CN109331251B - Clinical drainage intelligent control device - Google Patents

Abstract

Translated fromChinese

本发明涉及医疗器械领域，公开了一种临床引流智能控制装置，其包括称重式底座组件、悬撑组件、安置座组件、引流调节机构及控制器；在引流过程中称重式底座组件可向控制器反馈重量信号；安置座组件中设有用于连接引流管与引流袋的连接管；引流调节机构可在控制器控制下对连接管进行不同程度的挤压而控制连接管通断及调节积液流速，同时也可通过正向公转驱使连接管的积液向引流袋方向移动而实现负压引流。本临床引流智能控制装置，采用智能化设计，与现有常规引流组件配合使用可实现定时引流、定量引流及定速引流的自动控制，提高了引流操作的安全性与稳定性，其具有常压引流和负压引流两种引流模式，可满足大部分的临床引流所需。

The invention relates to the field of medical equipment, and discloses an intelligent control device for clinical drainage, which comprises a weighing base assembly, a suspension assembly, a seating assembly, a drainage adjustment mechanism and a controller; during the drainage process, the weighing base assembly can be Feedback weight signal to the controller; a connecting tube for connecting the drainage tube and the drainage bag is arranged in the seating assembly; the drainage adjusting mechanism can squeeze the connecting tube to different degrees under the control of the controller to control the connection and adjustment of the connecting tube At the same time, negative pressure drainage can also be realized by driving the effusion of the connecting tube to the direction of the drainage bag through the positive revolution. This clinical drainage intelligent control device adopts intelligent design and can realize automatic control of timing drainage, quantitative drainage and constant-speed drainage when used in conjunction with existing conventional drainage components, which improves the safety and stability of drainage operation. There are two drainage modes, drainage and negative pressure drainage, which can meet most of the clinical drainage needs.

Description

Clinical drainage intelligent control device

Technical Field

The invention relates to the technical field of medical instruments, in particular to an intelligent clinical drainage control device for hydrops drainage.

Background

Under normal conditions, a small amount of liquid is in the chest cavity and the abdominal cavity of a human body, so that the visceral organs in the cavity are lubricated, and if the liquid amount in the cavity is increased beyond a normal physiological range under a pathological condition, a disease such as hydrothorax and ascites can be caused. The causes of the abdominal dropsy and the pleural effusion are many and are very common clinical symptoms, and although the abdominal dropsy and the pleural effusion are only one sign, a large amount of the abdominal dropsy and the pleural effusion can cause a series of complications and are not beneficial to treatment of the causes, and even can endanger life in severe cases. Therefore, in cases with a large amount of peritoneal and pleural effusion, drainage of the effusion must be performed first in clinical treatment.

In the clinical operation process of draining a large amount of effusion, the clinical parameters such as daily drainage times, each drainage quantity, drainage speed and the like are required according to the state of illness of a case, in the actual clinical operation, the clinical parameters in the drainage process are generally realized by artificial subjective control of medical care personnel or family members of a patient, and the current artificial control mode has certain disadvantages, on one hand, the drainage process is not performed according to the expected mode of a doctor due to misunderstanding or negligence of the operating personnel and the like in oral delivery of medical advice, discomfort and injury are brought to the patient due to improper drainage, even the life of the patient is threatened, on the other hand, the real-time drainage quantity and the drainage speed are judged by artificial observation in the drainage process, the error is large, the drainage effect is difficult to guarantee, and simultaneously, the current control mode obviously increases the burden of medical staff and family members of patients.

The drainage bag is a relatively cheap medical article, is the best choice as a terminal container in clinical hydrops drainage, but can only be applicable to conventional hydrothorax drainage operation under normal pressure, but can not be applicable to negative pressure drainage, and if negative pressure drainage is carried out, a water-sealed bottle with a higher price than the drainage bag is usually needed, so that a certain economic burden is brought to a patient.

Disclosure of Invention

The invention aims to provide an intelligent clinical drainage control device which adopts an intelligent design, can realize normal-pressure drainage and negative-pressure drainage by matching with the existing drainage bag and a drainage tube, and can automatically control each drainage process according to preset drainage parameters such as drainage starting time, single drainage quantity, drainage speed and the like.

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

an intelligent control device for clinical drainage, comprising:

the weighing type base assembly is formed by sequentially matching a weighing platform, a weighing sensor and a base up and down, wherein the weighing sensor outputs a weighing signal capable of reflecting the weight of an object above the weighing platform, and a power supply module for supplying working current to the weighing sensor is arranged on the base;

the suspension support assembly comprises an upright rod with the lower end fixedly connected with the weighing platform and a suspension support beam fixedly connected with the upper end of the upright rod, a clamp used for clamping the top of the drainage bag is arranged on the suspension support beam, and the suspension support assembly is used for suspending the drainage bag right above the weighing platform;

the mounting seat assembly comprises a mounting plate and a connecting pipe, the mounting plate is supported by a telescopic rod and is positioned above the suspension support beam, the upper and lower positions of the mounting plate can be adjusted and locked, the telescopic rod is positioned at the rear side of the upright rod, and the lower end of the telescopic rod is fixedly connected with the base; the connecting pipe is made of soft elastic material, the upper end and the lower end of the connecting pipe are respectively used for connecting the drainage tube and the drainage bag, wherein the upper part of the connecting pipe is provided with a buffer bag, and the lower end of the connecting pipe is provided with a one-way output connector; the front side of the mounting plate is provided with a mounting groove for clamping and fixing the connecting pipe and a bag seat for clamping and fixing the buffer bag;

the drainage adjusting mechanism comprises a concave seat arranged at the front side of the placing plate, a section of arc-shaped side wall is arranged in the concave seat, a revolution wheel which is overlapped with the central shaft of the arc-shaped side wall is arranged in the concave seat, an arc-shaped gap which can contain the connecting pipe is formed between the arc-shaped side wall and the revolution wheel, when the connecting pipe is clamped and fixed in the placing groove, the connecting pipe passes through the arc-shaped gap, and the revolution wheel provides rotary power by a driving device; a roller which is positioned at the outer side of the revolution wheel and is parallel to the central shaft of the revolution wheel is fixed on the revolution wheel, and the roller can freely rotate around the roller shaft and can revolve along with the revolution wheel; in the process of positive revolution of the roller, after entering the arc-shaped gap each time, the roller extrudes the connecting pipe to a blocking state, and then moves the connecting pipe which is rolled in the arc-shaped gap all the time through self rotation to drive the fluid in the connecting pipe to flow backwards so as to finish primary fluid output; the position of the roller can be adjusted through forward revolution and reverse revolution, so that the connecting pipe can be extruded with the arc-shaped side wall to different degrees, and the purposes of controlling the on-off of the connecting pipe and adjusting the flow rate of accumulated liquid in the connecting pipe are achieved; when the roller is at the initial position, the roller is not contacted with the connecting pipe;

the controller is fixed on the placing plate, and a setting key and a display screen are arranged on the front side of the controller; the setting key is used for inputting a drainage mode, drainage parameters and a startup and shutdown instruction of each drainage into the controller, the drainage mode comprises normal-pressure drainage and negative-pressure drainage, the drainage parameters comprise drainage starting time, effusion weight drained in unit time in the drainage process, namely drainage speed, and effusion weight drained in single drainage, namely single drainage amount; the controller can acquire a weighing signal continuously fed back by the weighing sensor in real time, and the real-time drainage speed and the single real-time drainage quantity are calculated according to the weighing signal; the controller can adjust the revolution state of the roller by regulating and controlling the working state of the driving device, wherein the revolution state comprises the start and stop of revolution, the rotation direction, the rotation angle and the rotation speed; the controller can carry out coordination control on the revolution state of the roller based on the real-time drainage speed, the single real-time drainage quantity, the preset drainage mode and the preset drainage parameters, so as to realize the timed drainage, the constant-speed drainage and the quantitative drainage; after receiving a shutdown instruction, the controller firstly adjusts the roller to an initial position and then executes shutdown; the display screen is used for displaying the data information held by the palm in the controller;

and the power supply assembly is arranged on the mounting plate, consists of a storage battery and a plurality of voltage transformation modules and is used for providing working current for the driving device and the controller.

