CN108523927B

CN108523927B - Ultrasonic probe film feeding device

Info

Publication number: CN108523927B
Application number: CN201810661441.4A
Authority: CN
Inventors: 王昊; 陈玉国; 翟茜; 秦伟栋; 杨洪娜; 张建宁; 李�远; 张帆; 单悌超
Original assignee: Qilu Hospital of Shandong University
Current assignee: Qilu Hospital of Shandong University
Priority date: 2018-06-25
Filing date: 2018-06-25
Publication date: 2024-03-19
Anticipated expiration: 2038-06-25
Also published as: CN108523927A

Abstract

The invention relates to an ultrasonic probe film feeding device, which comprises a shell, a film discharging motor, an upper roller, a lower roller, a film roll and a control circuit, wherein the front end and the rear end of the shell are respectively provided with a film discharging cavity and a film covering cavity, and the film discharging cavity is provided with an upper cover, and the ultrasonic probe film feeding device is characterized in that: be provided with in the tectorial membrane chamber with ultrasonic probe matched with tectorial membrane hole, the membrane mouth has been seted up towards one side in tectorial membrane hole on the upper cover, and the diaphragm is formed by connecting the diaphragm section of equilength, and adjacent diaphragm section is connected through the intermittent line that can tear, and diaphragm section outwards one side is the face that contains the glue, has independent protection film on the face that contains the glue of diaphragm section. The ultrasonic probe film feeder can enable the outer surface of the ultrasonic probe to be wrapped with a layer of film, and then the outer surface of the film is coated with a layer of coupling agent, so that ultrasonic inspection operation can be performed; after the examination is finished, the membrane is torn off from the ultrasonic probe, and the membrane is re-coated when a new patient is examined, so that cross infection among different patients is avoided, the beneficial effect is obvious, and the ultrasonic probe is suitable for application and popularization.

Description

Ultrasonic probe film feeding device

Technical Field

The invention relates to an ultrasonic probe film feeding device, in particular to an ultrasonic probe film feeding device which can effectively avoid cross infection among different patients through film feeding.

Background

Ultrasonic examination (commonly known as ultrasound) can form a two-dimensional image of a focus, and is often applied to abdominal examination, gynecological examination, urinary system examination, body surface tumor and lesion examination, and the like. In the ultrasonic inspection process, after a layer of couplant is smeared on an ultrasonic probe, the couplant moves on the body surface of the inspected part, so that a clear image of the corresponding part is obtained. The ultrasonic probe is expensive and easy to damage, and common disinfectants such as ethanol, iodine and the like are extremely easy to damage the probe, so that the service life of the probe is greatly reduced. In clinical practice, medical staff often wipe the couplant on the ultrasonic probe with toilet paper after one patient is inspected, and the next patient is inspected after recoating a new layer of couplant without disinfection. The operation is not only tedious and time-consuming, but also easily causes cross infection among different patients, especially for severe patients or patients suffering from infectious diseases, the occurrence of nosocomial infection and epidemic of infectious diseases are easily caused, and the damage is serious.

Disclosure of Invention

The invention provides an ultrasonic probe film feeding device for overcoming the defects of the technical problems.

The invention relates to an ultrasonic probe film feeding device, which comprises a shell, a film discharging motor, an upper roller, a lower roller, a film roll and a control circuit, wherein a film discharging cavity and a film covering cavity are respectively arranged at the front end and the rear end of the shell, an upper cover capable of being opened and closed is arranged at the upper part of the film discharging cavity, the film roll is formed by winding a film, and the upper roller, the lower roller, the film roll discharging motor and the control circuit are all arranged in the film discharging cavity; the method is characterized in that: a tectorial membrane hole matched with the ultrasonic probe is arranged in the tectorial membrane cavity, and the opening of the tectorial membrane hole faces upwards; the film roll is rotationally arranged in the film outlet cavity through the film reel, the upper roller is in contact with the lower roller, a film outlet is formed in one side of the upper cover facing the film covering hole, and the film passes through a gap between the upper roller and the lower roller and then passes through the film outlet; the membrane is formed by connecting membrane segments with equal length, adjacent membrane segments are connected through intermittent lines which can be torn, one surface of each membrane segment facing outwards is a glue-containing surface which is adhered to an ultrasonic probe, an independent protective film is adhered to the glue-containing surface of each membrane segment, and an epitaxial wafer used for tearing the protective film from the membrane segment is arranged on the outer edge of each protective film.

