Disclosure of Invention
The invention aims to provide a device for preparing a semi-permeable membrane rough blank for nephrology department, which can exchange liquid suction and liquid discharge through an exchange assembly, and compared with the circulation of liquid suction and liquid discharge of a single stroke, the exchange assembly can carry out double circulation of liquid suction and liquid discharge, so that the efficiency is higher, and the speed is higher; the flow of the preparation stock solution can be adjusted by realizing the liquid separation assembly; the semi-permeable membrane blank forming process can be accelerated by the fixing frame assembly.
The purpose of the invention is realized by the following technical scheme:
the utility model provides a preparation facilities of pellicle rough blank for nephrology dept, includes that the hydrops holds case, communicating pipe one, hydrops exchange assembly, communicating pipe two, divides liquid assembly and mount assembly, the hydrops holds case and communicates communicating pipe one, communicating pipe one with hydrops exchange assembly connect and communicate, hydrops exchange assembly and mount assembly fixed connection, two exchange assembly with the hydrops and communicate communicating pipe two, divide liquid assembly fixed connection and intercommunication communicating pipe two.
As a further optimization of the technical scheme, the invention relates to a device for preparing semi-permeable membrane rough blanks for nephrology department, wherein the effusion exchange assembly comprises a front end cover, a middle end frame, a rear end cover, an exchange motor, an input belt wheel, a first transmission belt wheel, a second transmission belt wheel, a crankshaft, a rotary column, a piston rod, a liquid inlet cavity, a liquid outlet cavity, a middle end rotary cavity, a piston push rod, a threaded rod, a door-shaped frame, an internal rotary tooth, an internal rotary hole I, a crankshaft rotary hole, a threaded rod rotary hole and a push rod vertical rod, the front end cover is fixedly connected to the front end of the middle end frame, the rear end cover is fixedly connected to the rear end of the middle end frame, the exchange motor is fixedly connected to the upper end of the middle end frame, the input belt wheel is fixedly connected to an output shaft of the exchange motor, the crankshaft is rotatably connected to the front end cover and the rear end cover, the second transmission belt wheel is fixedly connected to the front end of the crankshaft, the first transmission belt wheel is connected to the input belt wheel and the second transmission belt wheel, the piston rod is connected with the rotary column in a sliding way, the middle-end rotary cavity is arranged at the middle end of the middle-end frame, the liquid inlet cavity is arranged at the left side of the inner end of the middle-end frame, the liquid outlet cavity is arranged at the right side of the inner end of the middle-end frame, the liquid inlet cavity is communicated with the liquid inlet hole, the liquid outlet cavity is communicated with the liquid outlet hole, the piston cavity II, the piston cavity III, the piston cavity IV and the piston cavity I are all arranged in the rotary column, the rotary column is rotatably connected in the middle-end rotary cavity, the piston rod is respectively and slidably connected in the piston cavity II, the piston cavity III, the piston cavity IV and the piston cavity I, the threaded rod is rotatably connected at the upper end of the piston rod, the piston push rod is slidably connected at the inner end of the piston rod, the door-shaped frame is slidably connected with the piston rod, the threaded rod is in threaded connection with the door-shaped frame, the inner end of the door-shaped frame is provided with a rack A, the door-shaped frame is in meshing transmission with the inward-rotating teeth through the rack A, the push rod vertical rod is arranged at the upper end of the piston rod, a rack B is arranged on the push rod vertical rod, the push rod montant passes through rack B and the meshing transmission of adversion tooth, the adversion tooth is provided with a plurality ofly, an adversion hole sets up on the piston rod, the piston rod is link up to an adversion hole, the bent axle changes the hole setting in the piston rod middle-end, the threaded rod changes the upper end of hole setting at the piston rod, the threaded rod rotates to be connected in the threaded rod commentaries on classics hole, the bent axle changes the hole and is connected with the bent axle rotation, one and middle-end frame fixed connection communicating pipe, one and income liquid hole intercommunication communicating pipe, go out liquid hole and two fixed connection and intercommunications communicating pipe.