The using method and the working principle of the clinical drainage intelligent control device are as follows:

the clinical drainage intelligent control device is placed on the ground or a platform lower than a patient, a drainage bag is fixed on the lower side of a suspension beam through a clamp, and the drainage bag is suspended above a weighing table; the buffer bag is clamped and fixed in the bag seat, the connecting pipe is clamped and fixed in the placing groove, the connecting pipe is ensured to penetrate through an arc-shaped gap formed between the arc-shaped side wall and the revolution wheel, the lower end of the connecting pipe is connected with the drainage bag, the height of the placing plate is adjusted, the part, located between the placing groove and the drainage bag, of the connecting pipe is in a natural stretching state, the tail end of the drainage pipe is connected with the upper end of the connecting pipe, the front end of the drainage pipe is communicated with and fixed with a cavity to be drained of a patient according to conventional drainage operation, the clinical drainage intelligent control device is adjusted to a starting state through a set key, a drainage mode and drainage parameters are preset in the controller through the set key according to clinical needs, and then early-stage preparation work of the drainage operation is completed; afterwards, the controller can regulate and control the revolution state of the roller based on the real-time drainage speed, the single real-time drainage quantity, the preset drainage mode and the drainage parameters, so that the timed drainage, the constant-speed drainage and the quantitative drainage are realized.

Furthermore, the one-way output joint comprises a main body, the upper end of the main body is provided with an input port connected with the lower end of the connecting pipe, and the lower end of the main body is provided with an output port connected with the drainage bag; a column cavity is arranged in the main body, a liquid inlet hole is formed in the bottom of the column cavity, a liquid discharge hole is formed in the side wall of the middle lower part, and a vent hole communicated with the atmosphere is formed in the upper end of the column cavity; the input port is communicated with the liquid inlet hole through a flow channel, and the liquid outlet hole is communicated with the output port through a flow channel; a floating ball with a smooth surface is arranged in the valve cavity, a gap is formed between the floating ball and the side wall of the column cavity, so that the liquid discharge hole is always communicated with the vent hole, and the floating ball can be in sealing fit with the liquid inlet hole after sinking to the bottom of the column cavity; when the column cavity is internally provided with the accumulated liquid, the floating ball floats on the upper surface of the accumulated liquid in the column cavity to communicate the liquid inlet hole, the liquid outlet hole and the air vent, and when the accumulated liquid does not exist in the column cavity, the floating ball sinks by gravity to plug the liquid inlet hole.

This clinical drainage intelligent control device has following beneficial effect:

the drainage device adopts an intelligent design, can be used by being matched with the conventional drainage component clinically, can be compatible with two working modes of normal-pressure drainage and negative-pressure drainage, can automatically control the whole drainage operation according to preset drainage parameters after presetting drainage parameters such as initial time of each drainage, single drainage quantity, drainage speed of each drainage and the like, realizes automatic intelligent drainage with timing, quantification and constant speed, greatly lightens the work burden of medical workers because human interference is not needed in the drainage process, avoids the situation that the drainage cannot be carried out according to an expected mode due to negligence or improper operation, improves the safety and stability of the clinical liquid drainage operation, and fully ensures the drainage effect; the intelligent control device for clinical drainage is used for controlling the drainage quantity and the drainage speed based on the coordination of the sensing device, the controller and the driving device, and compared with manual observation and control in the prior art, the intelligent control device for clinical drainage is more accurate in operation and control, so that the drainage effect is further ensured; the connecting pipe is used as a middle channel of the drainage pipe and the drainage bag and is a passage which is necessary for effusion in the drainage process, the regulation of the drainage speed and the generation of the drainage negative pressure of the clinical drainage intelligent control device are realized by extruding the connecting pipe based on the drainage regulating mechanism, the sealing performance of an effusion drainage pipeline is ensured, the isolation of the effusion from other parts is ensured, the safety and the sanitation are realized, the manufacturing cost of the connecting pipe is relatively low, the clinical drainage intelligent control device is suitable for one-time use, and the economical efficiency of the clinical drainage intelligent control device in clinical application is ensured; meanwhile, the drainage adjusting mechanism adopts a scientific and ingenious structural design, has multiple functions of controlling the on-off state of the connecting pipe, adjusting the flow rate of accumulated liquid, generating negative pressure in negative pressure drainage and the like, and exerts the utilization rate of components to the maximum, so that the structure of the clinical drainage intelligent control device tends to be more compact; in conclusion, the clinical drainage intelligent control device is very convenient to use, very flexible to apply, very simple to operate, compact in structure, ingenious in design, accurate in metering, low in manufacturing cost and use cost and extremely suitable for being popularized and used in medical units, and the main body component can be recycled.

Drawings

Fig. 1 is one of the overall structural schematic diagrams of the clinical drainage intelligent control device inembodiment 1.

Fig. 2 is a second schematic view of the overall structure of the intelligent control device for clinical drainage inembodiment 1.

Fig. 3 is a partially broken away schematic view of the weighing base assembly of example 1.

Fig. 4 is a schematic structural diagram of the mount assembly, the drainage adjustment mechanism, and the controller inembodiment 1.

Fig. 5 is a schematic view of the connection pipe and the drainage adjusting mechanism when the roller is in the initial position inembodiment 1.

Fig. 6 is a schematic view of a state of the clinical drainage intelligent control device inembodiment 1 after being combined with a drainage bag and a drainage tube.

Fig. 7 is an intelligent control schematic diagram of the clinical drainage intelligent control device inembodiment 1.

Fig. 8 is a working principle diagram of the drainage adjusting mechanism in the normal pressure drainage mode inembodiment 1.

Fig. 9 is a working principle diagram of the drainage adjusting mechanism in the negative pressure drainage mode in theembodiment 1.

Fig. 10 is a schematic structural view of a connection pipe inembodiment 2.

Fig. 11 is a schematic view of a fitting structure of a roll and a runner inembodiment 3.

Fig. 12 is a schematic structural view of a drainage adjustment mechanism according toembodiment 4 after further modification.

Fig. 13 is a schematic view illustrating the connection between the signal line and the retractable rod inembodiment 5.

FIG. 14 is a schematic structural view of the weighing base assembly of example 6.

Fig. 15 is a schematic structural view of the intelligent control device for clinical drainage in an extended state inembodiment 7.

Fig. 16 is a schematic structural diagram of the intelligent control device for clinical drainage in a contracted state inembodiment 7.

Fig. 17 is a state diagram of the connection pipe inembodiment 8 for fluid output and the fluid is accumulated.

Fig. 18 is a state diagram of the floating ball stopping the backflow of the accumulated liquid after the fluid output of the connection tube inembodiment 8 is completed.

Fig. 19 is a state diagram of the connection pipe in theembodiment 8 for outputting the fluid and the fluid is air.

In the figure, 1, a base, 2, a weighing platform, 3, a telescopic rod, 4, an upright rod, 5, a clamp, 6, a suspension beam, 7, an arc-shaped gap, 8, a placing plate, 9, a revolving wheel, 10, a driving device, 11, a power supply assembly, 12, an arc-shaped side wall, 13, a placing groove, 14, a bag seat, 15, a concave seat, 16, a display screen, 17, a setting key, 18, a roller, 19, a controller, 20, a positioning bolt, 21, a weighing sensor, 22, an indicator light, 23, an alarm, 24, a connecting pipe, 25, a buffer bag, 26, a drainage pipe, 27, a drainage bag, 28, a curve section, 29, a roller fork, 30, a tension spring, 31, a radial hole, 32, a tension pin, 33, a manual rotary handle, 34, a signal wire, 35, a telescopic section, 36, a ground foot, 37, a bolt, 38, an adjusting knob, 39, a bubble type level gauge, 40, an arc part, 41, a crank arm, 42 and a one-way output joint, 43. the device comprises anoutput port 44, aliquid inlet hole 45, amain body 46, afloating ball 47, acolumn cavity 48, aninput port 49, avent hole 50 and a liquid discharge hole.

