CN204092730U - A kind of full-automatic gravity vein transfusion monitor - Google Patents

Abstract

This utility model provides a kind of full-automatic gravity vein transfusion monitor 1, is made up of feature structure parts such as drawing lines carrier bar 2, monitor housing 3, synthesis central mounting hole 4, flow control module 5, synthesis carrier draw-in groove 6, operating console 7, synthesis operation bench draw-in groove 8, image modules 9; Can support the use with common disposable gravity intravenous transfusion device; Its integrated design is applicable to the applied environment of hospital; Its cutoff function, alarm function, image transmission function, the functions such as constant speed transfusion can meet the modernization demand of large data age venous transfusion management completely; It applies saving human resources that can be a large amount of, reduces the unnecessary work of medical personnel, reduces Hospital operation burden, improves nursing service quality, have huge economic benefit and social benefit.

Description

A kind of full-automatic gravity vein transfusion monitor

Technical field

This utility model provides a kind of full-automatic gravity vein transfusion monitor, is particularly a kind ofly applied to medical field, band own centre line road carrier bar, coordinates the defeated device of disposable gravity vein to use, has image collection transfer function, the full-automatic gravity vein transfusion monitor of one that its monitoring machine mechanical arm, flow control mechanical arm have automatic deploying and retracting function.

Background technology

Venous transfusion is the important medical treatment and nursing means of medical field disease therapy, be inpatient is even the requisite fluid infusion administrated method of non-inpatient; Venous transfusion occupies patient and entourage's a large amount of time, and also inevitably occupying a large amount of human resources, is also the main cause of hospital patient attending family, Gu work densely populated place; Advocating science and today of technology, venous transfusion progress can adopt electronic monitoring to replace manual observations completely, the quantity of minimizing In-patient entourage that like this can be a large amount of, also can reduce non-patient takies hospital's public resource simultaneously, reduce Hospital operation cost, alleviate medical worker's work burden, improve nursing service quality etc.; Its promotion and application will produce huge economic benefit and social benefit; In view of the foregoing, the follower in this field develops some venous transfusion electronic monitoring equipment, for replacing the manual observations of venous transfusion.Photosensitive method mainly used by these electronic equipments, gravimetric method, pressure application, dynamic method etc., be directly used in the control of venous transfusion, cut-off, alarm and remote information transmission, its objective is that not only can remove manpower nurse from observes, but also nursing staff can be allowed to obtain the transfusion condition of patient the very first time, accomplishes timely process; It is more thorough that these equipment are functionally considered, aspect of performance also reaches designing requirement substantially; From integrated application situation, these products also commercially do not obtain universal and are widely used, its reason is: 1, first these products only take into account monitoring function, does not consider the conservative management of equipment, is not organically combined with the environment of hospital by equipment; Just adopt the ways such as extension, card because custodial care facility is less, be suspended on drip stand, or be stuck on transfusion pole, be not easy to management like this, also easily lose, also add administrative burden; 2, secondly, monitor simplicity of design, outward appearance does not meet armarium style and corresponding standard-required, can not combine together, differ greatly with the requirement of modern medical service infrastructure device with existing medical treatment electronic equipment; Because the existence of demand, designer, to introduce to the market the soonest, to see for the purpose of benefit as early as possible, makes product lack Maturity; 3, monitoring method is numerous, because the demand of this respect just highlighted in recent years, so market there is multiple monitoring method and custodial care facility quickly, there is " blind area " in the choice in user, also do not know the monitor best performance selecting any method, any brand, welcome by patient, various monitor, also all not through the inspection in market, does not occur " famous brand " of trusting; 4, the glamour of monitor also does not fully play out, and inpatient and the medical personnel of the overwhelming majority also do not know there is such armarium, do not have the requirement of this respect, also not because monitor affects inpatient's quantity; Therefore, can drag in this expenditure hospital one day is one day, and as other armarium, time patient and medical personnel recognize its importance by the time, hospital will competitively equip; 5, its economic benefit brought hospital and social benefit also do not highlight, and based on monitor, the condition of armarium is also immature, and health care management layer does not also have corresponding management policy etc.Many reasons is also had all directly or indirectly to have influence on its promotion and application, as follower and the inventor of this respect, offer the best custodial care facility, meets the market demand widely, solving the thing that problem existing in this field is responsibility, is very necessary and right.

