CN114104520B

CN114104520B - Salvia miltiorrhiza injection constant temperature storage facilities

Info

Publication number: CN114104520B
Application number: CN202210032742.7A
Authority: CN
Inventors: 谭欢钦; 沈平平; 李明明
Original assignee: JIANGSU SHENLONG PHARMACEUTICAL CO Ltd
Current assignee: JIANGSU SHENLONG PHARMACEUTICAL CO Ltd
Priority date: 2022-01-12
Filing date: 2022-01-12
Publication date: 2022-09-20
Anticipated expiration: 2042-01-12
Also published as: CN114104520A

Abstract

The invention discloses a salvia miltiorrhiza injection constant-temperature storage device, wherein the upper part of a shell is rotatably connected with a cover plate, a containing cavity is formed in the shell, a heat-insulation layer is fixedly arranged on the inner wall of the containing cavity, an inner container is slidably connected in the containing cavity and is connected with the bottom wall of the containing cavity through an oscillating mechanism, more than two placing grooves are uniformly formed in the inner container, a lifting mechanism comprises a buffer air bag fixedly arranged at the bottom of the placing grooves, a cooling mechanism comprises a liquid storage bag which is funnel-shaped and fixedly connected with the buffer air bag, a fastening rubber ring is fixedly arranged at the center of the liquid storage bag, and a control panel is fixedly arranged on one side of the shell. According to the invention, the liquid storage bag is arranged in the placing groove, and the liquid storage bag is used for wrapping and fixing the injection bottle, so that the injection bottle can be uniformly heated at all places, and meanwhile, the liquid in the liquid storage bag has fluidity and can play a role of buffering when the shell is impacted, thereby protecting the injection bottle from being damaged.

Description

Salvia miltiorrhiza injection constant temperature storage facilities

Technical Field

The invention relates to the technical field of medical equipment, in particular to a constant-temperature storage device for a salvia miltiorrhiza injection.

Background

Modern medical and clinical experiments show that the salvia miltiorrhiza has the effects of expanding coronary arteries, increasing the blood flow of the coronary arteries, slowing down the heart rate, improving myocardial anoxia and the like in the aspect of cardiovascular, can be used for treating symptoms of angina pectoris, chest distress, palpitation, myocardial infarction and the like of coronary heart disease, and is used for resisting thrombosis and coagulation. The existing salvia miltiorrhiza injection storage device generally adopts a mode of arranging a refrigeration piece or a refrigeration fan in a storage box to cool a medicine bottle, but the refrigeration effect of the mode on the salvia miltiorrhiza injection is unstable, and the temperature close to one side of the refrigeration piece or the refrigeration fan is generally lower than that of other places, so that the injection in the storage box is cooled unevenly.

Disclosure of Invention

The invention aims to solve the technical problem that the existing salvia miltiorrhiza injection storage device is unstable in refrigeration effect and causes uneven internal temperature. In order to overcome the defects of the prior art, the invention provides the salvia miltiorrhiza injection constant-temperature storage equipment, the liquid storage bag is arranged in the placing groove, and the injection bottle is wrapped and fixed by the liquid storage bag, so that the injection bottle can be uniformly heated at all places, and meanwhile, the liquid in the liquid storage bag has fluidity and can play a role in buffering when the shell is impacted, thereby protecting the injection bottle from being damaged.

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

the invention provides a salvia miltiorrhiza injection constant-temperature storage device which comprises a shell, a cover plate, a heat-insulating layer, an inner container, an oscillating mechanism, a cooling mechanism, a lifting mechanism and a control panel, wherein the upper part of the shell is rotatably connected with the cover plate, a containing cavity is formed in the shell, the heat-insulating layer is fixedly arranged on the inner wall of the containing cavity, the inner container is connected in the containing cavity in a sliding manner, the inner container is connected with the bottom wall of the containing cavity through the oscillating mechanism, more than two placing grooves are uniformly formed in the inner container, the lifting mechanism comprises a buffer air bag which is fixedly arranged at the bottom of the placing grooves, the cooling mechanism comprises a liquid storage bag which is funnel-shaped, the liquid storage bag is fixedly connected with the buffer air bag, a fastening rubber ring is fixedly arranged in the center of the liquid storage bag, and the control panel is fixedly arranged on one side of the shell.