Detailed Description

Example 1

Referring to fig. 1, 2 and 6, the clinical drainage intelligent control device disclosed in this embodiment is composed of several parts, namely a weighing type base assembly, a suspension support assembly, a placement seat assembly, a drainage adjustment mechanism, acontroller 19 and apower supply assembly 10;

as shown in fig. 1 and 3, the weighing type base assembly is formed by sequentially matching aweighing platform 2, aweighing sensor 21 and abase 1 up and down, theweighing sensor 21 outputs a weighing signal capable of reflecting the weight of an object above theweighing platform 2, and thebase 1 is provided with a power supply module for supplying working current to theweighing sensor 21; for providing support for the suspension and seat assemblies on the one hand and for feeding back a weight signal to thecontroller 19 on the other hand;

as shown in fig. 1, 2 and 6, the suspension support assembly comprises anupright rod 4 and asuspension support beam 6, the lower end of theupright rod 4 is fixedly connected with theweighing platform 2, the middle part of thesuspension support beam 6 is fixedly connected with the upper end of theupright rod 4, and thesuspension support beam 6 is provided with aclamp 5 for clamping the top of thedrainage bag 27; the suspension support assembly is used for suspending thedrainage bag 27 right above theweighing platform 2 in a suspension manner, so that the weight of thedrainage bag 27 and accumulated liquid in the drainage bag tends to be totally and indirectly fed back to theweighing sensor 21;

as shown in fig. 1, 2, 5 and 6, the seat assembly includes aseat plate 8 and a connectingpipe 24; theplacing plate 8 is supported by atelescopic rod 3 and is positioned above thesuspension beam 6, the upper and lower positions of the placing plate can be adjusted and locked, thetelescopic rod 3 is positioned at the rear side of theupright rod 4, and the lower end of the telescopic rod is fixedly connected with thebase 1; theconnecting tube 24 is made of soft elastic material, so as to ensure good elastic deformation performance, the upper end and the lower end of theconnecting tube 24 are respectively used for connecting thedrainage tube 26 and thedrainage bag 27, wherein the upper part is provided with abuffer bag 25, the lower end is provided with a one-way output joint 42, and the one-way output joint 42 only allows effusion or air in the connectingtube 24 to flow towards thedrainage bag 27 as the name suggests; the front side of themounting plate 8 is provided with amounting groove 13 for clamping and fixing the connectingpipe 24 and abag seat 14 for clamping and fixing thebuffer bag 25;

as shown in fig. 1, 4, 5, 8, and 9, the drainage adjusting mechanism includes arecess 15 provided at the front side of theplacement plate 8, a section of arc-shaped side wall, called as an arc-shaped side wall 12, is provided in therecess 15, a revolvingwheel 9 overlapping with the central axis of the arc-shaped side wall 12 is provided in therecess 15, an arc-shaped gap 7 capable of accommodating a connectingpipe 24 is formed between the arc-shaped side wall 12 and the revolvingwheel 9, and the connectingpipe 24 passes through the arc-shaped gap 7 after being clamped in theplacement groove 13; therevolution wheel 9 is provided with rotary power by adriving device 10 fixed on thesetting plate 8; aroller 18 which is positioned at the outer side of therevolution wheel 9 and is parallel to the central axis of the revolution wheel is fixed on therevolution wheel 9, and theroller 18 can freely rotate around the roller shaft and can revolve with therevolution wheel 9; referring to fig. 9, in the continuous forward revolution process of theroller 18, after entering thearc gap 7 each time, the roller extrudes the connectingpipe 24 to a blocking state, and then moves the connectingpipe 24 rolling thearc gap 7 all the time by self rotation to drive the fluid in the connectingpipe 24 to flow backwards, so as to complete one-time fluid output, the fluid is accumulated fluid or air in the connectingpipe 24, and when the rolled connectingpipe 24 returns to its original shape by its own elasticity, the front end of the connectingpipe 24 will generate negative pressure to drive the accumulated fluid in the human body to enter the connectingpipe 24, and when theroller 18 leaves thearc gap 7, the connectingpipe 24 cannot output the fluid because of not being continuously extruded, but the one-way output joint 42 can effectively prevent the fluid in the connectingpipe 24 from flowing backwards, that is, when theroller 18 continues to perform the forward revolution, the connectingpipe 24 sequentially outputs the fluid, thereby achieving negative pressure drainage, the average drainage speed of the effusion drainage is determined by the positive revolution speed of theroller 18; referring to fig. 8, when normal pressure drainage is performed, theroller 18 can adjust the position through forward revolution and reverse revolution, so that the connectingpipe 24 can be extruded to different degrees with the arc-shaped side wall 12, and the purposes of controlling the on-off of the connectingpipe 24 and adjusting the flow rate of accumulated liquid in the connectingpipe 24 are achieved; referring to fig. 5, when theroll 18 is in the initial position, it is located at the other side opposite to the arc-shaped side wall 12 so as not to contact theconnection pipe 24, and in this state, theconnection pipe 24 can be smoothly combined with and separated from the drainage regulating mechanism;

as shown in fig. 1, 5, 6 and 7, thecontroller 19 is fixed on theinstallation plate 8, a control program is pre-installed in the controller, and asetting key 17 and adisplay screen 16 are arranged on the front side of the controller; thesetting key 17 is used for inputting a drainage mode, drainage parameters and a startup and shutdown instruction of each drainage into thecontroller 19, the drainage mode comprises normal-pressure drainage and negative-pressure drainage, the drainage parameters comprise drainage starting time, effusion weight drained in unit time in the drainage process, namely drainage speed, and effusion weight drained in single drainage, namely single drainage amount; thecontroller 19 can obtain a weighing signal continuously fed back by theweighing sensor 21 in real time, and calculate the real-time drainage speed and the single real-time drainage quantity according to the weighing signal; thecontroller 19 can adjust the revolution state of theroller 18 by regulating and controlling the working state of thedriving device 10, wherein the revolution state comprises the start and stop of revolution, the rotation direction, the rotation angle and the rotation speed; thecontroller 19 can perform coordination control on the revolution state of theroller 18 based on the real-time drainage speed, the single real-time drainage quantity, and a preset drainage mode and drainage parameters, so as to realize timing drainage, constant-speed drainage and quantitative drainage; after receiving the shutdown instruction, thecontroller 19 firstly adjusts theroller 18 to the initial position and then performs shutdown, thereby ensuring that the connectingpipe 24 can be smoothly separated from the drainage adjusting mechanism and theaccommodating groove 13 after drainage is finished, and ensuring that the connectingpipe 24 can be smoothly installed in the next drainage operation; thedisplay screen 16 is used for displaying data information grasped in thecontroller 19, including information such as real-time drainage speed, single real-time drainage quantity, set drainage mode and drainage parameters, and also displaying drainage states indirectly obtained based on the information, such as working states of drainage in progress, drainage pause, drainage end and the like;

referring to fig. 1 and 4, thepower module 10 is mounted on themounting plate 8, and is composed of a storage battery and a plurality of voltage transformation modules, and is used for providing operating current for thedriving device 10 and thecontroller 19, and the structure of thepower module 10 and the connection relationship with other elements are not described in detail since they can be easily implemented by the prior art.