The upper roller and the lower roller are respectively fixed on the upper shaft and the lower shaft, and two ends of the lower shaft are fixed on the inner wall of the shell through bearings; limiting frames are fixed on the inner walls of the two sides of the upper cover, the two ends of the upper shaft extend into the limiting frames and are sleeved with lantern rings, and pressure springs which always force the lantern rings to move downwards are arranged in the limiting frames.

The invention relates to an ultrasonic probe film feeding device, wherein a speed reducer, a driving gear, a transition gear, a driven gear and a rotary encoder are arranged in a film discharging cavity; the transition gear is fixed on the rotating shaft, two ends of the rotating shaft are fixed through bearings, and the rotating shaft is connected with an input shaft of the rotary encoder.

The invention relates to an ultrasonic probe film feeding device, a rotating shaft is connected to the front wall of an upper cover, a base is fixed on a shell below the rotating shaft, and the rotating shaft is hinged to the base; the lateral wall of upper cover rear end is last to be fixed with the concha card down, is fixed with on the casing outer wall of concha card below with concha card matched with fixture block.

According to the ultrasonic probe film feeding device, the detachable soft cushion block is arranged in the film covering cavity, and the film covering hole is formed in the soft cushion block; and a limiting plate for supporting the soft cushion block is arranged in the tectorial membrane cavity.

The control circuit of the ultrasonic probe film loading device is composed of a microcontroller, a liquid crystal display screen, a power switch, a film outlet key, an increment key, a decrement key, a power management module, a motor driving module and an indicator lamp, wherein the liquid crystal display screen, the power switch, the film outlet key, the increment key, the decrement key and the indicator lamp are connected with the microcontroller, and the liquid crystal display screen, the power switch, the film outlet key, the increment key, the decrement key and the indicator lamp are all arranged on the upper surface of the upper cover, so that the microcontroller controls the running state of the film outlet motor through the motor driving module.

The beneficial effects of the invention are as follows: according to the ultrasonic probe film feeding device, a film feeding motor, an upper roller, a lower roller and a control circuit are arranged in a film feeding cavity of a shell, a film on a film roll passes through a gap between the upper roller and the lower roller, and under the driving action of the film feeding motor, the upper roller and the lower roller can be driven to rotate, so that a film with the length of one film unit section is pushed out; a film covering cavity matched with the ultrasonic probe is arranged in the film covering cavity of the shell, and the pushed-out film unit section is arranged above the film covering cavity. Because the upward surface of the diaphragm unit section is the adhesive-containing surface, after the protective film on the adhesive-containing surface is removed, the ultrasonic probe and the diaphragm unit section are inserted into the film-covering hole together, so that the outer surface of the ultrasonic probe is wrapped with a layer of diaphragm, and then the outer surface of the diaphragm is coated with a layer of coupling agent, and ultrasonic inspection operation can be performed; after the examination is finished, the membrane is torn off from the ultrasonic probe, and the membrane is re-coated when a new patient is examined, so that cross infection among different patients is avoided, the beneficial effect is obvious, and the ultrasonic probe is suitable for application and popularization.

Drawings

FIG. 1 is a front view of an ultrasonic probe applicator of the present invention;

FIG. 2 is a top view of the ultrasound probe upper membrane device of the present invention;

FIG. 3 is a right side view of the ultrasonic probe applicator of the present invention;

FIG. 4 is a cross-sectional view of the ultrasonic probe applicator of the present invention;

FIG. 5 is a cross-sectional view of the ultrasonic probe applicator of the present invention;

FIG. 6 is a schematic view of a film spool fixation structure according to the present invention;

FIG. 7 is a schematic diagram of a membrane according to the present invention;

FIG. 8 is a schematic diagram of a control circuit according to the present invention;

fig. 9 is a schematic diagram of the use of the ultrasonic probe applicator of the present invention.

