CN113203244B - Automatic blood bank and automatic output equipment thereof - Google Patents

Abstract

The invention discloses an automatic blood bank and automatic output equipment thereof, relating to the technical field of medical equipment and comprising a box body; the supporting plate is arranged in the shell and forms a refrigerating chamber; the refrigerating column is positioned in the refrigerating chamber; the rotating column is arranged on the refrigerating column, penetrates through the supporting plate and is rotatably connected with the lower cover plate; the driving structure is arranged in the control room; the cold storage tanks are all arranged on the outer circumferential wall of the cold storage column; the temperature sensor is arranged in each refrigerating groove; the air passing chamber is arranged in the refrigerating column; the air inlet channel is respectively connected with the adjacent refrigerating chamber and the air passing chamber; one end of the air inlet pipe is embedded into the refrigeration column and communicated with the air passing chamber, and the other end of the air inlet pipe extends into the central groove; the automatic output equipment is arranged on the refrigeration column; the discharge channel is arranged in the shell and is used for receiving the plasma bag sent out from the refrigerating groove by the automatic output equipment; the invention has the advantages of convenient use, long refrigeration time, difficult blood plasma taking by mistake and the like.

Description

Automatic blood bank and automatic output equipment thereof

Technical Field

The invention relates to the technical field of medical equipment, in particular to an automatic blood bank and automatic output equipment thereof.

Background

The blood bank is a functional department of the hospital and is responsible for checking the blood type of patients, storing blood samples and blood products and matching blood for transfusion patients.

In some first-aid processes that need blood, hospital's ambulance can carry some plasma to the scene and carry out direct blood transfusion for the patient, plasma just need use within 4 hours after leaving the blood storehouse, otherwise plasma will become invalid, current opportunity car all can be equipped with and remove the blood storehouse, increase the save time of plasma, but current removal blood storehouse simple structure, mainly deposit in the incubator, in the in-process of depositing, various blood types are chaotic to be put, blood type mistake when easily causing the blood transfusion, and the incubator is when opening, the air conditioning is lost sooner, lead to unused plasma save time to shorten, not only brought economic loss, also wasted the resource.

Disclosure of Invention

The technical problem to be solved by the invention is to provide an automatic blood bank and an automatic output device thereof, so as to solve the problems of poor orderliness and short plasma storage time when the mobile blood bank is used in the prior art described in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: an automated blood bank comprising

The refrigerator comprises a box body, a refrigerator body and a control device, wherein the box body is provided with a shell, an upper cover plate and a lower cover plate which are connected with the shell, and a refrigerating chamber, a control chamber and a driving chamber are arranged in the shell;

the supporting plate is arranged in the shell and forms a refrigerating chamber;

a refrigerating column located in the refrigerating chamber, an outer circumferential wall of the refrigerating column being in sliding contact with an inner circumferential wall of the refrigerating chamber;

the rotating column is arranged on the refrigerating column, penetrates through the supporting plate and is rotatably connected with the lower cover plate;

the driving structure is arranged in the control chamber and used for driving the rotating column to rotate so as to drive the refrigerating column to rotate in the refrigerating chamber;

the plurality of refrigerating grooves are arranged on the outer circumferential wall of the refrigerating column;

a plurality of temperature sensors respectively arranged in each refrigerating groove;

the air passing chambers are arranged in the refrigerating column, and every two air passing chambers are respectively distributed with every two refrigerating grooves at intervals;

the plurality of air inlet channels are respectively connected with the adjacent refrigerating chambers and the air passing chambers;

the central groove is arranged on the upper surface of the refrigeration column;

one end of the air inlet pipe is embedded into the refrigeration column and communicated with the air passing chamber, and the other end of the air inlet pipe extends into the central groove;

the gas collecting box is connected to the upper cover plate, a rotatable rotating plate is arranged on the lower end wall of the gas collecting box, and a gas outlet pipe communicated with the gas inlet pipe is arranged on the rotating plate;

the refrigeration tank is arranged in the refrigeration chamber and is communicated with the gas collecting box through a connecting pipe;

the automatic output equipment is arranged on the refrigeration column;

the discharge channel is arranged in the shell and is used for receiving the plasma bag sent out from the refrigerating groove by the automatic output equipment;

the discharge hole is arranged on the side wall of the discharge channel;

the partition plate is movably arranged on the shell and used for blocking the discharge hole from being communicated with the discharge channel;

the electric cabinet is arranged in the control room and is provided with a control panel embedded on the side wall of the shell.