As a further optimization of the technical scheme, the device for preparing the semi-permeable membrane rough blank for the nephrology department comprises a connecting sleeve, a liquid-separating outer frame, a T-shaped rod, a manual sliding rod, a movable clamping rod, a dividing rod, a communication hole, a side wall sliding cavity, an inner conical cavity, a first inner wall rectangular sliding groove, a first communication waist groove, a fixed cavity, a clamping hole, a liquid-separating hole, a second inner wall rectangular sliding groove, an inner sliding column pushing spring, a transverse sliding column, a transverse pushing spring, a sliding waist groove, a driving column, a clamping rod boss and a connecting sliding plate, wherein the dividing rod comprises a liquid-separating ball, a first dividing sliding rod, a limiting boss and a second dividing sliding rod, the connecting sleeve is fixedly connected with the liquid-separating outer frame, the T-shaped rod is fixedly connected with the dividing rod, the dividing rod is slidably connected with the connecting sleeve, the movable clamping rod is slidably connected with the T-shaped rod, the manual sliding rod is slidably connected with the movable clamping rod, the T-shaped rod is cooperatively connected with the manual sliding rod, the intercommunicating pore is arranged at the upper side of the inner end of the connecting sleeve, the side wall sliding cavity is arranged on the side wall of the connecting sleeve, the inner conical cavity is arranged at the lower side of the inner end of the connecting sleeve, the inner conical cavity is communicated with the intercommunicating pore, the first inner wall rectangular sliding groove is arranged at the left end of the inner wall of the liquid separation outer frame, the second communication waist groove is arranged at the right end of the outer wall of the liquid separation outer frame, the clamping pore is provided with a plurality of holes, the liquid separation pore is arranged at the lower end of the liquid separation outer frame, the fixed cavity is arranged at the upper end of the liquid separation outer frame, the fixed cavity is communicated with the liquid separation pore, the second inner wall rectangular sliding groove is arranged at the right side of the inner end of the liquid separation outer frame, the first liquid separation sliding rod is arranged at the right end of the component rod, the first liquid separation sliding rod is fixedly connected with the component separating ball, the second liquid separation sliding rod is fixedly connected with the limiting boss, the second sliding rod is slidably connected in the side wall sliding cavity, divide liquid slide bar one and lateral wall sliding chamber sliding connection, divide liquid slide bar sliding connection in intercommunication waist inslot, T type pole and a fixed connection that divides liquid slide bar, interior sliding column sets up in T type pole, interior sliding column pushes away the spring and cup joints including connecting on the sliding column, horizontal sliding column fixed connection is at the right-hand member of T type pole, horizontal push spring cup joints on horizontal sliding column, interior sliding column pushes away the spring and all is in compression state with horizontal push spring, sliding waist groove and horizontal sliding column sliding connection, sliding waist groove sets up on manual slide bar, drive post fixed connection is at activity kelly right-hand member, kelly boss fixed connection is at the middle-end of activity kelly, connect the left end of slide fixed connection at the activity kelly, connect slide including slide fixed connection, kelly boss cooperation is connected in the kelly, drive post sliding connection is in sliding waist inslot, two fixed connection are at the upper end of connecting sleeve, communicating pipe two and intercommunicating pipe intercommunication.
As a further optimization of the technical scheme, the invention relates to a device for preparing a semi-permeable membrane rough blank for nephrology department, which comprises a bottom plate, a heat dissipation motor, an input connection bevel gear, a transmission belt II, a heat dissipation assembly, a connecting rod, a rotary spherical boss, an annular bevel gear, a motor boss, a middle-end rotary column, a left-side fixed column, a heat dissipation fixed rod, a driving rotary rod, a fan blade, a transmission bevel gear I, a shaft-bearing bevel gear I and a shaft-bearing bevel gear II, wherein the motor boss is fixedly connected at the right end of the bottom plate, the middle-end rotary column is fixedly connected at the middle end of the bottom plate, the left-side fixed column is fixedly connected at the left end of the bottom plate, the heat dissipation motor is fixedly connected to the motor boss, the input connection bevel gear is fixedly connected to an output shaft of the heat dissipation motor, the input connection bevel gear is in meshing transmission with the annular bevel gear, the annular bevel gear is fixedly connected with the rotary spherical boss, and the rotary spherical boss is rotatably connected with the middle-end rotary column, the heat dissipation assembly is fixedly connected with the bottom plate, the heat dissipation assembly is provided with a plurality of heat dissipation assemblies, the connecting rods are connected between the heat dissipation assemblies, the heat dissipation fixing rods are arranged in the heat dissipation assembly, the driving rotating rods are rotatably connected with the heat dissipation fixing rods, the fan blades are slidably connected with the driving rotating rods, the first transmission bevel gears are fixedly connected with the driving rotating rods, the first belt shaft bevel gears are in meshing transmission with the first transmission bevel gears, the first belt shaft bevel gears are rotatably connected with the heat dissipation fixing rods, the second belt shaft bevel gears are in meshing transmission with the first transmission bevel gears, one ends of the connecting rods are hinged to the first belt shaft bevel gears, the other ends of the connecting rods are hinged to the second belt shaft bevel gears in the adjacent heat dissipation assemblies, the middle end frame is fixedly connected with the left side fixing columns, and the second transmission belt is connected between the driving rotating rods and the output shaft of the heat dissipation motor.