Summary of the invention

This utility model provides a kind of full-automatic gravity vein transfusion monitor, particularly a kind of be applied to medical field, band own centre line road carrier bar, coordinate the defeated device of disposable gravity vein to use, there is image collection transfer function, the full-automatic gravity vein transfusion monitor of one that its monitoring machine mechanical arm, flow control mechanical arm have automatic deploying and retracting function, in order to achieve the above object, technical scheme of the present invention is achieved in that described full-automatic gravity vein transfusion monitor 1, it is primarily of drawing lines carrier bar 2, monitor housing 3, synthesis center assembling pipe 4, flow control module 5, synthesis carrier draw-in groove 6, operating console 7, synthesis operation bench draw-in groove 8, image module 9, synthesis battery compartment 10, Synthetic motor carrying draw-in groove 11, synthesis center cable-through hole 12, operation controls keypad 13, operation controls button 14, signal receiving antenna 15, power-line plug hole 16, retracting motor nest 17, upper fastening cap 18, lower fastening cap 19, structural member such as backhaul limit switch 20 grade is formed, its structural relation is that drawing lines carrier bar 2 runs through to be assemblied in and assembles synthesis center that form, that be connected as a single entity with monitor housing 3 by monitor upper shell 21, monitor lower house 22 and assemble in pipe 4, it is assemblied on one section of drawing lines carrier bar in monitor housing 3 carrier bar wire hole 23, and carrier bar wire hole 23 is corresponding with the synthesis center cable-through hole 12 that synthesis center is assembled in pipe 4, medicinal liquid bottle hanger can be assemblied on the carrier bar upper end 24 of drawing lines carrier bar 2, carrier bar lower end 25 can be assemblied in the transfusion pole jack being positioned on sick bed, on drip stand or on transfusion chair etc., carrier bar between carrier bar wire hole 23 and carrier bar lower end 25 there is carrier bar entrance hole 26, the basic configuration of monitor upper shell 21, monitor lower house 22 is cylindrical, and its columniform side disc is excessively outwards the round platform of fan cambered surface, monitor upper shell 21, monitor lower house 22 assembling one is cylindrical in the middle of forming, and two ends is the symmetry synthesis monitor housing 3 of fan cambered surface truncated cone-shaped, upper casing center assembling pipe 27 and upper round platform table top 49, lower casing center assembles pipe 28 and lower round platform table top 50 and to be connected as a single entity respectively structure, upper and lower casing assembling one forms monitor housing 3 and assembles pipe 4 with synthesis center, the internal diameter of synthesis center assembling pipe 4 is greater than the external diameter of drawing lines carrier bar 2, the upper casing center assembling pipe 27 of monitor upper shell 21, is symmetrical in the lower casing center assembling pipe 28 of monitor lower house 22, the upper petal locking head 29 of the exterior pipe end of its housing, is symmetrical in the lower petal locking head 32 of the exterior pipe end of housing, upper petal locking head 29 silk 30 outer with the upper locking on the excessive pipe of monitor upper shell 21, is symmetrical in lower petal locking head 32 silk 33 outer with the lower locking on the excessive pipe of monitor lower house 22, be sleeved on the upper fastening cap 18 on petal locking head 29, be symmetrical in the lower fastening cap 19 be sleeved on lower petal locking head 32, upper fastening cap internal thread 31 is meshed with the outer silk 30 of upper locking, is symmetrical in lower fastening cap internal thread 34 and is meshed with the outer silk 33 of lower locking, monitor upper shell 21 side with draw-in groove 35 and monitor lower house 22 side on the housing of assembling cross section orthogonal with the housing lower bayonet slot 36 of assembling cross section orthogonal, form upper and lower through synthesis carrier draw-in groove 6 when upper and lower casing assembling one, synthesis draw-in groove cable-through hole 37, carrier upper left stopper slot 38-1, carrier lower-left stopper slot 38-2 is had in synthesis carrier draw-in groove 6, carrier upper right stopper slot 38-3, carrier bottom right stopper slot 38-4, the flow control module 5 be made up of module carrier 62, monitoring machine mechanical arm 63, flow control mechanical arm 64, drive motors 65 and uni-drive gear box 66 is assemblied in synthesis carrier draw-in groove 6, the side that monitor upper shell 21 is adjacent with draw-in groove 35 on housing has and manipulates draw-in groove 39 on table top, monitor lower house 22 side adjacent with housing lower bayonet slot 36 has and manipulates table top lower bayonet slot 40, and upper and lower casing assembling one forms synthesis operation bench draw-in groove 8, and operating console 7 assembles wherein, on the housing that described image module 9 is assemblied in flow control module 5 upper end in draw-in groove 35, the lower end of its image element loading plate 140 to be stuck on module carrier 62 and housing between draw-in groove 35, operation bench upper limit ring 42-1 is had inside upper shell above synthesis operation bench draw-in groove 8, inside lower house below synthesis operation bench draw-in groove 8, the case inside at operation bench lower limit ring 42-2 place, has speaker fitting recess 43, loudspeaker switch fitting recess 44, monitor housing 3 outer surface has the protruding platform 45 of speaker nest and loudspeaker switch notch 46, outstanding outlet 47 is had with in the housing outer surface of the opposite side of protruding platform 45 symmetry of speaker nest, on the lower side body face that monitor lower house 22 is corresponding with battery compartment, oriented lower convexity trade mark platform 48.