Preferably: the driving structure comprises

The servo motor is arranged on the supporting plate and is positioned in the control chamber;

the gear ring is sleeved on the rotating column;

and the gear is arranged at the output end of the servo motor and is meshed with the gear ring.

Preferably: the number of the refrigerating grooves is at least four, and the refrigerating grooves are used for storing four different blood types.

Preferably: the distance between the notches of two adjacent refrigerating grooves is larger than the width of the discharging channel.

Preferably, the following components: the shell is provided with a sliding hole, the horizontal position of the upper end wall of the sliding hole is higher than that of the lower end wall of the discharge hole, and the horizontal position of the lower end wall of the sliding hole is lower than that of the lower end wall of the discharge hole.

Preferably: the partition board is also provided with a push plate, the width of the push plate is larger than that of the sliding hole, and the shell is also provided with a hiding groove for hiding the push plate.

Preferably: the shell is also provided with a limiting structure for limiting the movement of the push plate, and the limiting structure comprises

The rotating groove is arranged on the side wall of one side of the hiding groove;

the clamping groove is arranged on the push plate at a position corresponding to the rotating groove;

the cardboard rotates and sets up in rotating the inslot, and this cardboard can change over to leave hidden groove with the restriction push pedal in the draw-in groove.

An automatic blood bank and its automatic output device, the automatic output device includes

The cylinder is connected to the upper cover plate and is positioned in the central groove;

the first sliding chutes are respectively arranged on the upper end walls of the refrigerating chutes and penetrate through the outer circumferential surface of the refrigerating column;

the through holes are arranged on the inner wall of the central groove and are respectively communicated with the first sliding grooves;

the moving plate is arranged in the first sliding groove in a sliding mode, and a plurality of hooks for hanging the plasma bag are arranged on the moving plate;

the electromagnet is arranged on an output shaft of the cylinder and used for adsorbing the moving plate;

the second sliding groove is arranged on the upper end wall of the discharging channel and used for receiving the moving plate slid out by the first sliding groove.

The positioning plate is connected to the outer wall of the cylinder;

the connecting rod is connected with the positioning plate and the upper cover plate.

Preferably: be provided with industrial computer and battery in this electric cabinet, this industrial computer respectively with battery, control panel, refrigeration jar, temperature sensor, solenoid valve, electro-magnet, servo motor electric connection.

The beneficial effect of adopting above technical scheme is:

set up a plurality of cold-stored grooves on the cold-stored post of this application, a plasma for cold-stored different blood types, work as and refrigerate alone every cold-stored groove, can effectual improvement to the cold-stored effect of plasma, it rotates to drive cold-stored post through driving motor, make cold-stored groove align with discharging channel, then push away the movable plate to the second spout on discharging channel through the cylinder in, then take out plasma through the discharge gate, and the turned angle of the cold-stored post of the accurate control of drive structure, make the plasma in the cold-stored groove of corresponding blood type get into discharging channel, this application is taking out the cold-stored of plasma that plasma can not influence other blood types, can the cold-stored time of effectual improvement.

Drawings

FIG. 1 is a front view of an automated blood bank and its automated output device of the present invention.

Fig. 2 is a schematic structural diagram of an automated blood bank and its automatic output device according to the present invention.

Fig. 3 is a cross-sectional view taken at a-a of fig. 1 in accordance with the present invention.

Fig. 4 is an enlarged view of a portion of fig. 3 of the present invention.

FIG. 5 is a front view of the cold storage column of the present invention.

Fig. 6 is a cross-sectional view at B-B of fig. 1 of the present invention.

Fig. 7 is a right side view of an automated blood bank and its automated output device of the present invention.