The device for preparing the semi-permeable membrane rough blank for the nephrology department has the beneficial effects that:
according to the device for preparing the semi-permeable membrane rough blank for the nephrology department, the liquid separating ball moves upwards in the inner conical cavity, so that a gap formed between the liquid separating ball and the inner conical cavity is changed, the amount of the prepared stock solution flowing through the gap formed between the liquid separating ball and the inner conical cavity is further changed, and the flow of the prepared stock solution is further adjusted. The heat dissipation motor rotates, drives the drive rotating rod to rotate through the driving belt II, drives the fan blades to rotate, simultaneously drives the drive rotating rod in other heat dissipation combinations to rotate through the meshing transmission of the transmission bevel gear I and the transmission bevel gear II, and further enables other fan blades to rotate, air flow is accelerated through the fan blades, the cooling of the stock solution is accelerated to be prepared, and then the forming process of filtering the semi-permeable membrane rough blank is accelerated.
Drawings
The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.
FIG. 1 is a schematic view of the overall structure of the present invention;
FIG. 2 is a schematic view of a liquid loading container according to the present invention;
FIG. 3 is a schematic view of a second embodiment of the present invention;
FIG. 4 is a third schematic view of the liquid loading chamber of the present invention;
FIG. 5 is a fourth schematic view of the present invention;
FIG. 6 is a schematic view of a liquid loading chamber according to the present invention;
FIG. 7 is a sixth schematic view of the present invention showing a liquid loading chamber;
FIG. 8 is a seventh schematic view of the present invention showing a liquid loading chamber;
FIG. 9 is a schematic view of an eighth embodiment of the present invention;
FIG. 10 is a ninth schematic view of the effusion cell-containing box of the present invention;
FIG. 11 is a schematic view of a liquid loading chamber of the present invention;
FIG. 12 is a schematic view eleven of a effusion cell housing of the invention;
FIG. 13 is a first schematic view of a dispensing assembly according to the present invention;
FIG. 14 is a second schematic view of a dispensing assembly of the present invention;
FIG. 15 is a third schematic view of a liquid-separating assembly according to the present invention;
FIG. 16 is a fourth schematic view of a dispensing assembly of the present invention;
FIG. 17 is a fifth schematic view of a dispensing assembly of the present invention;
FIG. 18 is a sixth schematic view of a dispensing assembly of the present invention;
FIG. 19 is a seventh schematic view of a dispensing assembly of the present invention;
FIG. 20 is a schematic view eight of the structure of the liquid separation assembly of the present invention;
FIG. 21 is a ninth schematic diagram of a dispensing assembly of the present invention;
FIG. 22 is a schematic diagram of a liquid-separating assembly according to the present invention;
FIG. 23 is a eleventh schematic view of a dispensing assembly of the present invention;
FIG. 24 is a twelve schematic diagram of a dispensing assembly of the present invention;
FIG. 25 is a thirteen schematic structural diagram of a liquid separation assembly of the present invention;
FIG. 26 is a first schematic view of a first embodiment of a fastening frame assembly of the present invention;
FIG. 27 is a second schematic view of the fastening frame assembly of the present invention;
FIG. 28 is a third schematic view of the fastening frame assembly of the present invention;
FIG. 29 is a fourth schematic view of the fastening frame assembly of the present invention;
FIG. 30 is a fifth schematic view of the fastening frame assembly of the present invention;
fig. 31 is a sixth schematic structural view of the fastening frame assembly of the present invention.