The using method and the working principle of the clinical drainage intelligent control device are as follows:

referring to fig. 6 and 7, the clinical drainage intelligent control device is placed on the ground or a platform lower than a patient, thedrainage bag 27 is fixed on the lower side of thesuspension beam 6 through theclamp 5, at the moment, thedrainage bag 27 is suspended above theweighing platform 2, and the fixing mode of thedrainage bag 27 also provides favorable conditions for the full extension of the drainage bag in the drainage process; the method comprises the steps of clamping abuffer bag 25 in abag seat 14, clamping a connectingpipe 24 in aplacing groove 13, ensuring that the connectingpipe 24 penetrates through an arc-shaped gap 7 formed between an arc-shaped side wall 12 and a revolvingwheel 9, connecting a one-way output connector 42 at the lower end of the connectingpipe 24 with adrainage bag 27, adjusting the height of aplacing plate 8 to enable the part of the connectingpipe 24 between the placinggroove 13 and thedrainage bag 27 to be in a natural extension state, connecting the tail end of adrainage pipe 26 with the upper end of the connectingpipe 24, communicating and fixing the front end of thedrainage pipe 26 with a chamber to be drained of a patient according to conventional drainage operation, adjusting a clinical drainage intelligent control device to a starting state through asetting key 17, presetting a drainage mode and drainage parameters in acontroller 19 by using thesetting key 17 according to clinical requirements, and finishing early preparation work of the drainage operation; thereafter, thecontroller 19 can regulate and control the revolution state of theroller 18 based on the real-time drainage speed, the single real-time drainage quantity, the preset drainage mode and the drainage parameters, and the specific regulation and control mode is as follows:

(1) referring to fig. 7, 8, and 9, in the normal pressure drainage mode;

a. during primary drainage, thecontroller 19 enables theroller 18 to perform positive revolution according to a preset initial drainage starting time, trigger pressure is provided for a siphon effect based on normal-pressure drainage, when a weighing signal changes, it is indicated that partial accumulated liquid enters thedrainage bag 27, at the moment, theroller 18 continues to perform positive revolution, and the primary drainage is started until the connectingpipe 24 is in a conducting state; in each drainage, thecontroller 19 rotates theroller 18 to adjust the position according to the preset initial time of each drainage, so that the connectingpipe 24 is kept in a conducting state, accumulated liquid is stored in adrainage pipe 26 path formed by thedrainage pipe 26 and the connectingpipe 24, each drainage can be realized by means of a siphon effect, and the timed drainage is realized;

b. in the drainage process, thecontroller 19 enables theroller 18 to perform corresponding forward revolution or reverse revolution according to the real-time drainage speed to adjust the extrusion degree of theroller 18 on the connectingpipe 24, so that the effusion speed in the connectingpipe 24 is increased or reduced, and finally the real-time drainage speed is approximately equal to the preset drainage speed, namely constant-speed drainage is realized;

c. in the drainage process, thecontroller 19 calculates the single real-time drainage amount from the initial drainage to the current drainage in real time, when the single real-time drainage amount reaches the preset single drainage amount, thecontroller 19 drives theroller 18 to revolve to adjust the position, so that the connectingpipe 24 is extruded to a blocking state, and at the moment, the quantitative drainage is realized after the drainage is finished;

(2) referring to fig. 7 and 9, in the negative pressure drainage mode,

a. as shown in fig. 7 and 9, according to the preset drainage starting time, thecontroller 19 drives theroller 18 to perform positive revolution, and drives the effusion to flow into thedrainage bag 27 from the human body, namely, the timed drainage is realized;

b. in the drainage process, thecontroller 19 adjusts the rotation speed of the forward revolution of theroller 18 according to the real-time drainage speed, so that the frequency of outputting the accumulated liquid by the connectingpipe 24 is increased or reduced, the average flow speed of the accumulated liquid is indirectly increased or reduced, and finally the real-time drainage speed is approximately equal to the preset drainage speed, namely constant-speed drainage is realized;

c. in the drainage process, thecontroller 19 calculates the single real-time drainage amount of the initial drainage to the current time, when the single real-time drainage amount reaches the preset single drainage amount, thecontroller 19 enables theroller 18 to stop revolution under the condition that the connectingpipe 24 is extruded to the blocking state, and at the moment, the drainage is finished and the connectingpipe 24 keeps the stopping state, so that the quantitative drainage is realized.

Referring to fig. 9, in the clinical drainage intelligent control device, the revolution direction of theroller 18 is divided into a forward revolution and a reverse revolution, wherein the forward and reverse are relative only, and only one rotation direction set for convenience of description is referred to, because the relative position of the connectingpipe 24 and theroller 18 is not limited to a specific one during implementation, the actual revolution direction required by theroller 18 to drive the accumulated liquid in the connectingpipe 24 to flow from the human body to thedrainage bag 27 is influenced by the relative position of the connectingpipe 24 and theroller 18, therefore, in the foregoing description, the rotation direction which can drive the accumulated liquid in the connectingpipe 24 to flow from the human body to thedrainage bag 27 during the revolution of theroller 18 is defined as the forward direction, and vice versa.

Referring to fig. 1, 3 and 7, in the clinical drainage intelligent control device, a weighing base assembly is used for directly or indirectly providing support for other parts on one hand, and feeding back a weighing signal of the weight of an object above a weighingplatform 2 to acontroller 19 through a weighingsensor 21 on the other hand; based on the technical purpose, the specific matching structure of the weighingplatform 2, the weighingsensor 21 and thebase 1 can be implemented by referring to the structure of the existing electronic scale, specifically, the weighingplatform 2 is limited by thebase 1 and has a certain up-and-down floating stroke, but the weighing platform and the base cannot be completely separated, the weighingsensor 21 is arranged between the weighingplatform 2 and thebase 1, the weighingsensor 21 provides support for the weighingplatform 2 in the vertical direction, and a weighing signal output by the weighingsensor 21 changes along with the pressure applied to the weighingplatform 2 by the weighing platform.

Referring to fig. 2, in the clinical drainage intelligent control device, the settingplate 8 can be adjusted to be in the up-down position and locked based on the extension and retraction of thetelescopic rod 3, based on the technical requirement, thetelescopic rod 3 adopts the existing plug-in type structure, and meanwhile, thetelescopic rod 3 is provided with the positioning bolt 3720 capable of locking the length of the telescopic rod, so that the technical purpose can be achieved.

Referring to fig. 7, in the clinical drainage intelligent control device, thecontroller 19 can obtain the weighing signal continuously fed back by the weighingsensor 21 in real time, and the technical features of the prior art are that a wireless transmission module capable of performing data transmission can be arranged between the weighingsensor 21 and thecontroller 19, or a circuit for transmitting data can be arranged between the weighingsensor 21 and thecontroller 19.

Referring to fig. 6 and 8, in the clinical drainage intelligent control device, the connectingpipe 24 can be combined in the placinggroove 13; on one hand, the connectingpipe 24 fixed by the placinggroove 13 plays a good role in isolating thedrainage pipe 26 from thedrainage bag 27, so that external force interference caused by unstable factors such as shaking of thedrainage pipe 26 to thedrainage bag 27 is effectively avoided, and the data accuracy and stability of the real-time drainage speed and the single real-time drainage quantity are improved; on the other hand, thearrangement groove 13 guides the trend of the connectingpipe 24, and the matching stability of the connectingpipe 24 and the drainage adjusting mechanism is ensured.

Referring to fig. 6 and 7, in the clinical drainage intelligent control device, in the use process, the weight of the drainage bag 27 and the effusion inside the drainage bag is almost completely supported by the suspension beam 6, that is, almost the whole weight of the drainage bag 27 and the effusion inside the drainage bag is finally applied to the weighing sensor 21, the weights of the weighing platform 2, the upright stanchion 4, the suspension beam 6 and the drainage bag 27 after installation are constant and unchangeable in the drainage process, so that the change of the weighing signal output by the weighing sensor 21 is almost completely caused by the increase of the effusion in the drainage bag 27, so that the controller 19 can calculate the weight of the effusion in the drainage bag 27 in unit time according to the change state of the weighing signal in the drainage process, that is, the real-time drainage speed, and can calculate the weight of the effusion in the drainage bag 27 in the period from the beginning of the drainage to the present time, that is, the single real-time drainage quantity, therefore, the controller 19 can calculate the corresponding real-time drainage speed and single real-time drainage quantity based on the change state of the real-time weighing signal, which can be realized by adopting the prior art;

if the drainage bag is not placeable, the upper end of thedrainage bag 27 is fixedly connected with the connectingpipe 24 in the drainage process, the connectingpipe 24 inevitably generates certain acting force on thedrainage bag 27, and the acting force can be changed along with the deformation of thedrainage bag 27, so that certain influence is brought to the data accuracy of the real-time drainage speed and the single real-time drainage quantity; however, in the clinical drainage intelligent control device, the placingplate 8 is supported by thetelescopic rod 3, the height of the placing plate can be adjusted and locked, and before clinical drainage is implemented, the part of the connectingpipe 24, which is positioned between the placinggroove 13 and thedrainage bag 27, is in a natural extension state by adjusting the height of the placingplate 8, so that the acting force of the connectingpipe 24 on thedrainage bag 27 can be reduced, and the influence on the data accuracy of the real-time drainage speed and the single real-time drainage quantity is reduced.