Fig. 8 is an enlarged view of a portion of the invention at C in fig. 7.

Wherein: the refrigerator comprises a box body 100, a shell 110, a refrigerating chamber 111, a refrigerating chamber 112, a control chamber 113, a driving chamber 114, a lower cover plate 120, an upper cover plate 130, a support plate 200, a refrigerating column 300, a rotating column 301, a central groove 310, a refrigerating groove 320, an air passing chamber 330, an air inlet channel 340, an air inlet pipe 350, a solenoid valve 360, an air collecting box 370, a rotating plate 371, an air outlet pipe 372, a connecting pipe 373, a refrigerating tank 374, a temperature sensor 380, an automatic output device 400, a moving plate 410, a hook 420, a first sliding groove 430, a through hole 440, an air cylinder 450, a positioning plate 451, a connecting rod 452, an electromagnet 460, a discharge channel 470, a discharge hole 471, a partition plate 472, a sliding hole 473, a push plate 474, a hidden groove 475, a second sliding groove 476, a rotating groove 480, a clamping plate 481, a clamping groove 482, a driving structure 500, a servo motor 510, a gear 520, a gear 530, an electric cabinet 600 and a control panel 610.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1-8, in the first embodiment, an automated blood bank and an automatic output device thereof comprise

A cabinet 100 having a casing 110, and an upper cover 130 and a lower cover 120 connected to the casing 110, the casing 100 having a refrigeration compartment 112, a control compartment 113, and a driving compartment 114;

a support plate 200 disposed in the casing 110 and forming a refrigerating chamber 111;

a refrigerating column 300 positioned inside the refrigerating chamber 111, an outer circumferential wall of the refrigerating column 300 being in sliding contact with an inner circumferential wall of the refrigerating chamber 111;

the rotating column 301 is arranged on the refrigerating column 300, and the rotating column 301 penetrates through the support plate 200 and is rotatably connected with the lower cover plate 120;

the driving structure is arranged in the control room 114 and used for driving the rotating column 301 to rotate so as to drive the refrigerating column 300 to rotate in the refrigerating chamber 111;

a plurality of refrigerating grooves 320, each of which is provided on the outer circumferential wall of the refrigerating column 300;

a plurality of temperature sensors 370 disposed in each of the refrigerating compartments 320;

a plurality of air passing chambers 330 disposed in the refrigerating column 300, wherein every two air passing chambers 330 are respectively spaced from every two refrigerating tanks 320;

a plurality of air inlet passages 340 respectively connecting adjacent refrigerating compartments 320 and air passing chambers 330;

a central groove 310 provided on an upper surface of the refrigerating column 300;

an air inlet pipe 350, one end of which is embedded in the cold storage column 300 and communicated with the air passing chamber 330, and the other end of which extends into the central groove 310, wherein the air inlet pipe 350 is also provided with an electromagnetic valve 360;

the gas collecting box 370 is connected to the upper cover plate 130, the lower end wall of the gas collecting box 370 is provided with a rotatable rotating plate 371, and the rotating plate 371 is provided with a gas outlet tube 372 communicated with the gas inlet tube 350;

a refrigeration tank 374 disposed in the refrigeration compartment 112, the refrigeration tank 374 being in communication with the vapor collection box 370 via a connection 373;

an automatic output device 400 provided on the refrigerating column 300;

an outlet channel 470 disposed in the housing 110, the outlet channel 470 being configured to receive a plasma bag from the cold storage tank 320 of the automatic output device 400;

a discharge port 471 arranged on the side wall of the discharge channel 470;

a partition 472 movably disposed on the casing 110 for blocking the discharge port 471 from communicating with the discharge channel 470;

the electric cabinet 600 is disposed in the control room 113, and the electric cabinet 600 has a control panel 610 embedded in the side wall of the housing 110.