In the figure: a liquid accumulation accommodating box 1; a first communicating pipe 2; an accumulated liquid exchange assembly 3; a front end cover 3-1; a middle end frame 3-2; 3-3 parts of a rear end cover; 3-4 parts of a switching motor; 3-5 of an input belt wheel; 3-6 parts of a first transmission belt; a second transmission belt wheel 3-7; 3-8 parts of a crankshaft; 3-9 of a rotary column; 3-10 parts of a piston rod; 3-11 parts of a liquid inlet cavity; 3-12 parts of a liquid outlet cavity; 3-13 middle end rotary cavity; 3-14 parts of a piston cavity I; 3-15 parts of a piston push rod; 3-16 parts of a threaded rod; door frames 3-17; 3-18 parts of internal rotating teeth; 3-19 of an internal rotation hole I; 3-20 parts of crankshaft rotary holes; 3-21 of threaded rod rotating hole; 3-22 parts of a push rod vertical rod; 3-23 parts of liquid inlet hole; 3-24 parts of liquid outlet holes; 3-25 parts of a piston cavity II; piston chamber three 3-26; piston chamber four 3-27; a second communicating pipe 4; a liquid separation assembly 5; connecting a sleeve 5-1; 5-2 of a liquid separation outer frame; 5-3 of T-shaped rods; 5-4 of a manual sliding rod; 5-5 parts of movable clamping rod; 5-6 parts of a component rod; communicating holes 5-7; 5-8 of side wall sliding cavity; 5-9 parts of inner conical cavity; 5-10 of a rectangular sliding chute I on the inner wall; 5-11 of communicating waist groove; 5-12 parts of a fixed cavity; 5-13 of a clamping hole; 5-14 parts of liquid separation hole; 5-15 of a second rectangular sliding chute on the inner wall; 5-16 parts of liquid separation ball; 5-17 parts of a first liquid-separating sliding rod; 5-18 parts of a limiting boss; a second liquid separating slide bar 5-19; 5-20 parts of inner sliding column; 5-21 parts of inner sliding column push spring; 5-22 of transverse sliding columns; 5-23 of transverse push spring; 5-24 of a sliding waist groove; 5-25 of a driving column; 5-26 parts of clamping rod boss; connecting the sliding plates 5-27; a fixed frame assembly 6; a bottom plate 6-1; a heat dissipation motor 6-2; the input is connected with a bevel gear 6-3; 6-4 parts of a second transmission belt; 6-5 of a heat dissipation assembly; 6-6 of a connecting rod; rotating 6-7 parts of the spherical boss; 6-8 parts of annular bevel gear; 6-9 parts of a motor boss; 6-10 of a middle-end rotating column; 6-11 parts of left side fixing column; 6-12 parts of a heat radiation fixing rod; driving the rotating rod 6-13; 6-14 of fan blades; 6-15 parts of a first transmission bevel gear; 6-16 parts of a first conical tooth with an axis; and the second conical tooth with the shaft is 6-17.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.
The first embodiment is as follows:
this embodiment is explained below with reference to fig. 1-31, a preparation facilities of pellicle rough blank for nephrology dept, including hydrops containing box 1, communicating pipe 2, hydrops exchange assembly 3, communicating pipe two 4, divide liquid assembly 5 and mount assembly 6, hydrops containing box 1 is connected and communicates with communicating pipe 2, and communicating pipe 2 is connected and communicates with hydrops exchange assembly 3, and hydrops exchange assembly 3 and mount assembly 6 fixed connection, communicating pipe two 4 are connected and communicate with hydrops exchange assembly 3, and communicating pipe two 4 and divide liquid assembly 5 fixed connection and communicate.
The second embodiment is as follows:
the present embodiment is described below with reference to fig. 1 to 31, and is further described, where the effusion exchange assembly 3 includes a front end cover 3-1, a middle end frame 3-2, a rear end cover 3-3, an exchange motor 3-4, an input pulley 3-5, a transmission belt I3-6, a transmission pulley II 3-7, a crankshaft 3-8, a rotary column 3-9, a piston rod 3-10, a liquid inlet cavity 3-11, a liquid outlet cavity 3-12, a middle end rotary cavity 3-13, a piston push rod 3-15, a threaded rod 3-16, a door frame 3-17, an internal rotary tooth 3-18, an internal rotary hole I3-19, a crankshaft rotary hole 3-20, a threaded rod rotary hole 3-21, and a push rod vertical rod 3-22, the front end cover 3-1 is fixedly connected to the front end of the middle end frame 3-2, a rear end cover 3-3 is fixedly connected with the rear end of a middle end frame 3-2, an exchange motor 3-4 is fixedly connected with the upper end of the middle end frame 3-2, an input belt wheel 3-5 is fixedly connected with an output shaft of the exchange motor 3-4, a crankshaft 3-8 is rotatably connected with a front end cover 3-1 and the rear end cover 3-3, a transmission