In a preferred technical scheme of the invention, the oscillating mechanism comprises a vibrating motor, a triangular block, an arc-shaped plate and a first compression spring, the vibrating motor is symmetrically arranged at the bottom of the inner container in the left-right direction, the triangular block is fixedly arranged at the power output end of the vibrating motor, a sliding groove is formed below the accommodating cavity, the arc-shaped plate is connected in the sliding groove in a sliding manner, two ends of the arc-shaped plate are connected with the side wall of the sliding groove through the first compression spring, and the triangular block is abutted against the arc-shaped plate.

In a preferred technical scheme of the invention, the cooling mechanism further comprises a cooling liquid storage box, a water pump, a first shunt pipe, a first collecting pipe, a first corrugated hose, a second corrugated hose, a water inlet pipe, a water outlet pipe, a one-way valve, a temperature sensor and a cooling fin, wherein a working cavity is formed in one side of the accommodating cavity and communicated with the accommodating cavity, the cooling liquid storage box is arranged in the working cavity, the water pump is fixedly arranged on the cooling liquid storage box, the first shunt pipe and the first collecting pipe are embedded in the top of the inner container, the first shunt pipe and the first collecting pipe are symmetrically arranged on two sides of the placing groove, the first shunt pipe is connected with the water pump through the first corrugated hose, the first collecting pipe is connected with the cooling liquid storage box through the second corrugated hose, one end of the liquid storage bag is connected with the first shunt pipe through the water inlet pipe, the other end of the liquid storage bag is connected with the first collecting pipe through the water outlet pipe, the water outlet pipe is internally and fixedly provided with a one-way valve, the cooling liquid storage box is internally and fixedly provided with a temperature sensor and a cooling fin, and the temperature sensor and the cooling fin are electrically connected with the control panel.

In a preferred technical scheme of the invention, the lifting mechanism further comprises a control assembly, a second shunt pipe, an air inlet pipe, an air blower and a second compression spring, the buffer air bag is fixedly connected with the bottom wall of the placing groove through the control assembly, the second shunt pipe is embedded below the placing groove and connected with the control assembly through the air inlet pipe, the air blower is fixedly arranged at the bottom of the inner container and connected with the second shunt pipe, and the second compression spring is arranged in the buffer air bag.

In a preferred technical scheme of the invention, the control assembly comprises a control box, a sealing slide block, a flow distribution plate, a control motor, a rotating gear and an air outlet pipe, wherein a control cavity is formed in the control box, the sealing slide block is connected in the control cavity in a sliding manner, the flow distribution plate is fixedly arranged at the top of the sealing slide block, a groove is formed below the control cavity, the control motor is embedded in the side wall of the groove, the rotating gear is fixedly arranged at the power output end of the control motor, the rotating gear is meshed with the gear of the sealing slide block, the buffering air bag is fixedly arranged at the top of the control box and is communicated with the control cavity, the air inlet pipe and the air outlet pipe are connected to the bottom of the control box, and the air inlet pipe and the air outlet pipe are symmetrically arranged at two sides of the sealing slide block.

In a preferred technical scheme of the invention, a spherical rubber block is fixedly arranged on the inner side of the cover plate, and the spherical rubber block is in inserted fit with the placing groove.

In a preferred technical scheme of the invention, the heat insulation layer is made of rock wool material.

The invention has the beneficial effects that:

1. through set up the reservoir in the standing groove, utilize the fixed injection bottle of reservoir parcel, can enough guarantee that injection bottle each department is heated evenly, liquid in the reservoir has the mobility simultaneously, can receive the cushioning effect when the casing receives the striking to the protection injection bottle does not receive the damage.

2. Through the arrangement of the oscillating mechanism, the vibrating motor is utilized to drive the triangular block to rotate, and then the triangular block and the arc-shaped plate generate a relative action to drive the inner container to move up and down, so that the injection in the injection bottle is oscillated to prevent the generation of precipitation; simultaneously when the casing receives violent impact, the inner bag can extrude the arc and make it take place elastic deformation to make first compression spring shrink, and then can absorb partly vibration energy, reduce the impact force that the inner bag received.