The present embodiment is implemented as follows:

when the plasma temperature control device is used, cold air is sent into the gas collecting box 370 through the connecting pipe 373 by the arranged refrigeration tank 374, then is guided into the air chamber 330 through the air outlet pipe 372 and the air inlet pipe 350, and then enters the refrigeration groove 320 through the air inlet channel 340 to cool plasma, the temperature in the refrigeration groove 320 is sensed by the arranged temperature sensor 380, when the temperature reaches a set value, the electromagnetic valve 360 is closed, otherwise, the electromagnetic valve 350 is opened; the plasma can be refrigerated independently, and the energy-saving effect is achieved; the cold air in the application can play a role in cooling the whole refrigeration column 300 through the air passing chamber 330;

when plasma is taken out to needs, drive cold-stored post 300 reciprocating rotation through the drive structure 500 that sets up, the biggest angle of rotation is 360 degrees, in order to reduce the pipe fitting winding, in the pivoted in-process because outlet duct 372 is connected with intake pipe 350, consequently, can drive rotor plate 371 and rotate, can prevent to twine on a large scale, in order to protect the pipe fitting, and rotate the cold-stored groove 320 that corresponds the blood group place to the position that corresponds discharging channel 370, then can deliver to discharging channel 470 in with plasma through the automatic output device 400 that sets up, then take out plasma from discharge gate 471 through opening baffle 472, and there is not the influence to the cold-stored of the plasma of other blood groups this moment, can be very big improvement plasma save time.

As a further optimization scheme of the present embodiment: the driving structure comprises

A servo motor 510 disposed on the support plate 200 and located in the control chamber 114;

the gear ring 530 is sleeved on the rotating column 301;

and a gear 520 provided at an output end of the servo motor 510 and engaged with the ring gear 530.

This optimization scheme can drive gear 520 through the servo motor 510 that sets up and rotate, and gear 520 drives ring gear 530 and rotates, and ring gear 530 drives rotation post 301 and is rotating, can realize the accurate control to rotation post 301 turned angle.

As a further optimization scheme of the embodiment: the number of the refrigerating compartments 320 is at least four, and four different blood types are stored.

This optimization scheme puts into the plasma of different blood types in the cold-stored groove of difference, then through the turned angle of the control panel control drive structure who sets up to take out corresponding plasma.

Example two

As an optimization of the first embodiment, the distance between the notches of two adjacent refrigerating slots 320 is larger than the width of the discharging channel 470.

This embodiment is implemented like this, after plasma got into discharging channel 470 under automatic output device 400's effect, servo motor 510 will restart this moment, drive rotation post 301 and rotate certain angle for the arcwall face between two adjacent cold-stored grooves 320 is to discharging channel 470, and this just can reduce the loss of the interior cold air of cold-stored groove 320, improves the heat preservation effect.

EXAMPLE III

As an optimization scheme of the first embodiment, the housing 110 has a sliding hole 473, the horizontal position of the upper end wall of the sliding hole 473 is higher than that of the lower end wall of the discharging port 471, and the horizontal position of the lower end wall of the sliding hole 473 is lower than that of the lower end wall of the discharging port 471.

This embodiment is implemented like this, through extending the upper and lower both ends with slide-hole 475 to exceeding discharge gate 471 for baffle 472 increases the isolated effect of discharge gate 471 and discharging channel 470, is more favorable to blockking to cold air.

As a further optimization scheme of the present embodiment:

the spacer 472 further has a push plate 474 having a width larger than that of the slide hole 473, and the housing 110 further has a concealing slot 475 for concealing the push plate 474.

This optimization scheme through the push pedal 474 that sets up and hide the design of groove 475, can hide the push pedal 474 in hiding the groove 475, improves the convenience of using.

As a further optimization scheme of the embodiment: the housing 110 is further provided with a limiting structure for limiting the movement of the pushing plate 474, and the limiting structure comprises

A rotation groove 480 provided on one side wall of the hidden groove 474;

a locking groove 482, which is arranged on the push plate 475 at a position corresponding to the rotating groove 480;

a catch plate 481 rotatably disposed in the rotary groove 480, the catch plate 481 being rotatable into the catch groove 482 to restrict the push plate 475 from exiting the hidden groove 474

This optimization scheme through rotating the cardboard, can change over into the draw-in groove 482 with the one end of cardboard 481 for push pedal 474 can not leave and hide groove 475, prevents that external vibrations from making baffle 472 remove.