belt wheel II 3-7 is fixedly connected with the front end of the crankshaft 3-8, a transmission belt I3-6 is connected with the input belt wheel 3-5 and the transmission belt wheel II 3-7, a piston rod 3-10 is connected with a rotary column 3-9 in a sliding way, a middle end rotary cavity 3-13 is arranged at the middle end of the middle end frame 3-2, a liquid inlet cavity 3-11 is arranged at the left side of the inner end of the middle end frame 3-2, a liquid outlet cavity 3-12 is arranged at the right side of the inner end of the middle end frame 3-2, the liquid inlet cavity 3-11 is communicated with the liquid inlet hole 3-23, the liquid outlet cavity 3-12 is communicated with the liquid outlet hole 3-24, the piston cavity two 3-25, the piston cavity three 3-26, the piston cavity four 3-27 and the piston cavity one 3-14 are all arranged in the rotary column 3-9, the rotary column 3-9 is rotatably connected in the rotary cavity 3-13 at the middle end, a plurality of piston rods 3-10 are arranged, the piston rods 3-10 are respectively and slidably connected in the piston cavity two 3-25, the piston cavity three 3-26, the piston cavity four 3-27 and the piston cavity one 3-14, the threaded rods 3-16 are rotatably connected at the upper end of the piston rods 3-10, the piston push rods 3-15 are slidably connected at the inner end of the piston rods 3-10, the door-shaped frame 3-17 is slidably connected with the piston rods 3-10, the threaded rod 3-16 is connected with the door-shaped frame 3-17 through threads, the inner end of the door-shaped frame 3-17 is provided with a rack A, the door-shaped frame 3-17 is in meshing transmission with the inner turning teeth 3-18 through the rack A, the push rod vertical rod 3-22 is arranged at the upper end of the piston push rod 3-15, the push rod vertical rod 3-22 is provided with a rack B, the push rod vertical rod 3-22 is in meshing transmission with the inner turning teeth 3-18 through the rack B, the inner turning teeth 3-18 are provided with a plurality of inner turning holes 3-19 which are arranged on the piston rod 3-10, the inner turning holes 3-19 penetrate through the piston rod 3-10, the crankshaft turning hole 3-20 is arranged at the middle end of the piston rod 3-10, the threaded rod turning hole 3-21 is arranged at the upper end of the piston rod 3-10, the threaded rod 3-16 is rotatably connected in the threaded rod turning hole 3-21, the crankshaft rotating holes 3-20 are rotatably connected with the crankshafts 3-8, the first communicating pipe 2 is fixedly connected with the middle-end frame 3-2, the first communicating pipe 2 is communicated with the liquid inlet holes 3-23, and the liquid outlet holes 3-24 are fixedly connected and communicated with the second communicating pipe 4;
when the piston rod 3-10, the piston cavity II 3-25 and the piston cavity IV 3-27 slide to form a cavity for discharging stock solution into the liquid outlet cavity 3-12, the other piston rods 3-10, the piston cavity III 3-26 and the piston cavity I3-14 slide to form empty suction for taking the stock solution into the liquid cavity 3-11; compared with single liquid suction and liquid discharge circulation, the double liquid suction and liquid discharge circulation has higher efficiency and higher speed; the volume of a cavity formed between the piston push rod 3-15 and the piston cavity II 3-25, the piston cavity III 3-26, the piston cavity IV 3-27 and the piston cavity I3-14 changes, so that the volume of a preparation stock solution which can be contained by the cavity formed between the piston push rod 3-15 and the piston cavity II 3-25, the piston cavity III 3-26, the piston cavity IV 3-27 and the piston cavity I3-14 changes, and further the adjustment of the amount of the discharged stock solution and the amount of the absorbed stock solution is realized.
The third concrete implementation mode:
the embodiment is described below with reference to fig. 1-31, and the embodiment further describes a first embodiment, wherein the liquid separation assembly 5 comprises a connecting sleeve 5-1, a liquid separation outer frame 5-2, a t-shaped rod 5-3, a manual slide rod 5-4, a movable clamping rod 5-5, a component rod 5-6, a communication hole 5-7, a side wall slide cavity 5-8, an inner tapered cavity 5-9, an inner wall rectangular sliding groove I5-10, a communication waist groove 5-11, a fixed cavity 5-12, a clamping hole 5-13, a liquid separation hole 5-14, an inner wall rectangular sliding groove II 5-15, an inner sliding column 5-20, an inner sliding column push spring 5-21, a transverse sliding column 5-22, a transverse push spring 