Described full-automatic gravity vein transfusion monitor 1, with on the housing of the adjacent side of draw-in groove 35 on housing in monitor upper shell 21, has draw-in groove 39 on operation bench; In monitor upper shell 21, there is upper battery compartment 51 side corresponding with draw-in groove on housing 35; On its housing, another sides adjacent of draw-in groove 35 to have inside retracting motor upper limit position groove 53 outside upper limit position groove 52 and retracting motor, and its hull outside has the protruding platform 54 of the upper shell motor corresponding with upper limit position groove inside retracting motor 53; On the housing of side adjacent with housing lower bayonet slot 36 in monitor lower house 22, there is manipulation table top lower bayonet slot 40; In monitor lower house 22, there is lower battery compartment 55 side corresponding with housing lower bayonet slot 36; Its another sides adjacent of housing lower bayonet slot 36 to have inside retracting motor lower limit groove 57 outside lower limit groove 56 and retracting motor, and its hull outside has the protruding platform 58 of the lower house motor corresponding with lower limit groove 57 outside retracting motor; In the monitor housing 3 that monitor upper shell 21 and monitor lower house 22 are formed, draw-in groove 35 on housing, corresponding with housing lower bayonet slot 36 form synthesize carrier draw-in groove 6; On manipulation table top, draw-in groove 39 forms with manipulation table top lower bayonet slot 40 corresponding matching and synthesizes operation bench draw-in groove 8; Upper battery compartment 51 and lower battery compartment 55, corresponding matching forms synthesis battery compartment 10; Lower limit groove 57 corresponding matching outside lower limit groove 56, retracting motor inside upper limit position groove 53 and retracting motor outside upper limit position groove 52, retracting motor inside retracting motor, forms to synthesize outside stopper slot 59, retracting motor inside retracting motor and synthesizes stopper slot 60; The protruding platform 54 of the upper shell motor in the outside of upper limit position groove 53 correspondence outside retracting motor, the protruding platform 58 of lower house motor in the outside corresponding with lower limit groove 57 outside retracting motor, corresponding matching forms the protruding platform 61 of synthesis retracting motor.

