircular plate 521 are closed, the tail part of the yin ultrasonic probe is clamped, the opening of the disinfection barrel 3 is sealed at the same time, then the time control switch 33 is switched on to supply power to the cold light UV germicidal lamp 31 to disinfect the yin ultrasonic probe, the motor 21 is started to drive the upper circular plate 22 and the disinfection barrel 3 to rotate at the same time, the yin ultrasound probe is sterilized and disinfected comprehensively, no dead angle exists, and ninety seconds after sterilization and disinfection, the operation is reversed to take out the yin ultrasonic probe, and the yin ultrasonic probe can be disinfected completely and rapidly without dead angles only by four simple operations.

To sum up, this scheme is cleaned overcast super probe through 250 mg/L's chlorine dioxide wet piece of cloth earlier, carries out preliminary disinfection, is carrying out comprehensive quick no dead angle disinfection, easy operation, and it is effectual to disinfect, under the effect on antibiotic layer, has improved the holistic antibiotic effect of this device.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (10)

1. A device for rapid disinfection of a yin ultrasound probe, comprising:

the disinfection device comprises a disinfection mechanism, wherein the disinfection mechanism comprises a disinfection barrel (3), a cold light UV (ultraviolet) sterilization lamp (31) is installed on the inner wall of the disinfection barrel (3), a charging source (32) is installed at the bottom of the disinfection barrel (3), a time control switch (33) is embedded in the side wall of the disinfection barrel (3), the charging source (32), the time control switch (33) and the cold light UV sterilization lamp (31) are connected in series to form a closed loop, and a power charging port (321) is formed in the bottom of the right side wall of the disinfection barrel (3);

the rotating mechanism drives the disinfection mechanism to rotate and comprises a motor (21), the motor (21) is installed in the middle of the top of the lower circular plate (2) through a bolt, the lower circular plate (2) is installed in the middle of the top of the rectangular bottom plate (1), the upper end of an output shaft of the motor (21) is connected with the middle of the bottom of the upper circular plate (22) through a bolt, and the disinfection barrel (3) is adhered to the middle of the top of the upper circular plate (22);

press from both sides tightly and right cloudy super probe disinfection cask (3) seal clamping mechanism who seals, seal clamping mechanism and include rectangle diaphragm (5), rectangle diaphragm (5) are welded in the below of rectangle roof (4) through circular connecting rod (51), rectangle roof (4) are welded through rectangle backup pad (41) in the top of rectangle bottom plate (1), the bottom right side welding of rectangle diaphragm (5) has rectangle connecting rod (52), the bottom welding of rectangle connecting rod (52) has right semicircle board (521), the bottom left side movable mounting of rectangle diaphragm (5) has slider (53), the bottom welding of slider (53) has left semicircle board (531), rectangle connecting rod (52) with the cover has rubber band (54) between slider (53), card hole (55) have all been seted up to left semicircle board (531) and the middle part of right semicircle board (521), when the tail part of the ultrasonic probe is positioned in the clamping hole (55), the left semicircular plate (531) and the right semicircular plate (521) are closed to clamp the ultrasonic probe and seal the disinfection barrel (3).

2. The apparatus for rapid disinfection of the inside of a body, ultrasound probe of claim 1, wherein: the left side wall of the right semicircular plate (521) is pasted with a right rubber layer (5211), and the right side wall of the left semicircular plate (531) is pasted with a left rubber layer (5311).

3. The apparatus for rapid disinfection of the inside of a body, ultrasound probe of claim 2, wherein: the left side wall of the right rubber layer (5211) is integrally formed with a rectangular insertion block (5212), and the right side wall of the left rubber layer (5311) is provided with a rectangular insertion groove (5312) for the rectangular insertion block (5212) to be inserted.

4. The apparatus for rapid disinfection of the inside of a body, super probe of claim 3, wherein: the top and the bottom of the left side wall of the rectangular insertion block (5212) are both provided with inclined notches (52121).

5. The apparatus for rapid disinfection of the inside of a body, super probe of claim 4, wherein: the sliding block (53) is a T-shaped sliding block, and a T-shaped sliding groove (501) for the sliding block (53) to slide is formed in the bottom of the rectangular transverse plate (5).

6. The apparatus for rapid disinfection of the inside of a body, super probe of claim 5, wherein: and four corners of the top of the sliding block (53) are provided with a second roller (534) in a rolling way through the mounting rack.

7. The apparatus for rapid disinfection of the inside of a body, super probe of claim 6, wherein: the middle part of the left side wall of the sliding block (53) is welded with a circular cross rod (532), and the left end of the circular cross rod (532) is welded with a hand-held round rod (533).

8. The apparatus for rapid disinfection of the inside of a body, ultrasound probe of claim 1, wherein: and clamping grooves (535) for clamping the rubber bands (54) are formed in the left side wall of the sliding block (53) and the right side wall of the rectangular connecting rod (52).

9. The apparatus for rapid disinfection of the inside of a body, ultrasound probe of claim 1, wherein: go up the bottom of plectane (22) and wait the angle welding at least and have three rectangle branch (221), the bottom of rectangle branch (221) all is installed gyro wheel one (222) through the mounting bracket roll, the confession has been seted up at the top of plectane (2) down gyro wheel groove (201) that gyro wheel one (222) are rolling.

10. The apparatus for rapid disinfection of the inside of a body, ultrasound probe of claim 1, wherein: landing legs (11) are all welded in the four corners of the lower end face of the rectangular bottom plate (1), and self-locking universal wheels (12) are installed at the lower ends of the landing legs (11) in a rolling mode through an installation frame.

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