5-23, a sliding waist groove 5-24, a driving column 5-25, a clamping rod boss 5-26, A connecting slide plate 5-27, a component rod 5-6 including a liquid separating ball 5-16, a liquid separating slide rod one 5-17, a limit boss 5-18, and a liquid separating slide rod two 5-19, the connecting sleeve 5-1 is fixedly connected with the liquid separating outer frame 5-2, the T-shaped rod 5-3 is fixedly connected with the component rod 5-6, the component rod 5-6 is connected with the connecting sleeve 5-1 in a sliding manner, the movable clamping rod 5-5 is connected with the T-shaped rod 5-3 in a sliding manner, the manual slide rod 5-4 is connected with the movable clamping rod 5-5 in a sliding manner, the T-shaped rod 5-3 is connected with the manual slide rod 5-4 in a matching manner, a communication hole 5-7 is arranged at the upper side of the inner end of the connecting sleeve 5-1, a side wall slide cavity 5-8 is arranged on the side wall of the connecting sleeve 5-1, an inner conical cavity 5-9 is arranged at the lower side of the inner end of the connecting sleeve 5-1, the inner conical cavity 5-9 is communicated with a communication hole 5-7, the inner wall rectangular sliding chute one 5-10 is arranged at the left end of the inner wall of the liquid separation outer frame 5-2, the communication waist groove 5-11 is arranged at the right end of the outer part of the liquid separation outer frame 5-2, the clamping hole 5-13 is arranged on the outer wall of the liquid separation outer frame 5-2, a plurality of clamping holes 5-13 are arranged, the liquid separation hole 5-14 is arranged at the lower end of the liquid separation outer frame 5-2, the fixed cavity 5-12 is arranged at the upper end of the liquid separation outer frame 5-2, the fixed cavity 5-12 is communicated with the liquid separation hole 5-14, the inner wall rectangular sliding chute two 5-15 is arranged at the right side of the inner end of the liquid separation outer frame 5-2, the inner wall rectangular sliding chute two 5-15 is communicated with the communication waist groove 5-11, the liquid separation sliding rod one 5-17 is arranged at the right end of the liquid separation rod 5-6, a first separating slide bar 5-17 is fixedly connected with a second separating ball 5-16, a second separating slide bar 5-19 is fixedly connected with a second separating ball 5-16, a limit boss 5-18 is fixedly connected with the second separating slide bar 5-19, the second separating slide bar 5-19 is slidably connected in a side wall slide cavity 5-8, the first separating slide bar 5-17 is slidably connected with the side wall slide cavity 5-8, the first separating slide bar 5-17 is slidably connected in a communicating waist groove 5-11, a T-shaped bar 5-3 is fixedly connected with the first separating slide bar 5-17, an inner slide column 5-20 is arranged in the T-shaped bar 5-3, an inner slide column push spring 5-21 is connected on the inner slide column 5-20 in a sleeved mode, a transverse slide column 5-22 is fixedly connected at the right end of the T-shaped bar 5-3, and a transverse push spring 5-23 is connected on the transverse slide column 5-22 in a sleeved mode, the inner sliding column push springs 5-21 and the transverse push springs 5-23 are all in a compressed state, the sliding waist grooves 5-24 are in sliding connection with the transverse sliding columns 5-22, the sliding waist grooves 5-24 are arranged on the manual sliding rods 5-4, the driving columns 5-25 are fixedly connected to the right ends of the movable clamping rods 5-5, clamping rod bosses 5-26 are fixedly connected to the middle ends of the movable clamping rods 5-5, connecting sliding plates 5-27 are fixedly connected to the left ends of the movable clamping rods 5-5, connecting sliding plates 5-27 are fixedly connected to the inner sliding columns 5-20, the clamping rod bosses 5-26 are connected in clamping holes 5-13 in a matching mode, the driving columns 5-25 are connected in the sliding waist grooves 5-24 in a sliding mode, the communicating pipe two 4 is fixedly connected to the upper end of the connecting sleeve 5-1, and the communicating pipe two 4 is communicated with the communicating holes 5-7;
the liquid separating ball 5-16 moves upwards in the inner conical cavity 5-9, so that a gap formed between the liquid separating ball 5-16 and the inner conical cavity 5-9 is changed, further, the amount of the preparation stock solution flowing through the gap formed between the liquid separating ball 5-16 and the inner conical cavity 5-9 is changed, and further, the adjustment of the flow of the preparation stock solution is realized.