Described full-automatic gravity vein transfusion monitor 1, the module carrier 62 of its flow control module 5 is formed primarily of loading plate 68 on the right side of loading plate on the left of carrier 67, carrier and carrier disjunctor plate 76, uni-drive gear box 66, toothed wheel box cover plate 77; Its structure is that a longitudinal edge of loading plate 67 on the left of carrier is connected with a longitudinal edge of carrier connecting plate 76; On the right side of its carrier, a longitudinal edge of loading plate 68 and another longitudinal edge of carrier carrier connecting plate 67 connect and compose module carrier 62; On the left of its carrier, there is monitoring arm loading plate left side pivot holes 78 top of loading plate 67, there are flow control arm loading plate left side pivot holes 80 and left side drive motor axis hole 70 in below, and on the left of carrier, the outside of loading plate 67 has the spacing nest 80-1 of retracting motor and left side loading plate upper limit bar 67-1, left side loading plate lower limit bar 67-2 to coordinate with right side loading plate upper limit bar 68-1, the right side loading plate upper limit bar 68-2 of loading plate on the right side of carrier 68 respectively; The right side drive motors axis hole 71 that on the right side of its carrier, there is upper shaft hole 79 on the right side of monitoring arm loading plate the top of loading plate 68, there are lower shaft hole 81 and centre on the right side of flow control arm loading plate in below; On the right side of carrier, there is on the right side of uni-drive gear box 66 and carrier lower limit bar 80-5 on the right side of upper limit bar 80-4, carrier in the outside of loading plate 68; Carrier disjunctor plate 76 there is carrier cable-through hole 76-1; Drive motors 65 is assemblied in the spacing nest 17 of retracting motor on the left of carrier outside loading plate 67, its motor driving shaft 69 by the right side drive motors axis hole 71 on loading plate 68 on the right side of the left side drive motor axis hole 70 on loading plate on the left of carrier 67, carrier with the driven wheel 72 in uni-drive gear box 66, travelling gear 73, monitor arm transmitting gear 74, flow control arm transmitting gear 75 is communicated with, and forms driving relationship with monitoring machine mechanical arm 63, flow control mechanical arm 64; Toothed wheel box cover plate 77 can embed in the case lid installation opening 66-1 of uni-drive gear box 66, and the driving gearshaft 77-1 on it, monitoring arm reach 77-2, flow control arm reach 77-3 are matched with in driving cog wheel bore 73-1, monitoring arm gear hole 74-1, flow control arm gear hole 75-1 respectively; Right side loading plate upper limit bar 68-1 on the right side of carrier on loading plate 68, right side loading plate lower limit bar 68-2 coordinate with carrier upper right stopper slot 38-3, the carrier bottom right stopper slot 38-4 in synthesis carrier draw-in groove 6 through upper limit bar notch 77-4, the lower limit bar notch 77-5 on toothed wheel box cover plate 77.

Described full-automatic gravity vein transfusion monitor 1, the monitoring machine mechanical arm 63 of its flow control module 5, by monitoring arm carrier 82, monitoring element snap ring 83, on the left of monitoring element stopper slot 84, dropping funnel snap ring 85, metallic channel 86, metallic channel lid 87, monitoring arm rotation carrying axis hole 88, gear fixing hole 89, transmitting gear 73, transmitting gear axis hole 73-1, gear fixed leg 98, monitoring arm, on the right side of reach 91, monitoring arm, reach 92 is formed; The external end head of monitoring arm is monitoring element snap ring 83, the rotation carrying axis hole 88 of monitoring arm, turning gear wheel bore 90 by upper shaft hole 78 on the left of the monitoring arm loading plate on reach 92 on the right side of reach 91, monitoring arm on the left of monitoring arm and module carrier 62, monitor upper shaft hole 79 and module carrier 62 on the right side of arm loading plate and assembles integrally; The gear fixed leg 89 of transmitting gear 73 is assemblied in the gear fixing hole 89 of monitoring arm; Transmitting gear 73 and the gears meshing in uni-drive gear box 66; Monitoring element is assemblied in monitoring element stopper slot 84; Dropping funnel snap ring 85 is assemblied in monitoring element snap ring 83; Metallic channel lid 87 is assemblied in metallic channel 86.