Referring to fig. 6 and 9, in the clinical drainage intelligent control device, the lower end of the connecting pipe 24 adopts the one-way output joint 42, when the roller 18 drives the connecting pipe 24 to output fluid, the accumulated fluid or air in the connecting pipe 24 can be output through the one-way output joint 42, and when the connecting pipe 24 does not output fluid, the one-way output joint 42 can prevent the accumulated fluid or air in the connecting pipe 24 from flowing back, so the one-way output joint 42 is a necessary component, and plays a necessary role in the negative pressure drainage process and the initial stage of normal pressure drainage; based on the arrangement of the one-way output joint 42, the one-way output joint can be realized by adopting the prior art, for example, the one-way output joint 42 can adopt a ball valve type or a duckbill one-way valve commonly used in the prior fluid conveying field; meanwhile, because the connecting pipe 24 is the only connecting channel between the drainage pipe 26 and the drainage bag 27, the normal pressure drainage is performed based on the siphon effect, and the pressure difference between the head and the tail of the drainage pipeline is generally limited by the relative height, and considering this factor, the working pressure of the one-way output joint 42 should be as small as possible, so as to reduce the resistance to the effusion flow in the normal pressure drainage.

Referring to fig. 9, when the clinical drainage intelligent control device is used clinically, based on the structural characteristics of the drainage adjustment mechanism, in the negative pressure drainage mode, when theroller 18 revolves around in the positive direction, theconnection pipe 24 outputs fluid once and a fluid stagnation stage exists at the same time, that is, the fluid output in theconnection pipe 24 is performed in a pulse mode, and thebuffer bag 25 is arranged at the middle upper part of theconnection pipe 24, and can store and accumulate the negative pressure generated in theconnection pipe 24, provide a relatively smooth and uniform negative pressure for the lower end of thedrainage pipe 26, weaken the pulse effect in thedrainage pipe 26, make the flow rate of the effusion at the upper part of thedrainage pipe 26 tend to be uniform in the drainage process, and avoid discomfort for the patient.

Referring to fig. 6, 7 and 9, when the intelligent control device for clinical drainage is used clinically, in a negative pressure drainage mode, thecontroller 19 can adjust the rotation speed of theroller 18 in positive revolution according to the real-time drainage speed to realize constant-speed drainage; however, the problem is that in the negative pressure drainage mode, the accumulated liquid enters thedrainage bag 27 in a pulse mode, so that the unit time based on which thecontroller 19 calculates the real-time drainage speed through the weighing signal is not too short, and at least the unit time is longer than the time required by one revolution of theroller 18;

meanwhile, the average drainage speed can be calculated by the weight of the drained accumulated liquid in a longer period of time to serve as the real-time drainage speed, and if thecontroller 19 calculates the real-time drainage speed by adopting the method, the drainage effect is not obviously influenced.

Referring to fig. 7, 8 and 9, in the clinical drainage intelligent control device, thecontroller 19 can adjust the revolution state of theroller 18 by adjusting the working state of the drivingdevice 10, the revolution state includes the start and stop of revolution, the rotation direction, the rotation angle and the rotation speed, for this purpose, the drivingdevice 10 can be composed of a servo motor and a speed reducer, and as for the existing electromechanical control technology, thecontroller 19 is adopted to adjust the working state of the servo motor, so that the technical requirements are not difficult to achieve.

Referring to fig. 7, in the clinical drainage intelligent control device, thedisplay screen 16 can display data information and corresponding drainage state grasped in thecontroller 19, and an operator can know the operation condition and the drainage state of the clinical drainage intelligent control device through thedisplay screen 16, but the information transmission of thedisplay screen 16 is limited, and the operator must obtain the information through an active observation mode; for this purpose, as shown in fig. 4, analarm 23 and anindicator light 22 may be installed on thecontroller 19, and both of them can express the working state of the clinical drainage intelligent control device, such as the on-off state, the electric quantity shortage, the drainage start, the drainage end, the drainage pause, etc., through the sound and light signals based on the data information grasped in thecontroller 19; therefore, thecontroller 19 can more timely and effectively transmit the information of the running state, the key drainage state and the like of the clinical drainage intelligent control device to the operator.

The intelligent control device for clinical drainage adopts an intelligent design, and can realize functions of timed drainage, constant-speed drainage, quantitative drainage and the like according to preset drainage parameters in the clinical drainage operation, so that the aim of intelligent automatic drainage control is fulfilled, the labor burden is saved, and the safety, stability and accuracy of the drainage operation are improved; the clinical drainage intelligent control device is matched with theconventional drainage bag 27 and thedrainage tube 26 for use, and the existing structures of thedrainage bag 27 and thedrainage tube 26 are not required to be changed, so that the clinical drainage intelligent control device is easier to popularize and use; this clinical drainage intelligent control device has two kinds of mode of ordinary pressure drainage and negative pressure drainage, can satisfy different drainage operation demands such as pleural effusion drainage, abdominal cavity hydrops drainage, and the suitability is stronger, and application scope is wider, has great clinical spreading value.

Example 2

Referring to fig. 6, in the clinical drainage intelligent control device disclosed inembodiment 1, during the drainage process, theconnection tube 24 will generate a certain acting force on thedrainage bag 27, although the acting force on thedrainage bag 27 caused by theconnection tube 24 can be reduced by adjusting the placingplate 8 to make the portion of theconnection tube 24 between the placinggroove 13 and thedrainage bag 27 in a natural extending state, there is still a certain unavoidable influence on the data accuracy of the real-time drainage speed and the single real-time drainage volume, and in order to further reduce this influence, this embodiment further has the following improvements on theconnection tube 24, and the specific structure is:

referring to fig. 10, the middle-lower section of the connectingtube 24 is prefabricated with acurved section 28 which is easy to deform telescopically, and thecurved section 28 is in a spiral curve shape; therefore, after the connectingpipe 24 is connected with thedrainage bag 27, the height of the placingplate 8 is adjusted to enable thecurve section 28 to be in a natural extension state, and in the drainage process, even if thecurve section 28 deforms or moves downwards along with the increase of the effusion in thedrainage bag 27, the acting force on thedrainage bag 27 cannot change obviously, so that the data accuracy of the real-time drainage speed and the single real-time drainage quantity calculated by thecontroller 19 is ensured.

Example 3

Referring to fig. 9, in the clinical drainage intelligent control device disclosed inembodiment 1, when theroller 18 revolves forward and enters the arc-shapedgap 7, it squeezes theconnection pipe 24 to the blocking state, and then moves theconnection pipe 24 that is rolling from the beginning to the end in the arc-shapedgap 7 to drive the accumulated liquid in theconnection pipe 24 to flow backward, in this process, the pressure applied by theroller 18 to theconnection pipe 24 should be appropriate, on one hand, theconnection pipe 24 should be squeezed as much as possible to the arc-shapedside wall 12, so as to improve the fluid output efficiency, and on the other hand, theroller 18 should be prevented from causing excessive pressure to theconnection pipe 24, so as to avoid theconnection pipe 24 from being damaged, in order to ensure the balance of the above two effects, the matching manner of theroller 18 and therevolution wheel 9 is further improved, and the specific implementation structure is:

referring to fig. 11, the rollingroller 18 is fixed in theroller fork 29 through a rotating shaft, aradial hole 31 with a square cross section is formed inwards on the side wall of the revolvingwheel 9, atensioning pin 32 which is in a square column shape and is in sliding fit with theradial hole 31 is defined in theradial hole 31, atensioning spring 30 which provides thrust for the tensioning pin is arranged at the bottom of theradial hole 31, and the outer end of thetensioning pin 32 is fixedly connected with the top of theroller fork 29; when theroller 18 and the arc-shapedside wall 12 compress the connectingpipe 24, thetension spring 30 is in a compressed state and is not completely compressed;

therefore, theroller 18 can float along the radial direction of the revolvingwheel 9, and has a tensioning function, when the roller passes through the arc-shapedgap 7, the fluid output efficiency can be improved to the maximum extent, and the connectingpipe 24 can be prevented from being damaged due to overlarge pressure applied by theroller 18.