3. Through setting up hoist mechanism, when medical personnel need get it filled, the panel control buffering gasbag inflation is controlled in the utilization, and then makes the injection bottle stretch out the standing groove, makes things convenient for medical personnel to take, has improved user's use and has experienced.

Drawings

FIG. 1 is a schematic structural diagram of a constant-temperature storage device for Salvia miltiorrhiza Bunge injecta according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1;

FIG. 3 is an enlarged schematic view at B of FIG. 1;

fig. 4 is an enlarged schematic view at C in fig. 3.

In the figure:

1. a housing; 11. an accommodating chamber; 12. a working chamber; 13. a chute; 2. a cover plate; 3. a heat insulation layer; 4. an inner container; 41. a placement groove; 5. an oscillating mechanism; 51. a vibration motor; 52. a triangular block; 53. an arc-shaped plate; 54. a first compression spring; 6. a cooling mechanism; 601. a reservoir; 602. a coolant storage tank; 603. a water pump; 604. a first shunt pipe; 605. a first collection pipe; 606. a first bellows tube; 607. a second corrugated hose; 608. a water inlet pipe; 609. a water outlet pipe; 610. a one-way valve; 611. a temperature sensor; 612. a cooling fin; 62. fastening a rubber ring; 7. a lifting mechanism; 71. a buffer air bag; 72. a control component; 721. a control box; 722. sealing the sliding block; 723. a splitter plate; 724. controlling the motor; 725. a rotating gear; 726. a control chamber; 727. a groove; 728. an air outlet pipe; 73. a second shunt pipe; 74. an air inlet pipe; 75. a blower; 76. a second compression spring; 8. a control panel; 9. a spherical rubber block; 10. and (4) injection bottles.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

As shown in fig. 1-4, the embodiment provides a salvia miltiorrhiza injection constant-temperature storage device, which comprises a housing 1, a cover plate 2, a heat-insulating layer 3, an inner container 4, an oscillating mechanism 5, a cooling mechanism 6, a lifting mechanism 7 and a control panel 8, wherein the upper part of the housing 1 is rotatably connected with the cover plate 2, a containing cavity 11 is formed in the housing 1, the heat-insulating layer 3 is fixedly arranged on the inner wall of the containing cavity 11, the inner container 4 is slidably connected with the containing cavity 11, the inner container 4 is connected with the bottom wall of the containing cavity 11 through the oscillating mechanism 5, more than two placing grooves 41 are uniformly formed in the inner container 4, the lifting mechanism 7 comprises a buffer air bag 71, the buffer air bag 71 is fixedly arranged at the bottom of the placing groove 41, the cooling mechanism 6 comprises a liquid storage bag 601, and the liquid storage bag 601 is funnel-shaped, the liquid storage bag 601 is fixedly connected with the buffer air bag 71, the center of the liquid storage bag 601 is also fixedly provided with a fastening rubber ring 62, and one side of the shell 1 is fixedly provided with the control panel 8.