Described full-automatic gravity vein transfusion monitor 1, the flow control mechanical arm 64 of its flow control module 5 is formed primarily of flow control motor 94, lead screw motor axle 95, flow control slip tongue block 96, synthesis flow control arm carrying housing 97, flow control arm transmitting gear 75, sliding door module 99, synthesis backhaul limit switch groove 100, synthesis pressure switch groove 101, synthesis sliding door drive post stopper slot 114-2, synthesis flow control arm carrying housing 97 has flow control mechanical arm upper shell 102, flow control mechanical arm lower house 103 upper and lower corresponding is assembled, there is draw-in groove 104 on tube for transfusion the external end head side of flow control mechanical arm upper shell 102, there is tube for transfusion lower bayonet slot 105 the external end head side of flow control mechanical arm lower house 103, and upper and lower casing assembling one forms synthesis flow control draw-in groove 106, fitting recess 107, flow control slip tongue block gliding groove 108, sliding door gliding groove 109, sliding door drive post gliding groove 109-1, spacing lower switch groove 110, limit switch post gliding groove 110-1, downforce switch groove 111 under flow control motor is had in flow control mechanical arm lower house 103, fitting recess 112, flow control slip tongue block upper hopper chute 113, sliding door upper hopper chute 114, sliding door drive post upper hopper chute 114-1, the spacing upper switch groove 115 of backhaul, limit switch post upper hopper chute 115-1, upward pressure switch groove 116 on symmetrical flow control motor is had in flow control mechanical arm upper shell 102, flow control mechanical arm upper shell 102 and flow control mechanical arm lower house 103 assembling one, form Synthetic motor fitting recess 117, synthesis flow control slip tongue block chute 118, synthesis sliding door chute 119, synthesis sliding door drive post stopper slot 114-2, synthesis backhaul limit switch groove 100, synthesis limit switch post sliding tray 115-2, synthesis pressure switch groove 121, flow control motor 94 is assemblied in Synthetic motor fitting recess 117, the lead screw motor axle 95 of flow control motor is assemblied in slip tongue block silk hole 124, flow control slip tongue block 96 is assemblied in synthesis flow control slip tongue block chute 118, sliding panel 122 on sliding door module 99 is assemblied in synthesis sliding door chute 119, sliding door drives limited post 96-1 to be assemblied in synthesis sliding door drive post stopper slot 114-2, backhaul limit switch 20 is assemblied in synthesis backhaul limit switch groove 100, backhaul limit switch post 96-2 is assemblied in synthesis limit switch post sliding tray 115-2 and sliding door drives in 99-1, pressure switch is assemblied in synthesis pressure switch groove 121, flow control gear assembling post 123 on flow control arm transmitting gear 75 is assemblied in the sprocket pilot hole 125 on synthesis flow control mechanical arm carrying housing 97, flow control arm transmitting gear 75 and the gears meshing in uni-drive gear box 66, on the left of flow control arm, folding and unfolding rotational axis hole 126 is corresponding with flow control arm loading plate left side pivot holes 80, on the left of flow control arm, folding and unfolding turning gear wheel bore 126 and the flow control arm loading plate right side pivot holes 81 on right side loading plate 68 are with corresponding, assemble one by reach on the right side of reach 128 on the left of flow control arm and flow control arm 129 and module carrier 62.