Example 4

Referring to fig. 4 and 5, in the clinical drainage intelligent control device disclosed inembodiment 1, the separation operation of theconnection pipe 24 from the drainage adjustment mechanism can be performed only when theroller 18 is at the initial position, and if any one of the components of thecontroller 19, thepower supply component 10, the drivingdevice 10, the drainage adjustment mechanism, etc. fails, when the clinical drainage intelligent control device is shut down, theroller 18 cannot move to the initial position smoothly, so that theconnection pipe 24 cannot be separated from the drainage adjustment mechanism smoothly, the medical operation efficiency is reduced, and even the medical treatment time may be delayed, for this reason, the present embodiment has a further improvement on theroller 18 on the basis of the structure of the drainage adjustment mechanism disclosed inembodiment 1, and the specific implementation structure is as follows:

referring to fig. 12, theroller 18 is connected with the revolvingwheel 9 through aroller fork 29, a manualrotating handle 33 is installed outside theroller fork 29, theroller 18 can be manually driven to revolve through the manualrotating handle 33, so that the position of theroller 18 can be adjusted according to clinical needs, and the operation is convenient and fast.

Example 5

Referring to fig. 7, in the clinical drainage intelligent control device disclosed inembodiment 1, thecontroller 19 may obtain the weighing signal continuously fed back by the weighingsensor 21 in real time, and it is mentioned in the foregoing explanation that the foregoing data transmission requirement may be achieved by adding a wireless transmission module, this embodiment obviously increases the overall manufacturing cost of the clinical drainage intelligent control device, and also reduces the working stability of the clinical drainage intelligent control device, it can be seen that a circuit for transmitting data is preferably arranged between the weighingsensor 21 and thecontroller 19 to ensure stability and economy, but there is a problem that thecontroller 19 and the weighingsensor 21 are distributed up and down, and thecontroller 19 may be adjusted in height along with theinstallation plate 8, which causes that if the circuit is installed in a conventional manner, the circuit is exposed, on the one hand, the overall structure of the clinical drainage intelligent control device is not compact, on the other hand, the exposed circuit is easily damaged by external force due to the lack of necessary protection; therefore, the present embodiment has a further improvement on the matching relationship between thecontroller 19 and theload cell 21, and the specific implementation structure is as follows:

referring to fig. 13, asignal line 34 for transmitting a weighing signal is connected between the weighingsensor 21 and thecontroller 19, a threading cavity for extending thesignal line 34 is formed in thebase 1, thetelescopic rod 3 and the mountingplate 8, a portion of thesignal line 34 located in thetelescopic rod 3 has a coil spring-shapedtelescopic section 35, and thetelescopic section 35 can be extended and retracted together with thetelescopic rod 3.

From this,signal line 34 is because of extending inbase 1,telescopic link 3 and mountingplate 8 to can not expose outside, also possessed better guard effect simultaneously, and improved job stabilization nature and life-span.

Example 6

Referring to fig. 1, 6 and 7, in the clinical drainage intelligent control device disclosed inembodiment 1, the weighing type base assembly is formed by sequentially matching a weighingplatform 2, a weighingsensor 21 and abase 1 up and down, the weighingsensor 21 outputs a weighing signal capable of reflecting the weight of an object above the weighingplatform 2, the structure is similar to an electronic scale, the weight of the accumulated liquid in thedrainage bag 27 can be measured and fed back to thecontroller 19 in the form of a weighing signal, the placement of the weighing base assembly on a horizontal surface during use may provide the most accurate weighing function, but has problems, in the clinical use field, the ground or the platform for placing the weighing type base component is difficult to ensure to be horizontal, the error of the output weighing signal is large or even inaccurate, so that the clinical drainage intelligent control device can not play the expected quantitative drainage and constant-speed drainage; to overcome this technical problem, the present embodiment provides a further improvement to the symmetrical base assembly, and the specific implementation structure thereof is as follows:

referring to fig. 14, four corners of thebase 1 are respectively provided with screw holes extending up and down, fourbolts 37 are in one-to-one threaded fit with the four screw holes, upper ends of thebolts 37 are respectively fixedly connected with adjustingknobs 38 positioned above thebase 1, and lower ends of thebolts 37 are respectively fixedly connected withanchor feet 36 positioned below thebase 1; a bubbletype level meter 39 is arranged on the weighingplatform 2;

therefore, when the intelligent control device for clinical drainage is used, the intelligent control device for clinical drainage is placed on the ground or on a platform, the bubbletype level meter 39 is observed to judge whether the weighing type base assembly is horizontally placed or not, the upper position and the lower position of the fourground feet 36 are adjusted according to the condition, the weighing type base assembly tends to be horizontally placed, the weighing function accuracy of the weighing type base assembly is improved, and the quantitative drainage and the constant-speed drainage can be accurately realized by the intelligent control device for clinical drainage finally.

Example 7

Referring to fig. 1 and 2, as the clinical drainage process is mostly performed by a patient lying on a hospital bed, and the intelligent control device for clinical drainage is used as an auxiliary drainage device, the patient needs to be frequently moved back and forth between a ward and an instrument room, and meanwhile, when the intelligent control device is used clinically, the position needs to be adjusted according to the layout of the drainage component, so that the intelligent control device for clinical drainage is small and compact and has great significance in improving portability; in the clinical drainage intelligent control device disclosed inembodiment 1, when carrying and being idle, can move down theplace plate 8 and the part supported by it, make the whole volume of clinical drainage intelligent control device reduce to a certain extent, still there is great improvement space for this reason, this embodiment has further improvement to the suspension subassembly and the seat subassembly of settling, and the concrete structure is as follows:

referring to fig. 15 and 16, the vertical rod 4 adopts a telescopic structure so that the vertical position of the suspension beam 6 can be adjusted and locked; the middle part of the suspension beam 6 is provided with a section of bow part 40 which is sunken towards the rear side, the upper end of the upright stanchion 4 is fixedly connected with the bow part 40, the upper end of the telescopic rod 3 is connected with a crank arm 41, the other end of the crank arm 41 is fixedly connected with the top of the rear side of the placing plate 8, and when the telescopic rod 3 and the upright stanchion 4 are both in the shortest state, the placing plate 8 is just positioned in the inner space of the bow part 40; therefore, in clinical use, as shown in fig. 15, the suspension beam 6 and the placing plate 8 are moved upwards and locked respectively, the clinical drainage intelligent control device is in an extending state, and the relative positions of the parts can meet the requirements of work; when the device is not used, as shown in fig. 16, the suspension beam 6 and the placing plate 8 are both moved downwards to the lowest position, and at the moment, the clinical drainage intelligent control device is in a retraction state, so that the device has a small and compact integral structure, and greatly improves the portability and the occupied space when the device is not used;

meanwhile, due to the existence of thearch part 40 in thesuspension beam 6, after the connectingpipe 24 is connected with thedrainage bag 27, thesuspension beam 6 does not form an obstacle to the up-and-down extension of the tail section part of the connectingpipe 24, the connectingpipe 24 can be connected with thedrainage bag 27 in a state of tending to natural extension, the acting force generated on thedrainage bag 27 is reduced, and in addition, the connection and separation operation of the connectingpipe 24 and thedrainage bag 27 is more convenient and smooth.