In this embodiment, the bottom of casing 1 inner wall and side apron 2 all is provided with thermal insulation layer 3, and when apron 2 closed, thermal insulation layer 3 formed inclosed space to prevent to hold the heat effluvium in the chamber 11, help reducing the energy consumption. The inner container 4 is also made of heat preservation and insulation materials, so that the loss of cold energy in the liquid storage bag 601 can be reduced, and the injection in the injection bottle 10 can be uniformly cooled. Reservoir 601 is preferably made of high elastic material such as rubber, can produce great elastic deformation, reservoir 601 is infundibulate structure, and reservoir 601's maximum diameter is greater than the diameter of standing groove 41, the top is provided with the inverted cone shape groove, make things convenient for medical personnel to put into the medicine, fastening rubber circle 62 sets up in the pointed end of inverted cone shape groove, and fastening rubber circle 62 and reservoir 601 fixed connection, fastening rubber circle 62's diameter slightly is less than the bottom diameter of injection bottle 10, the inside coolant liquid that is provided with of reservoir 601. The fastening rubber ring 62 can be elastically deformed largely when a force is applied. The oscillating mechanism 5 can conveniently oscillate and shake the injection in the injection bottle 10, so that the long-term standing is prevented from causing precipitation, and the oscillating mechanism 5, the cooling mechanism 6 and the lifting mechanism 7 are all electrically connected with the control panel 8. When the medical staff needs to store the injection bottle 10, the injection bottle 10 is put into the inverted cone-shaped groove of the reservoir 601, and the bottom of the injection bottle 10 is clamped into the fastening rubber ring 62, so that the injection bottle is fixedly connected with the liquid storage bag 601, then the lifting mechanism 7 is started, the lifting mechanism 7 controls the buffer air bag 71 to contract, and then the liquid storage bag 601 is pulled into the placing groove 41, the liquid storage bag 601 generates elastic deformation in the moving process, then the cooling mechanism 6 is started, the cooling mechanism 6 circularly introduces cooling liquid into the liquid storage bag 601, and further the liquid storage bag 601 is inflated until the injection bottle 10 is completely wrapped, because the internal temperature of the cooling liquid is even, the injection liquid can be uniformly cooled, and the inner container 4 is made of a heat-insulating material, the loss of the cooling capacity of the cooling liquid in the liquid storage bag 601 can be reduced, the energy consumption can be reduced, and the storage cost can be reduced.

Specifically, oscillating mechanism 5 includes vibrating motor 51, three hornblocks 52, arc 53 and

first compression spring

54, and 4 bottom bilateral symmetry of inner bag are provided with vibrating motor 51, and three hornblocks 52 set firmly in vibrating motor 51's power take off end, hold the chamber 11 below and seted up spout 13, and sliding connection has arc 53 in spout 13, and the both ends of arc 53 all are connected with spout 13 lateral wall through first compression spring 54, three hornblocks 52 and arc 53 butt. In this embodiment, the vibration motors 51 are electrically connected to the control panel 8, and the two vibration motors 51 are symmetrically disposed on two sides of the arc-shaped plate 53. The arc plate 53 is an elastic plate, and can be elastically deformed when receiving pressure, and the outer side wall of the arc plate 53 abuts against the inner container 4. During the use, control vibrating motor 51 through controlling panel 8 and start, vibrating motor 51 drives triangle block 52 and rotates, and triangle block 52 is interrupted the contact with arc 53 lateral wall, and then makes the continuous up-and-down reciprocating motion of inner bag 4 produce the vibration, and then prevents that the injection in injection bottle 10 from producing the sediment. Meanwhile, when the housing 1 is severely impacted, the liner 4 can slide up and down along the accommodating cavity 11, so as to extrude the arc-shaped plate 53 to elastically deform the arc-shaped plate, and the first compression spring 54 contracts to absorb a part of vibration energy and reduce the impact force on the liner 4. In another embodiment, the cam blocks 52 may also be replaced with cams.