Example four

As an optimization of the above embodiment, the automatic output device 400 includes

A cylinder 450 connected to the upper cover plate 130 and located in the central groove 310;

a plurality of first sliding grooves 430 respectively formed at the upper end wall of the refrigerating groove 320, the first sliding grooves 430 penetrating the outer circumferential surface of the refrigerating column 300;

a plurality of through holes 440 disposed on an inner wall of the central groove 310, the plurality of through holes 440 being respectively communicated with the first sliding grooves 430;

a moving plate 410 slidably disposed in the first sliding groove 430, wherein the moving plate 410 has a plurality of hooks 420 for hanging a plasma bag;

an electromagnet 469 disposed on the output shaft of the cylinder 450 for attracting the moving plate 410;

a second chute 476 provided in the upper end wall of the discharging passage 470 for receiving the moving plate 410 slid out of the first chute 439;

a positioning plate 451 attached to an outer wall of the cylinder 450;

the connecting rod 452 connects the positioning plate 451 and the upper cover 130.

In this embodiment, when plasma is taken, the air cylinder 450 drives the electromagnet 460 to pass through the through hole 440 and enter the first chute 430, the moving plate 410 is sucked by the electromagnet 460, then the air cylinder 450 is started to continue to drive the moving plate 410 to enter the second chute 476, at this time, the moving plate 410 drives the plasma bag on the hook 420 to enter the discharging channel 470, and after the plasma is taken out, the air cylinder 450 drives the moving plate 410 to enter the first chute 430 through the electromagnet 460.

As a further optimization scheme of the present embodiment: an industrial personal computer and a storage battery are arranged in the electric cabinet 600, and the industrial personal computer is electrically connected with the storage battery, the control panel 610, the refrigeration tank 374, the temperature sensor 380, the electromagnetic valve 360, the electromagnet 460 and the servo motor 510 respectively.

This optimization scheme, industrial computer cooperation control panel 610 through in the electric cabinet 600 can realize getting intelligent, the automated control of plasma to also can improve the save time of plasma.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many variations and modifications can be made without departing from the inventive concept of the present invention, which falls into the protection scope of the present invention.

Claims (7)

1. An automated blood bank, comprising: comprises that

The refrigerator comprises a box body, a refrigerator body and a control device, wherein the box body is provided with a shell, an upper cover plate and a lower cover plate which are connected with the shell, and a refrigerating chamber, a control chamber and a driving chamber are arranged in the shell;

the supporting plate is arranged in the shell and forms a refrigerating chamber;

a refrigerating column located in the refrigerating chamber, an outer circumferential wall of the refrigerating column being in sliding contact with an inner circumferential wall of the refrigerating chamber;

the rotating column is arranged on the refrigerating column, penetrates through the supporting plate and is rotatably connected with the lower cover plate;

the driving structure is arranged in the control chamber and used for driving the rotating column to rotate so as to drive the refrigerating column to rotate in the refrigerating chamber;

the plurality of refrigerating grooves are arranged on the outer circumferential wall of the refrigerating column; the number of the refrigerating grooves is at least four, the refrigerating grooves are used for storing four different blood types, and the distance between the notches of two adjacent refrigerating grooves is larger than the width of the discharging channel;

a plurality of temperature sensors respectively arranged in each refrigerating groove;

the air passing chambers are arranged in the refrigerating column, and every two air passing chambers are respectively distributed at intervals with every two refrigerating grooves;

the plurality of air inlet channels are respectively connected with the adjacent refrigerating chambers and the air passing chambers;

the central groove is arranged on the upper surface of the refrigeration column;

one end of the air inlet pipe is embedded into the refrigeration column and communicated with the air passing chamber, and the other end of the air inlet pipe extends into the central groove;

the gas collecting box is connected to the upper cover plate, a rotatable rotating plate is arranged on the lower end wall of the gas collecting box, and a gas outlet pipe communicated with the gas inlet pipe is arranged on the rotating plate;