In the figure: 1 shell, 2 out film cavity, 3 film cavity, 4 upper cover, 5 out film motor, 6 film roll, 7 upper roller, 8 lower roller, 9 soft cushion, 10 film hole, 11 out film mouth, 12 film, 13 lower shaft, 14 upper shaft, 15 limit frame, 16 pressure spring, 17 rotating shaft, 18 base, 19 outer ear card, 20 fixture block, 21 speed reducer, 22 driving gear, 23 transition gear, 24 driven gear, 25 rotating shaft, 26 rotary encoder, 27 motor base, 28 limit plate, 29 film reel, 30 square frame, 31 limit cavity, 32 gap, 33 film unit section, 34 discontinuous line, 35 protective film, 36 epitaxial wafer, 37 microcontroller, 38 liquid crystal display, 39 power switch, 40 out film key, 41 increment key, 42 decrement key, 43 power management module, 44 motor driving module, 45 indicator lamp, 46 groove, 47 ultrasonic probe, 48 couplant, 49 collar.

Detailed Description

The invention will be further described with reference to the drawings and examples.

As shown in fig. 1 to 5, a front view, a top view, a right view and two cross-sectional views of the ultrasonic probe film feeding device of the present invention are respectively provided, the ultrasonic probe film feeding device is composed of a casing 1, an upper cover 4, a film feeding motor 5, a film roll 6, an upper roller 7, a lower roller 8 and a soft cushion 9, the casing 1 has fixing and supporting functions, the front end and the rear end in the casing 1 are respectively provided with a film feeding cavity 2 and a film feeding cavity 3, the film feeding motor 5, the film roll 6, the upper roller 7 and the lower roller 8 are all positioned in the film feeding cavity 2, the upper cover 4 is arranged at the top of the film feeding cavity 2, a film feeding hole 10 matched with the ultrasonic probe 47 is arranged in the film feeding cavity 3, and the opening of the film feeding hole 10 faces upwards. The film roll 6 is fixed on the film roll 29, and two ends of the film roll 29 are rotatably arranged on the inner wall of the shell 1; the film roll 6 is formed by winding a film sheet 12. A motor seat 27 is arranged in the film outlet cavity 2, and the film outlet motor 5 is fixed on the motor seat 27. The upper roller 7 and the lower roller 8 are horizontally arranged in contact, and the membrane 12 at the end part of the membrane roll 6 passes through a gap between the upper roller 7 and the lower roller 8 and then passes out through the membrane outlet 11; the film outlet 11 is arranged on the side wall of the upper cover 4 facing the film covering hole 10.

The upper roller 7 and the lower roller 8 are respectively arranged on an upper shaft 14 and a lower shaft 13, and two ends of the lower shaft 13 are fixed on the inner wall of the shell 1 through bearings so as to ensure the free rotation of the lower shaft 13 and the lower roller 8. The two side walls of the upper cover 4 are respectively fixed with a limit frame 15, and when the upper cover 4 is buckled on the shell 1, the two limit frames 15 are positioned right above the lower roller 8; the two ends of the upper shaft 14 penetrate through the two collars 49, and the limiting frame 15 is provided with a pressure spring 16 which always forces the collars 49 to move downwards, so that after the upper cover 4 is buckled on the shell 1, the upper roller 7 always presses the lower roller 8 under the action of the pressure spring 16, and the membrane 12 between the upper roller 7 and the lower roller 8 is also pressed.

The front end of the upper cover 4 is fixedly connected with two rotating shafts 17, a base 18 is fixed on the outer wall of the shell 1 below the two rotating shafts 17, and the rotating shafts 17 are hinged on the base 18 so as to realize the rotation of the upper cover 4 around the front end of the shell 1; the rear end of the upper cover 4 is shown with a recess 46, and a user can lift the upper cover 4 by inserting his or her hand into the recess 46. The two side walls of the rear end of the upper cover 4 are fixedly provided with outer ear cards 19, the shell 1 below the outer ear cards 19 is fixedly provided with clamping blocks 20, the lower end of the outer ear cards 19 is in an inward L-shaped hook shape, when the upper cover 4 is pressed from top to bottom, the outer ear cards 19 can be clamped on the clamping blocks 20, and at the moment, the upper roller 7 is also in a pressing state on the lower roller 8, so that the membrane 12 between the upper roller 7 and the lower roller 8 can be pushed out in the process of rotating the lower roller 8.