The fourth concrete implementation mode:
the embodiment is described below with reference to fig. 1 to 31, and the embodiment further describes the first embodiment, where the fixing frame assembly 6 includes a bottom plate 6-1, a heat dissipation motor 6-2, an input connection bevel gear 6-3, a transmission belt II 6-4, a heat dissipation assembly 6-5, a connection rod 6-6, a rotary spherical boss 6-7, an annular bevel gear 6-8, a motor boss 6-9, a middle end rotary column 6-10, a left side fixing column 6-11, a heat dissipation fixing rod 6-12, a driving rotary column 6-13, a fan blade 6-14, a transmission bevel gear I6-15, a shaft-carrying bevel gear I6-16, and a shaft-carrying bevel gear II 6-17, the motor boss 6-9 is fixedly connected to the right end of the bottom plate 6-1, the middle end rotary column 6-10 is fixedly connected to the middle end of the bottom plate 6-1, a left fixed column 6-11 is fixedly connected with the left end of a bottom plate 6-1, a heat dissipation motor 6-2 is fixedly connected with a motor boss 6-9, an input connection bevel gear 6-3 is fixedly connected with an output shaft of the heat dissipation motor 6-2, the input connection bevel gear 6-3 is in meshing transmission with an annular bevel gear 6-8, the annular bevel gear 6-8 is fixedly connected with a rotary spherical boss 6-7, the rotary spherical boss 6-7 is in rotary connection with a middle end rotary column 6-10, a heat dissipation assembly 6-5 is fixedly connected with the bottom plate 6-1, a plurality of heat dissipation assemblies 6-5 are arranged, a connecting rod 6-6 is connected between the heat dissipation assemblies 6-5, a heat dissipation fixed rod 6-12 is arranged in the heat dissipation assembly 6-5, and a driving rotary rod 6-13 is in rotary connection with the heat dissipation fixed rod 6-, the fan blades 6-14 are connected with the driving rotating rods 6-13 in a sliding mode, the transmission bevel gear I6-15 is fixedly connected with the driving rotating rods 6-13, the belt shaft bevel gear I6-16 is in meshing transmission with the transmission bevel gear I6-15, the belt shaft bevel gear I6-16 is in rotating connection with the heat dissipation fixing rod 6-12, the belt shaft bevel gear II 6-17 is in meshing transmission with the transmission bevel gear I6-15, one end of the connecting rod 6-6 is hinged to the belt shaft bevel gear I6-16, the other end of the connecting rod 6-6 is hinged to the belt shaft bevel gear II 6-17 in the adjacent heat dissipation combination 6-5, the middle-end frame 3-2 is fixedly connected with the left-side fixing column 6-11, and the transmission belt II 6-4 is connected between the driving rotating rods 6-13 and the output shaft of the heat dissipation motor 6;
the heat dissipation motor 6-2 rotates, the driving rotating rod 6-13 is driven to rotate through the transmission belt II 6-4, the fan blades 6-14 are driven to rotate, meanwhile, the driving rotating rod 6-13 in the rest heat dissipation assemblies 6-5 is driven to rotate through the meshing transmission of the transmission bevel gear I6-15, the transmission bevel gear I6-16 and the transmission bevel gear II 6-17, the rest fan blades 6-14 are further driven to rotate, air flow is accelerated through the fan blades 6-14, cooling of a prepared stock solution is accelerated, and the forming process of filtering the semi-permeable membrane rough blank is further accelerated.
The invention relates to a device for preparing a semi-permeable membrane rough blank for nephrology department, which has the working principle that:
when in use, the prepared stock solution is poured into the inner end of the effusion containing box 1, the exchange motor 3-4 is started at the same time, the exchange motor 3-4 drives the input belt wheel 3-5 to rotate, the input belt wheel 3-5 drives the transmission belt wheel 3-7 to rotate through the transmission belt wheel 3-6, the crankshaft 3-8 is driven to rotate through the transmission belt wheel 3-7, the crankshaft 3-8 rotates, the piston rod 3-10 is driven to slide along the piston cavity two 3-25, the piston cavity three 3-26, the piston cavity four 3-27 and the piston cavity one 3-14 through the connection of the crankshaft 3-8 and the crankshaft rotating hole 3-20, and the rotating column 3-9 is driven to rotate along the middle end rotating cavity 3-13 through the sliding of the piston rod 3-10 in the piston cavity two 3-25, the piston cavity three 3-26, the piston cavity four 3-27 and the piston cavity one 3-14, the rotation direction of the crankshaft 3-8 is anticlockwise rotation, when the right side of the crankshaft 3-8 rotates towards the upper side, the piston rod 3-10 slides upwards in the piston cavity two 3-25 and the piston cavity four 3-27, the rotary column 3-9 is driven to rotate through the piston rod 3-10, the piston cavity two 3-25 and the piston cavity four 3-27 are driven to be communicated with the liquid inlet cavity 3-11, the original liquid in the liquid inlet cavity 3-11 is sucked through a cavity formed by the piston rod 3-10, the piston cavity two 3-25 and the piston cavity four 3-27 in a sliding mode, when the right side of the crankshaft 3-8 rotates towards the lower side, the rotary column 3-9 is driven to rotate through the piston rod 3-10, the piston cavity two 3-25 and the piston cavity four 3-27 are driven to be communicated with the liquid outlet cavity 3-12, the piston rod 3-10 slides downwards in the piston cavity two 3-25 and the piston cavity four 3-27, the piston rod 3-10 pushes the preparation stock solution