the refrigeration tank is arranged in the refrigeration chamber and is communicated with the gas collecting box through a connecting pipe;

the automatic output equipment is arranged on the refrigerating column;

the discharge channel is arranged in the shell and is used for receiving the plasma bag sent out from the refrigerating groove by the automatic output equipment;

the discharge port is arranged on the side wall of the discharge channel;

the partition plate is movably arranged on the shell and used for blocking the discharge hole from being communicated with the discharge channel;

the electric cabinet is arranged in the control room and is provided with a control panel embedded on the side wall of the shell;

the automatic output device includes

The cylinder is connected to the upper cover plate and is positioned in the central groove;

the first sliding chutes are respectively arranged on the upper end walls of the refrigerating chutes and penetrate through the outer circumferential surface of the refrigerating column;

the through holes are arranged on the inner wall of the central groove and are respectively communicated with the first sliding grooves;

the moving plate is arranged in the first sliding groove in a sliding mode, and a plurality of hooks for hanging the plasma bag are arranged on the moving plate;

the electromagnet is arranged on the output shaft of the air cylinder and used for adsorbing the moving plate;

the second chute is arranged on the upper end wall of the discharge channel and used for receiving the movable plate slid out by the first chute;

the positioning plate is connected to the outer wall of the cylinder;

the connecting rod is connected with the positioning plate and the upper cover plate.

2. An automated blood bank according to claim 1, wherein the drive mechanism comprises

The servo motor is arranged on the supporting plate and is positioned in the control chamber;

the gear ring is sleeved on the rotating column;

and the gear is arranged at the output end of the servo motor and is meshed with the gear ring.

3. The automated blood bank of claim 1, wherein the housing has a slide hole, the slide hole has an upper end wall with a horizontal position higher than a horizontal position of the lower end wall of the outlet, and the slide hole has a lower end wall with a horizontal position lower than the horizontal position of the lower end wall of the outlet.

4. The automated blood bank of claim 3, wherein the partition further comprises a push plate having a width greater than the width of the slide hole, and the housing further comprises a hidden slot for hiding the push plate.

5. The automated blood bank of claim 4, wherein the housing further comprises a limiting structure for limiting the movement of the push plate, the limiting structure comprising

The rotating groove is arranged on the side wall of one side of the hiding groove;

the clamping groove is arranged on the push plate at a position corresponding to the rotating groove;

the cardboard rotates and sets up in rotating the inslot, and this cardboard can change over to leave hidden groove with the restriction push pedal in the draw-in groove.

6. The automated blood bank of claim 2, wherein an industrial personal computer and a storage battery are arranged in the electric cabinet, and the industrial personal computer is electrically connected with the storage battery, the control panel, the refrigeration tank, the temperature sensor, the electromagnetic valve, the electromagnet and the servo motor respectively.

7. The use method of the automatic blood bank according to claim 1, wherein the cold air is sent into the air collecting box through the connecting pipe by the arranged refrigeration tank, then is guided into the air chamber through the air outlet pipe and the air inlet pipe, and then enters the refrigerating tank through the air inlet channel to cool the blood plasma, the temperature in the refrigerating tank is sensed by the arranged temperature sensor, when the temperature reaches a set value, the electromagnetic valve is closed, otherwise, the electromagnetic valve is opened; the plasma can be refrigerated independently, and the energy-saving effect is achieved; the cold air passes through the air chamber, so that the effect of cooling the whole refrigerating column can be achieved;

when needs take out plasma, drive cold-stored post reciprocating rotation through the drive structure that sets up, the biggest angle of rotation is 360 degrees, in order to reduce the pipe fitting winding, in the pivoted in-process because outlet duct and air-intake connection, consequently, can drive the rotor plate and rotate, can prevent to twine on a large scale, in order to protect the pipe fitting, and rotate the cold-stored groove that corresponds the blood type place to the position that corresponds discharging channel, then can deliver to discharging channel with plasma in through the automatic output equipment who sets up, then take out plasma from the discharge gate through opening the baffle, and do not influence this moment to the cold-stored of the plasma of other blood types, can be very big improvement plasma's save time.

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