In order to drive the lower roller 8 to rotate by the film discharging motor 5, a speed reducer 21, a driving gear 22, a transition gear 23, a driven gear 24 and a rotary encoder 26 are further arranged in the film discharging cavity 2, an output shaft of the film discharging motor 5 is connected with an input shaft of the speed reducer 21, the driving gear 22 is fixed on the output shaft of the speed reducer 21, the driven gear 24 is fixed on the lower shaft 13, and the driving gear 22 and the driven gear 24 are meshed with the transition gear 23, so that the lower shaft 13 and the lower roller 8 can be driven to rotate under the action of the film discharging motor 5. The transition gear 23 is shown fixed on a rotation shaft 25, both ends of the rotation shaft 25 are fixed on the inner wall of the housing 1 via bearings, and an input shaft of a rotary encoder 26 is connected with the rotation shaft 25 to measure the rotation angle of the rotation shaft 25, thereby obtaining the rotation angle of the lower roller 8.

In order to fix the film roll 6, as shown in fig. 6, a schematic diagram of a fixing structure of the film roll in the invention is provided, square frames 30 are fixed on inner walls of two sides of the shell 1, a limiting cavity 31 matched with the film roll 29 is arranged inside the square frames 30, a notch 32 is arranged at one end of the square frames 30 far away from the film outlet 11, and after two ends of the film roll 29 are placed into the limiting cavity 31 through the notch 32, free rotation of the film roll 6 can be ensured, and replacement of the film roll 6 is also facilitated.

The soft cushion block 9 is fixed in the tectorial membrane cavity 3, the tectorial membrane hole 10 is opened on the soft cushion block 9, is provided with the limiting plate 28 to the support of soft cushion block 9 in the tectorial membrane cavity 3 to realize the support to soft cushion block 9. Because the size and shape of the ultrasound probe 47 of different ultrasound devices are different, the lamination of different ultrasound probes 47 can be achieved by replacing the cushion blocks 9 with lamination holes 10 of different shapes. The pushed-out film 12 is placed over the film-covering hole 10, and as shown in fig. 7, a schematic diagram of the film structure in the present invention is given, the film 12 is shown to be composed of film unit sections 33 of equal length, and adjacent film unit sections 33 are connected by intermittent lines 34 so that the adjacent film unit sections 33 can be torn by force. The upwardly facing face of the diaphragm unit segment 33 is a glue-containing face for adhesion to the ultrasound probe 47. Each of the illustrated film element segments 33 is covered with a separate protective film 35 to protect the film element segments 33 from adhesive until use. The outer edge of each protective film 25 is provided with an epitaxial wafer 36, which can be pulled off from the film unit section 33 by pinching the epitaxial wafer 36 by hand.

As shown in fig. 8, the schematic diagram of the control circuit in the present invention is composed of a microcontroller 37, a liquid crystal display 38, a power switch 39, a film-out button 40, an increment button 41, a decrement button 42, a power management module 43, a motor driving module 44, and an indicator lamp 45, wherein the liquid crystal display 38, the power switch 39, the film-out button 40, the increment button 41, the decrement button 42, and the indicator lamp 45 are all disposed on the upper surface of the upper cover 4, the power management module 43 provides electric energy for the microcontroller 37, the motor driving module 44, the indicator lamp, and the liquid crystal display 38, and the microcontroller 37 drives the film-out motor 5 to operate via the motor driving module 44. The rotary encoder 26 is connected to the input of a microcontroller 37 to obtain the rotational speed of the lower roller 8. The length of the single film outlet 12 can be adjusted through the increment key 41 and the decrement key 42, and the liquid crystal display 38 can display the film outlet length in the adjusting process.