Example 8

Referring to fig. 6 and 9, in the clinical drainage intelligent control device disclosed inembodiment 1, the one-way output connector 42 is a necessary component, the arrangement and the function of which are described in detail above, and which can be implemented by using the existing one-way valve structure, but there is a problem that most of the existing one-way valves are reset to the cut-off state by an elastic member, so that the conduction of the existing one-way valves needs to reach a certain pressure, and the adoption of the one-way valve with a smaller working pressure can enable normal pressure drainage, but still does not bring a certain resistance to the flow of effusion, thereby reducing the adjustable range of the drainage speed in the normal pressure drainage; based on this, the present embodiment provides an excellent design for theunidirectional output connector 42, and the specific implementation structure thereof is as follows:

as shown in fig. 17, 18 and 19, the one-way output joint 42 comprises a main body 45, an input port 48 is arranged at the upper end of the main body 45 and is connected with the lower end of the connecting pipe 24, and an output port 43 is arranged at the lower end and is connected with the drainage bag 27; a column cavity 47 is formed in the main body 45, a liquid inlet hole 44 is formed in the bottom of the column cavity 47, a liquid discharging hole 50 is formed in the side wall of the middle lower part, and a vent hole 49 communicated with the atmosphere is formed in the upper end of the column cavity; the inlet 48 is communicated with the liquid inlet hole 44 through a flow passage, and the liquid outlet hole 50 is communicated with the outlet 43 through a flow passage; a floating ball 46 with a smooth surface is arranged in the valve cavity, a gap is formed between the floating ball 46 and the side wall of the column cavity 47, so that the liquid discharge hole 50 is always communicated with the vent hole 49, and the floating ball 46 sinks to the bottom of the column cavity 47 and then can be in sealing fit with the liquid inlet hole 44; when the liquid accumulation exists in the column cavity 47, the floating ball 46 floats on the upper surface of the liquid accumulation in the column cavity 47 to enable the liquid inlet hole 44, the liquid outlet hole 50 and the vent hole 49 to be communicated, and when the liquid accumulation does not exist in the column cavity 47, the floating ball 46 sinks by gravity to block the liquid inlet hole 44;

(1) when the fluid is output from the connectingtube 24 and is accumulated, as shown in fig. 17 and 18, the accumulated fluid pushes the floatingball 46 upwards and enters thecolumn cavity 47 through thefluid inlet hole 44, the floatingball 46 rises with the increase of the accumulated fluid in thecolumn cavity 47, the accumulated fluid in thecolumn cavity 47 is discharged through thefluid outlet hole 50 and finally flows into the drainage bag, and the accumulated fluid cannot overflow through theair outlet hole 49 because theair outlet hole 49 is higher than the fluid outlet hole; after the connectingpipe 24 finishes one-time fluid output, as theliquid discharge hole 50 is communicated with thevent hole 49, the accumulated liquid in the valve cavity can continuously flow into the drainage bag, the floatingball 46 sinks along with the reduction of the accumulated liquid in thecolumn cavity 47, and if the accumulated liquid in the connectingpipe 24 flows back, the accumulated liquid in thecolumn cavity 47 disappears, so that the floatingball 46 sinks to the bottom of thecolumn cavity 47 to block theliquid inlet hole 44, and thus the accumulated liquid in the connecting pipe is prevented from flowing back;

(2) when the fluid is output through the connectingpipe 24 and is air, as shown in fig. 19, the air pushes the floatingball 46 to rise and enter thecolumn cavity 47 through theliquid inlet hole 44, then continuously flows upwards through a gap between the floatingball 46 and thecolumn cavity 47, and is finally discharged to the outside, if the drainage bag is provided with an exhaust pipeline, part of the air in thecolumn cavity 47 is also discharged into the drainage bag through theliquid outlet hole 50, and is finally discharged to the outside through the exhaust pipeline of the drainage bag; after the connectingpipe 24 finishes the primary fluid output, the floatingball 46 sinks to the bottom of thecolumn cavity 47 by means of self-weight to block theliquid inlet hole 44, so that the air in the connecting pipe is prevented from flowing back;

after the unidirectional output joint 42 adopts the design, the unidirectional output joint has the unidirectional output characteristic of fluid, and can meet the technical requirements of negative pressure drainage and normal pressure drainage; in addition, because the floatingball 46 can float on the accumulated liquid, the density is low, the pressure required by the conduction of the floating ball is small, namely the working pressure is low, the flowing of the accumulated liquid can not be excessively hindered in the drainage process, and particularly in the normal-pressure drainage, the adjustable range of the drainage speed can be furthest improved;

meanwhile, the one-way output joint 42 is reset to the cut-off state based on the gravity of the floating ball, and the reset force is provided without an additional elastic piece, so that the structure is simple, the working stability of the one-way output joint 42 is ensured, and the service life is prolonged.

Claims (3)