Specifically, the cooling mechanism 6 further includes a coolant storage tank 602, a water pump 603, a first shunt tube 604, a first collecting tube 605, a first corrugated hose 606, a second corrugated hose 607, a water inlet tube 608, a water outlet tube 609, a one-way valve 610, a temperature sensor 611, and a cooling fin 612, a working chamber 12 is formed in one side of the accommodating chamber 11, the working chamber 12 is communicated with the accommodating chamber 11, the coolant storage tank 602 is disposed in the working chamber 12, the water pump 603 is fixedly disposed on the coolant storage tank 602, the first shunt tube 604 and the first collecting tube 605 are embedded in the top of the inner container 4, the first shunt tube 604 and the first collecting tube 605 are symmetrically disposed on two sides of the placement groove 41, the first shunt tube 604 is connected with the water pump 603 through the first corrugated hose 606, the first collecting tube 605 is connected with the coolant storage tank 602 through the second corrugated hose 607, one end of the reservoir 601 is connected with the first shunt tube 604 through the water inlet tube 608, the other end of the reservoir 601 is connected with the first collecting tube 605 through the water outlet tube 609, the outlet pipe 609 is fixedly provided with a check valve 610, the cooling liquid storage tank 602 is also fixedly provided with a temperature sensor 611 and a cooling fin 612, and the temperature sensor 611 and the cooling fin 612 are both electrically connected with the control panel 8. In this embodiment, the water pump 603, the temperature sensor 611, and the cooling fin 612 are all electrically connected to the control panel 8, and the model of the temperature sensor 611 is preferably DS18B 20. The first corrugated hose 606 and the second corrugated hose 607 can be extended or contracted along with the up-and-down movement of the inner container 4, and the corrugated hoses have excellent flexibility and kink resistance and long service life. The first shunt pipe 604 and the first collecting pipe 605 are transversely arranged, and the first shunt pipe 604 and the first collecting pipe 605 are arranged on two sides of each discharge placement groove 41. During the use, detect the temperature in the coolant liquid storage tank 602 through temperature sensor 611, and will monitor temperature information transfer to control in the panel 8, control the panel 8 and can compare the temperature and the settlement temperature of coolant liquid automatically, and then control the work of cooling fin 612 or close, make the temperature of coolant liquid maintain the settlement scope all the time, then start water pump 603, water pump 603 passes through first corrugated hose 606 with the coolant liquid in the coolant liquid storage tank 602, first shunt pipe 604 and inlet tube 608 and enters into the reservoir 601, and then make reservoir 601 inflation, and closely wrap up injection bottle 10. Because the injection bottle 10 is usually a glass bottle, the strength of the injection bottle is weak, in order to prevent the liquid storage bag 601 from crushing the injection bottle 10, when the pressure in the liquid storage bag 601 reaches a certain gradient, the check valve 610 is pushed open, at the moment, the cooling liquid flows back to the cooling liquid storage tank 602 through the water outlet pipe 609, the first collecting pipe 605 and the second corrugated hose 607, a cooling liquid circulation loop is formed, the injection bottle 10 is cooled circularly, and the cooling effect is better.

Specifically, the lifting mechanism 7 further includes a control component 72, a second shunt pipe 73, an air inlet pipe 74, a blower 75 and a second compression spring 76, the buffer air bag 71 is fixedly connected with the bottom wall of the placing groove 41 through the control component 72, the second shunt pipe 73 is embedded below the placing groove 41, the second shunt pipe 73 is connected with the control component 72 through the air inlet pipe 74, the blower 75 is fixedly arranged at the bottom of the inner container 4, the blower 75 is connected with the second shunt pipe 73, and the second compression spring 76 is arranged in the buffer air bag 71. In this embodiment, the control assembly 72 is used to control the opening and closing of the intake pipe 74. The second shunt pipe 73 is arranged laterally, and the second shunt pipe 73 is located directly below the placement tank 41. When medical personnel need take out a certain injection bottle 10, control the work of the control assembly 72 that corresponds in the standing groove 41 through control panel 8 for intake pipe 74 and buffering gasbag 71 switch-on, air-blower 75 lets in the air to buffering gasbag 71 this moment, makes buffering gasbag 71 inflation and tensile second compression spring 76, and buffering gasbag 71 inflation can be ejecting out the standing groove 41 with the reservoir 601 in, and reservoir 601 top is opened and is leaked the injection bottle 10 this moment, makes things convenient for medical personnel to take. After the taking is finished, the control assembly 72 is closed, at this time, the buffer air bag 71 is pulled to contract under the elastic force of the second compression spring 76, and at this time, the buffer air bag 71 can pull the liquid storage bag 601 back into the placing groove 41 again. In addition, when the housing 1 is severely impacted, the buffer air bag 71 can also play a role in buffering the injection bottle 10 to prevent the injection bottle from being damaged.