As shown in fig. 9, a schematic diagram of the use of the membrane applicator of the ultrasonic probe of the present invention is provided, and the use process is as follows: firstly, opening the upper cover 4, putting the film roll 6 into the film outlet cavity 2, pulling out one end of the film 12 to be placed on the upper roller 8, then putting down the upper cover 4, and clamping the upper cover 4 by using the external ear card 19 and the clamping block 20; the whole equipment is electrified by pressing a power switch 39, then a film outlet key 40 is pressed, and a film outlet motor 5 drives a lower roller 8 and an upper roller 7 to send out a section of film unit section 33, so that the film unit section 33 at the forefront end is ensured to be right above a film covering hole 10, and if not, correction is carried out by hand; then, the protective film 35 on the diaphragm unit segment 33 is torn off by pinching the epitaxial wafer 36 by hand, then the ultrasonic probe 47 is aligned to the film covering hole 10, the ultrasonic probe 47 and the diaphragm unit segment 33 are inserted into the film covering hole 10 together, the diaphragm unit segment 33 can be adhered to the ultrasonic probe 47, and ultrasonic detection can be performed after the coupling agent is smeared on the diaphragm unit segment 33. After the detection is completed, the diaphragm unit segment 33 on the ultrasonic probe 47 is removed, and the diaphragm unit segment 33 is replaced with a new one, so that the next patient can be detected.

Claims

1. The ultrasonic probe film feeding device comprises a shell (1), a film discharging motor (5), an upper roller (7), a lower roller (8), a film roll (6) and a control circuit, wherein a film discharging cavity (2) and a film covering cavity (3) are respectively arranged at the front end and the rear end of the shell, an upper cover (4) capable of being opened and closed is arranged at the upper part of the film discharging cavity, the film roll is formed by winding a film (12), and the upper roller, the lower roller, the film roll film discharging motor and the control circuit are all arranged in the film discharging cavity; the method is characterized in that: a tectorial membrane hole (10) matched with the ultrasonic probe (47) is arranged in the tectorial membrane cavity, and the opening of the tectorial membrane hole faces upwards; the film roll is rotatably arranged in the film outlet cavity through a film reel (29), the upper roller is in contact with the lower roller, a film outlet (11) is formed in one side of the upper cover, which faces the film covering hole, and the film passes through a gap between the upper roller and the lower roller and then passes through the film outlet; the membrane is formed by connecting membrane segments (33) with equal length, adjacent membrane segments are connected through a tearable discontinuous line (34), one surface of each membrane segment facing outwards is a glue-containing surface adhered to an ultrasonic probe, an independent protective film (35) is adhered to the glue-containing surface of each membrane segment, and an epitaxial wafer (36) for tearing the membrane segments from the outer edges of the protective films is arranged;

the upper roller (7) and the lower roller (8) are respectively fixed on an upper shaft (14) and a lower shaft (13), and two ends of the lower shaft are fixed on the inner wall of the shell (1) through bearings; limiting frames (15) are fixed on the inner walls of the two sides of the upper cover (4), two ends of the upper shaft extend into the limiting frames and are sleeved with lantern rings (49), and pressure springs (16) which always force the lantern rings to move downwards are arranged in the limiting frames;

a speed reducer (21), a driving gear (22), a transition gear (23), a driven gear (24) and a rotary encoder (26) are arranged in the film outlet cavity (2), an output shaft of the film outlet motor (5) is connected with an input shaft of the speed reducer, the driving gear is fixed on the output shaft of the speed reducer, the driven gear is fixed on the lower shaft (13), and the driving gear, the driven gear and the transition gear are all meshed; the transition gear is fixed on a rotating shaft (25), two ends of the rotating shaft are fixed through bearings, and the rotating shaft is connected with an input shaft of the rotary encoder;

a rotating shaft (17) is connected to the front wall of the upper cover (4), a base (18) is fixed on the shell (1) below the rotating shaft, and the rotating shaft is hinged to the base; the side wall of the rear end of the upper cover is fixed with a downward outer ear card (19), and the outer wall of the shell below the outer ear card is fixed with a clamping block (20) matched with the outer ear card;

a detachable soft cushion block (9) is arranged in the tectorial membrane cavity (3), and a tectorial membrane hole (10) is formed in the soft cushion block; a limiting plate (28) for supporting the cushion block is arranged in the tectorial membrane cavity.

2. The ultrasonic probe film applicator of claim 1, wherein: the control circuit consists of a microcontroller (37), a liquid crystal display (38), a power switch (39), a film outlet key (40), an increment key (41), a decrement key (42), a power management module (43), a motor driving module (44) and an indicator lamp (45), wherein the liquid crystal display, the power switch, the film outlet key, the increment key, the decrement key and the indicator lamp are all arranged on the upper surface of the upper cover (4), and the microcontroller controls the running state of the film outlet motor (5) through the motor driving module.