Translated fromChinese

1.一种临床引流智能控制装置，其特征在于，其包括：1. a clinical drainage intelligent control device, is characterized in that, it comprises:称重式底座组件，其由称重台、称重传感器及基座上下依次配合而构成，称重传感器输出能够反映称重台上方物体重量的称重信号，基座上安设有为称重传感器提供工作电流的电源模块；The weighing base assembly is composed of a weighing platform, a weighing sensor and a base that are matched up and down in sequence. The weighing sensor outputs a weighing signal that can reflect the weight of the object above the weighing platform. The sensor provides the power module of the working current;悬撑组件，其包括下端与称重台固定连接的立杆、与立杆上端固定连接的悬撑梁，悬撑梁上设有用于夹持引流袋顶部的夹子，悬撑组件用于将引流袋悬挂于称重台的正上方；The suspension assembly includes a vertical rod whose lower end is fixedly connected with the weighing platform, and a suspension beam fixedly connected with the upper end of the vertical rod. The suspension beam is provided with a clip for clamping the top of the drainage bag, and the suspension assembly is used to drain the drainage. The bag is hung directly above the weighing platform;安置座组件，其包括安置板与连接管，安置板经一伸缩杆支撑而位于悬撑梁的上方，其上下位置可调节并可锁定，伸缩杆位于立杆的后侧且其下端与基座固定连接；连接管采用软质弹性材料制成，其上下端分别用于连接引流管与引流袋，其中上部设有一缓冲囊，其下端设有单向输出接头；安置板前侧开有用于卡固连接管的安置槽、用于卡固缓冲囊的囊座；The mounting seat assembly includes a mounting plate and a connecting pipe, the mounting plate is supported by a telescopic rod and is located above the suspension beam, its upper and lower positions can be adjusted and can be locked, the telescopic rod is located on the rear side of the vertical rod and its lower end Fixed connection; the connecting pipe is made of soft elastic material, the upper and lower ends of which are respectively used to connect the drainage pipe and the drainage bag, the upper part is provided with a buffer bag, and the lower end is provided with a one-way output joint; The placement groove of the connecting tube, the bag seat for clamping the buffer bag;引流调节机构，其包括一开设在安置板前侧的凹座，凹座内设有一段呈圆弧状的弧形侧壁，凹座内设有一与弧形侧壁中心轴重合的公转轮，弧形侧壁与公转轮之间形成有一个可容纳连接管的弧形间隙，当连接管卡固于安置槽后将从弧形间隙中穿过，公转轮由一驱动装置提供旋转动力；公转轮上固定有一位于其外侧且与其中心轴平行的轧辊，轧辊可绕辊轴自由旋转并可随公转轮进行公转；轧辊正向公转过程中，每次进入弧形间隙后，其将连接管挤压至阻断状态，而后将通过自转始终轧着弧形间隙内的连接管进行移动，驱使连接管中的流体向后流动，完成一次流体输出；轧辊可通过正向公转和反向公转来调节位置，从而可与弧形侧壁对连接管实施不同程度的挤压，实现控制连接管通断及调节连接管内部积液流速的目的；轧辊处于初始位置时，其不与连接管接触；The drainage adjustment mechanism includes a recessed seat opened on the front side of the placement plate, a segment of arc-shaped side wall in the shape of an arc is arranged in the recessed seat, and a revolution wheel coincident with the central axis of the arc-shaped side wall is arranged in the recessed seat. An arc-shaped gap is formed between the arc-shaped side wall and the revolving wheel, which can accommodate the connecting tube. When the connecting tube is clamped in the placement groove, it will pass through the arc-shaped gap, and the revolving wheel is provided with rotational power by a driving device. ; On the revolving wheel, a roller is fixed on the outer side and parallel to its central axis. The roller can freely rotate around the roller axis and can revolve with the revolving wheel; during the forward revolution of the roller, every time it enters the arc-shaped gap, its Squeeze the connecting pipe to a blocking state, and then move the connecting pipe in the arc-shaped gap through its rotation, driving the fluid in the connecting pipe to flow backwards to complete a fluid output; the roller can rotate forward and reverse. Adjust the position by revolving in the direction of rotation, so that the connecting pipe can be squeezed to different degrees with the arc-shaped side wall, so as to control the on-off of the connecting pipe and adjust the fluid flow rate inside the connecting pipe; when the roll is in the initial position, it is not connected to the connecting pipe. tube contact;控制器，其固定于安置板上，前侧设有设置键与显示屏；设置键用于向控制器中输入每次引流的引流模式和引流参数以及开关机指令，引流模式包括常压引流和负压引流，引流参数包括引流起始时间、引流过程中单位时间内引流的积液重量即引流速度、单次引流积液重量即单次引流量；控制器可获取称重传感器连续实时反馈的称重信号，并以此计算出实时引流速度、单次实时引流量；控制器可通过调控驱动装置的工作状态而调节轧辊的公转状态，公转状态包括公转的启停、旋转方向、旋转角度以及旋转速度；控制器可基于实时引流速度、单次实时引流量以及预设的引流模式和引流参数，对轧辊的公转状态进行协调控制，实现定时引流、定速引流及定量引流；控制器在收到关机指令后，先将轧辊调节至初始位置再执行关机；显示屏用于显示控制器中掌握的数据信息；The controller is fixed on the placement board, and the front side is provided with a setting button and a display screen; the setting button is used to input the drainage mode and drainage parameters of each drainage into the controller, as well as the switch on and off instructions. The drainage modes include normal pressure drainage and Negative pressure drainage, drainage parameters include drainage start time, drainage weight per unit time during drainage process, namely drainage speed, and single drainage effusion weight, namely single drainage volume; the controller can obtain continuous real-time feedback from the weighing sensor. Weigh the signal, and calculate the real-time drainage speed and single real-time drainage volume based on this; the controller can adjust the revolution state of the roll by regulating the working state of the drive device. The revolution state includes the start and stop of the revolution, the rotation direction, the rotation angle and Rotation speed; the controller can coordinately control the revolution state of the rolls based on the real-time drainage speed, the single real-time drainage amount, and the preset drainage mode and drainage parameters to realize timing drainage, constant-speed drainage and quantitative drainage; After the shutdown command is reached, first adjust the roll to the initial position and then execute the shutdown; the display screen is used to display the data information mastered in the controller;电源组件，其安设在安置板上，由蓄电池及若干变压模块构成，用于为驱动装置和控制器提供工作电流；The power supply assembly, which is installed on the mounting plate, is composed of a battery and several transformer modules, and is used to provide working current for the driving device and the controller;所述的单向输出接头包括一个主体，主体上端设有用于与连接管下端相连的输入口，下端设有用于与引流袋相连的输出口；主体内部开设有一柱腔，柱腔的底部设有进液孔，中下部的侧壁上设有一排液孔，上端设有与大气相通的通气孔；输入口经流道与进液孔相通，排液孔经流道与输出口相通；阀腔内设有一表面光滑的浮球，浮球与柱腔侧壁具有间隙而使排液孔与通气孔始终相连通，浮球下沉至柱腔底部后可与进液孔密封配合；当柱腔内部具有积液时，浮球漂浮在柱腔内的积液上表面而使进液孔、排液孔及通气孔三者连通，当柱腔内部不存在积液时，浮球靠重力下沉而将进液孔封堵。The one-way output joint includes a main body, the upper end of the main body is provided with an input port for connecting with the lower end of the connecting pipe, and the lower end is provided with an output port for connecting with the drainage bag; a column cavity is provided inside the main body, and the bottom of the column cavity is provided with an output port. The liquid inlet hole is provided with a liquid discharge hole on the side wall of the middle and lower part, and a ventilation hole communicated with the atmosphere is provided on the upper end; There is a floating ball with a smooth surface inside. The floating ball and the side wall of the column cavity have a gap so that the drain hole and the vent hole are always connected. After the floating ball sinks to the bottom of the column cavity, it can be sealed with the liquid inlet hole; When there is liquid accumulation inside, the floating ball floats on the upper surface of the liquid accumulation in the column cavity, so that the liquid inlet hole, the liquid discharge hole and the ventilation hole are connected. When there is no liquid accumulation inside the column cavity, the floating ball sinks by gravity. The liquid inlet hole is blocked.2.根据权利要求1所述的一种临床引流智能控制装置，其特征在于：在常压引流模式中，控制器基于实时引流速度、单次实时引流量以及引流参数，对轧辊的公转状态进行调控的方式为：2. a kind of clinical drainage intelligent control device according to claim 1 is characterized in that: in normal pressure drainage mode, the controller is based on real-time drainage speed, single real-time drainage amount and drainage parameters, the revolution state of the roll is carried out. The way of regulation is:a、在初次引流时，控制器根据预设的首次引流起始时间使轧辊进行正向公转，当称重信号发生变化时，使继续使轧辊正向公转，直至连接管处于导通状态，初次引流便开始；在此后的每次引流中，控制器根据预设的每次引流起始时间，使轧辊进行公转而调节位置，使连接管保持导通状态，即实现定时引流；a. During the initial drainage, the controller makes the roll revolve in the forward direction according to the preset initial drainage start time. When the weighing signal changes, it continues to make the roll revolve in the forward direction until the connecting pipe is in the conduction state. Drainage starts; in each subsequent drainage, the controller revolves the roll to adjust the position according to the preset start time of each drainage, so as to keep the connecting pipe in a conducting state, that is, to achieve timing drainage;b、在引流过程中，控制器根据实时引流速度使轧辊进行对应的正向公转或反向公转来调节轧辊对连接管的挤压程度，使连接管中的积液速度增大或减小，最终使实时引流速度与预设的引流速度趋于相等，即实现定速引流；b. During the drainage process, the controller makes the rolls perform corresponding forward revolution or reverse revolution according to the real-time drainage speed to adjust the extrusion degree of the rollers on the connecting pipe, so that the liquid accumulation speed in the connecting pipe increases or decreases. Finally, the real-time drainage speed is equal to the preset drainage speed, that is, constant-speed drainage is realized;c、在引流过程中，控制器实时计算出该次引流起始至目前所达到的单次实时引流量，当单次实时引流量达到预设的单次引流量时，控制器将驱使轧辊公转而调节位置，使连接管被挤压至阻断状态，此时此次引流结束，即实现定量引流。c. During the drainage process, the controller calculates in real time the single real-time drainage volume from the start of the drainage to the present. When the single real-time drainage volume reaches the preset single drainage volume, the controller will drive the rolls to revolve And adjust the position, so that the connecting tube is squeezed to the blocking state, at this time the drainage is over, that is, quantitative drainage is realized.3.根据权利要求1所述的一种临床引流智能控制装置，其特征在于：在负压引流模式中，控制器基于实时引流速度、单次实时引流量以及引流参数，对轧辊的公转状态进行调控的方式为：3. a kind of clinical drainage intelligent control device according to claim 1, is characterized in that: in negative pressure drainage mode, the controller is based on real-time drainage speed, single real-time drainage and drainage parameters, the revolution state of the roller is carried out. The way of regulation is:a、根据预设的引流起始时间，控制器驱使轧辊进行正向公转，驱使积液被迫由人体流至引流袋中，即实现定时引流；a. According to the preset drainage start time, the controller drives the roller to revolve in the forward direction, and drives the effusion to flow from the human body to the drainage bag, that is, to realize the timing drainage;b、在引流过程中，控制器根据实时引流速度调节轧辊的正向公转的旋转速度，使连接管中的积液平均流速增大或减小，最终使实时引流速度与预设的引流速度趋于相等，即实现定速引流；b. During the drainage process, the controller adjusts the rotation speed of the forward revolution of the roll according to the real-time drainage speed, so as to increase or decrease the average flow rate of the accumulated liquid in the connecting pipe, and finally make the real-time drainage speed and the preset drainage speed tend to be closer. equal, that is, to achieve constant speed drainage;c、在引流过程中，控制器实时计算出该次引流起始至目前所达到的单次实时引流量，当单次实时引流量达到预设的单次引流量时，控制器将在连接管被挤压至阻断状态的情况下使轧辊停止公转，此时此次引流结束，即实现定量引流。c. During the drainage process, the controller calculates in real time the single real-time drainage volume from the beginning of the drainage to the current one. When the single real-time drainage volume reaches the preset single drainage volume, the controller will connect the pipe in real time. In the case of being squeezed to a blocking state, the rolls stop revolving. At this time, the drainage is completed, that is, quantitative drainage is realized.

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