Specifically, the control assembly 72 includes a control box 721, a sealing slider 722, a flow dividing plate 723, a control motor 724, a rotating gear 725 and an air outlet tube 728, a control chamber 726 is formed in the control box 721, the sealing slider 722 is slidably connected in the control chamber 726, the flow dividing plate 723 is fixedly arranged on the top of the sealing slider 722, a groove 727 is formed below the control chamber 726, the control motor 724 is embedded in the side wall of the groove 727, the rotating gear 725 is fixedly arranged at the power output end of the control motor 724, the rotating gear 725 is in gear engagement with the sealing slider 722, the cushion air bag 71 is fixedly arranged on the top of the control box 721, the cushion air bag 71 is communicated with the control chamber 726, the bottom of the control box 721 is connected with an air inlet tube 74 and an air outlet tube 728, and the air inlet tube 74 and the air outlet tube 728 are symmetrically arranged on two sides of the sealing slider 722. In this embodiment, the control motor 724 is electrically connected to the control panel 8. The width of the groove 727 is smaller than the length of the sealing slider 722, so that the sealing slider 722 can seal the groove 727 all the time during moving, and good air tightness of the control cavity 726 is ensured. The flow dividing plate 723 is vertically and fixedly arranged at the center of the top of the sealing slider 722, and the width of the flow dividing plate 723 is larger than the diameter of the air inlet of the buffer air bag 71. When the injection bottle 10 needs to be taken, the control panel 8 starts the control motor 724, the control motor 724 rotates forward to drive the rotating gear 725 to rotate, and further drives the sealing sliding block 722 to move leftward, so that the air inlet pipe 74 is communicated with the buffer air bag 71, the buffer air bag 71 expands, and the injection bottle 10 is ejected out of the placing groove 41; then the motor 724 is controlled to rotate reversely, so that the sealing sliding block 722 moves rightwards, the flow dividing plate 723 is further enabled to block an air inlet of the buffer air bag 71, the injection bottle 10 is enabled to keep a pushed-out state, and the motor 724 is controlled to be in a stop state; after the medical staff successfully takes the injection bottle 10, the control motor 724 is started to rotate reversely, so that the sealing sliding block 722 moves rightwards continuously, the buffering air bag 71 is communicated with the air outlet pipe 728, the buffering air bag 71 compresses and exhausts air from the air outlet pipe 728 under the action of the second compression spring 76, and the effect of controlling the lifting of the injection bottle 10 is achieved.

Specifically, the spherical rubber block 9 is fixedly arranged on the inner side of the cover plate 2, and the spherical rubber block 9 is matched with the placing groove 41 in an inserting manner. In this embodiment, can insert the standing groove 41 with spherical rubber block 9 after closing apron 2 in to seal standing groove 41, reduce cold volume and run off, spherical rubber block 9 can also play the cushioning effect when the inner bag 4 moves up simultaneously, and then reduces the vibration of inner bag 4.

Specifically, the heat-insulating layer 3 is made of rock wool material. The rock wool material has excellent heat preservation and heat insulation performance, can reduce the cold volume leakage in the containing cavity 11, is green and pollution-free, and meets the requirement of environmental protection.

While the invention has been described with reference to preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the invention. The present invention is not to be limited by the specific embodiments disclosed herein, and other embodiments that fall within the scope of the claims of the present application are intended to be within the scope of the present invention.

Claims

1. The utility model provides a salvia miltiorrhiza bunge injection constant temperature storage device which is characterized in that: comprises a shell (1), a cover plate (2), a heat-insulating layer (3), a liner (4), an oscillating mechanism (5), a cooling mechanism (6), a lifting mechanism (7) and a control panel (8), wherein the upper part of the shell (1) is rotatably connected with the cover plate (2), a containing cavity (11) is formed in the shell (1), the inner wall of the containing cavity (11) is fixedly provided with the heat-insulating layer (3), the liner (4) is slidably connected in the containing cavity (11), the liner (4) is connected with the bottom wall of the containing cavity (11) through the oscillating mechanism (5), more than two placing grooves (41) are uniformly formed in the liner (4), the lifting mechanism (7) comprises a buffer air bag (71), the buffer air bag (71) is fixedly arranged at the bottom of the placing grooves (41), the cooling mechanism (6) comprises a liquid storage bag (601), the liquid storage bag (601) is funnel-shaped, and the liquid storage bag (601) is fixedly connected with the buffer air bag (71), a fastening rubber ring (62) is fixedly arranged at the center of the liquid storage bag (601), and a control panel (8) is fixedly arranged on one side of the shell (1);