in the cavities of the piston rod 3-10, the piston cavity II 3-25 and the piston cavity IV 3-27 to be discharged into the liquid outlet cavity 3-12, the piston rod 3-10 pushes the air in the cavities of the piston cavity II 3-25 and the piston cavity IV 3-27, the preparation stock solution enters the liquid separating assembly 5 through the liquid outlet cavity 3-12 and the communicating pipe II 4 by the pushing of the air, and when the stock solution in the liquid outlet cavity 3-11 is sucked by the cavity formed by the sliding of the piston rod 3-10, the piston cavity II 3-25 and the piston cavity IV 3-27, the stock solution is discharged into the liquid outlet cavity 3-12 by the cavities formed by the sliding of the other piston rod 3-10, the piston cavity III 3-26 and the piston cavity I3-14; when the piston rod 3-10, the piston cavity II 3-25 and the piston cavity IV 3-27 slide to form a cavity for discharging stock solution into the liquid outlet cavity 3-12, the other piston rods 3-10, the piston cavity III 3-26 and the piston cavity I3-14 slide to form empty suction for taking the stock solution into the liquid cavity 3-11; compared with single liquid suction and liquid discharge circulation, the double liquid suction and liquid discharge circulation has higher efficiency and higher speed; when the amount of discharged stock solution and absorbed stock solution needs to be changed, the threaded rod 3-16 is manually rotated, so that the threaded rod 3-16 rotates in the threaded rod rotating hole 3-21, the threaded rod 3-16 is in threaded connection with the door type frame 3-17, the door type frame 3-17 is driven to slide along the inner wall of the piston rod 3-10, the rack A on the door type frame 3-17 drives the inner rotating teeth 3-18 to rotate, the rack B on the inner rotating teeth 3-18 and the push rod vertical rod 3-22 drives the push rod vertical rod 3-22 to drive the piston push rod 3-15 to slide along the inner wall of the piston rod 3-10 to the lower side, and the volume of a cavity formed among the piston push rod 3-15, the piston cavity two 3-25, the piston cavity three 3-26, the piston cavity four 3-27 and the piston cavity one 3-14 is changed, so that the volume of the preparation stock solution which can be contained in a cavity formed between the piston push rod 3-15 and the piston cavity II 3-25, the piston cavity III 3-26, the piston cavity IV 3-27 and the piston cavity I3-14 is changed, and further the adjustment of the amount of the discharged stock solution and the absorbed stock solution is realized; the preparation stock solution flowing into the liquid separation assembly 5 enters the inner conical cavity 5-9 through the communicating hole 5-7, falls into the rotary spherical boss 6-7 through the liquid separation hole 5-14, flows down along the outer wall of the rotary spherical boss 6-7 under the action of liquid surface tension, simultaneously starts the heat dissipation motor 6-2, drives the input connecting conical tooth 6-3 to rotate through the heat dissipation motor 6-2, drives the rotary spherical boss 6-7 to rotate through the meshing of the input connecting conical tooth 6-3 and the annular conical tooth 6-8, enables the preparation stock solution to uniformly cover the rotary spherical boss 6-7, and completes the preparation process of the filtering semipermeable membrane rough blank; when the flow of the prepared stock solution needs to be adjusted, manually pushing a manual slide bar 5-4 to the left side to enable the manual slide bar 5-4 to move to the left side along a transverse slide column 5-22, simultaneously compressing a transverse push spring 5-23, driving a connecting slide plate 5-27 to simultaneously move to the inner side along an inner slide column 5-20 through the matching connection between a sliding waist groove 5-24 on the manual slide bar 5-4 and a driving column 5-25, driving a clamping rod boss 5-26 to be separated from a clamping hole 5-13 through the connecting slide plate 5-27, simultaneously pushing the manual slide bar 5-4 to the upper side, driving the transverse slide column 5-22 to move upwards through the manual slide bar 5-4, driving a liquid separation slide bar 5-17 to slide upwards along a side wall slide cavity 5-8 through the fixed connection between a T-shaped bar 5-3 and the liquid separation slide bar 5-17, further driving the liquid separating balls 5-16 to move upwards in the inner conical cavities 5-9, so that gaps formed between the liquid separating balls 5-16 and the inner conical cavities 5-9 are changed, further changing the amount of the preparation stock solution flowing through the gaps formed between the liquid separating balls 5-16 and the inner conical cavities 5-9, and further realizing the adjustment of the flow of the preparation stock solution; the heat dissipation motor 6-2 rotates, the driving rotating rod 6-13 is driven to rotate through the transmission belt II 6-4, the fan blades 6-14 are driven to rotate, meanwhile, the driving rotating rod 6-13 in the rest heat dissipation assemblies 6-5 is driven to rotate through the meshing transmission of the transmission bevel gear I6-15, the transmission bevel gear I6-16 and the transmission bevel gear II 6-17, the rest fan blades 6-14 are further driven to rotate, air flow is accelerated through the fan blades 6-14, cooling of a prepared stock solution is accelerated, and the forming process of filtering the semi-permeable membrane rough blank is further accelerated.
It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.