the cooling mechanism (6) further comprises a cooling liquid storage tank (602), a water pump (603), a first shunt pipe (604), a first collecting pipe (605), a first corrugated hose (606), a second corrugated hose (607), a water inlet pipe (608), a water outlet pipe (609), a one-way valve (610), a temperature sensor (611) and a cooling fin (612), a working chamber (12) is formed in one side of the accommodating chamber (11), the working chamber (12) is communicated with the accommodating chamber (11), the cooling liquid storage tank (602) is arranged in the working chamber (12), the water pump (603) is fixedly arranged on the cooling liquid storage tank (602), the first shunt pipe (604) and the first collecting pipe (605) are embedded in the top of the inner container (4), the first shunt pipe (604) and the first collecting pipe (605) are symmetrically arranged on two sides of the placing groove (41), the first shunt pipe (604) is connected with the water pump (603) through the first corrugated hose (606), the first collecting pipe (605) is connected with the cooling liquid storage tank (602) through a second corrugated hose (607), one end of the liquid storage bag (601) is connected with the first shunt pipe (604) through a water inlet pipe (608), the other end of the liquid storage bag (601) is connected with the first collecting pipe (605) through a water outlet pipe (609), a one-way valve (610) is fixedly arranged in the water outlet pipe (609), a temperature sensor (611) and a cooling fin (612) are further fixedly arranged in the cooling liquid storage tank (602), and the temperature sensor (611) and the cooling fin (612) are both electrically connected with the control panel (8).

2. The salvia miltiorrhiza injection constant-temperature storage device as claimed in claim 1, wherein: oscillating mechanism (5) include vibrating motor (51), three hornblocks (52), arc (53) and first compression spring (54), inner bag (4) bottom bilateral symmetry is provided with vibrating motor (51), and three hornblocks (52) set firmly in the power take off of vibrating motor (51), hold chamber (11) below and seted up spout (13), sliding connection has arc (53) in spout (13), and the both ends of arc (53) all are connected with spout (13) lateral wall through first compression spring (54), three hornblocks (52) and arc (53) butt.

3. The salvia miltiorrhiza injection constant-temperature storage device as claimed in claim 1, wherein: elevating system (7) still include control assembly (72), second shunt tubes (73), intake pipe (74), air-blower (75) and second compression spring (76), buffering gasbag (71) through control assembly (72) with standing groove (41) diapire fixed connection, standing groove (41) below has inlayed second shunt tubes (73), second shunt tubes (73) are connected with control assembly (72) through intake pipe (74), air-blower (75) set firmly in inner bag (4) bottom, and air-blower (75) are connected with second shunt tubes (73), are provided with second compression spring (76) in buffering gasbag (71).

4. The salvia miltiorrhiza injection constant-temperature storage device as claimed in claim 3, wherein: the control assembly (72) comprises a control box (721), a sealing sliding block (722), a flow distribution plate (723), a control motor (724), a rotating gear (725) and an air outlet pipe (728), a control cavity (726) is formed in the control box (721), the sealing sliding block (722) is connected in the control cavity (726) in a sliding mode, the flow distribution plate (723) is fixedly arranged at the top of the sealing sliding block (722), a groove (727) is formed below the control cavity (726), the control motor (724) is embedded in the side wall of the groove (727), the rotating gear (725) is fixedly arranged at the power output end of the control motor (724), the rotating gear (725) is meshed with the gear of the sealing sliding block (722), the buffer air bag (71) is fixedly arranged at the top of the control box (721), the buffer air bag (71) is communicated with the control cavity (726), the air inlet pipe (74) and the air outlet pipe (728) are connected to the bottom of the control box (721), the air inlet pipe (74) and the air outlet pipe (728) are symmetrically arranged at two sides of the sealing sliding block (722).

5. The salvia miltiorrhiza injection constant-temperature storage device as claimed in claim 1, wherein: spherical rubber blocks (9) are fixedly arranged on the inner side of the cover plate (2), and the spherical rubber blocks (9) are in plug-in fit with the placing grooves (41).

6. The salvia miltiorrhiza injection constant-temperature storage device as claimed in claim 1, wherein: the heat insulation layer (3) is made of rock wool material.