Described full-automatic gravity vein transfusion monitor 1, its operating console 7 has operation bench housing 130, and operation bench table top 131, table top liquid crystal display screen window 132, indicator lamp hole 133, operational and controlled key button hole 134, on and off switch mouth 135, USB port 136, operation bench housing upper limit platform 137, operation bench housing lower limit platform 138 are formed; The front of operation bench housing 130 is operation bench table top 131, and the middle top of table top panel is table top liquid crystal display screen window 132, the panel under liquid crystal display screen window has indicator lamp hole 133, operational and controlled key button hole 134; Operation bench left lateral sides there are on and off switch mouth 135, USB port 136; There are operation bench housing upper limit platform 137, operation bench housing lower limit platform 138 in the upper side of operation bench housing 130 and downside; Operation bench housing 130 is corresponding with synthesis table top draw-in groove assembles one, and in operation bench housing upper limit platform 137, operation bench housing lower limit platform 138 and monitor housing, in upper limit ring 39-1, monitor housing, lower limit ring 39-2 coordinates fixing.

Described full-automatic gravity vein transfusion monitor 1, its image module 9 is made up of image element loading plate 140, camera hole 141, light source hole 142, photographic hole 143; On the monitor housing that the upper end of image element loading plate 140 is assemblied in carrier upper end in draw-in groove, loading plate lower end to be stuck on carrier and monitor housing between draw-in groove; Camera hole 141 is corresponding with the dropping funnel in monitoring arm snap ring; Light source hole 142, photographic hole 143 are positioned at the both sides, below that camera hole 141 corresponds to dropping funnel, corresponding with the dropping funnel in monitoring snap ring.

Described full-automatic gravity vein transfusion monitor 1, on it, fastening cap 18 is by fastening cap internal thread 31, and fastening cap rounded nose 144, deflation annular mouth 145, outer ring surface tread plate 146 are formed; The outer silk 30 of upper locking that fastening cap internal thread 31 and center are assembled on pipe 4 engages; The fastening cap rounded nose 144 of upper fastening cap 18 is the spherical calotte with fastening cap equal diameters; Tightening annular mouth 145 is the cross section mouth being less than radius with the ballhead of fastening cap equal diameters; Fastening cap outer ring surface there is outer ring surface tread plate 146; Belonging to vein transfusion monitor 1, its lower fastening cap 19 is symmetry equivalent with upper fastening cap 18, is two identical parts.

Accompanying drawing explanation

Arm front view is received in the full-automatic gravity vein transfusion monitor assembling of Fig. 1

Arm front view is received in the full-automatic gravity vein transfusion monitor assembling of Fig. 2

The full-automatic gravity vein transfusion monitor of Fig. 3 receives arm front view

The full-automatic gravity vein transfusion monitor of Fig. 4 receives arm rearview

The full-automatic gravity vein transfusion monitor of Fig. 5 receives arm left view

The full-automatic gravity vein transfusion monitor of Fig. 6 receives arm right view

The full-automatic gravity vein transfusion monitor of Fig. 7 receives arm top view

View under Fig. 8 full-automatic gravity vein transfusion monitor receipts arm

Right front-upper three-dimensional view of Fig. 9 full-automatic gravity vein transfusion monitor

Left front-upper three-dimensional view of Figure 10 full-automatic gravity vein transfusion monitor

Figure 11 full-automatic gravity vein transfusion monitor exhibition arm front view

Figure 12 full-automatic gravity vein transfusion monitor exhibition arm rearview

Figure 13 full-automatic gravity vein transfusion monitor exhibition arm top view

View under Figure 14 full-automatic gravity vein transfusion monitor exhibition arm

Left front-upper three-dimensional view of Figure 15 full-automatic gravity vein transfusion monitor exhibition arm

Right front-upper three-dimensional view of Figure 16 full-automatic gravity vein transfusion monitor exhibition arm

Figure 17 monitor enclosure interior part confined state front view

Figure 18 monitor enclosure interior part confined state rearview

Figure 19 monitor housing front view

Figure 22 monitor housing left side view

Figure 21 monitor housing right side view

Left front-upper three-dimensional view of Figure 22 monitor housing

Figure 23 monitor housing X-Y shaft centre line cross section view

Figure 24 monitor housing A-A cross section view

Figure 25 monitor housing B-B cross section view

Figure 26 monitor upper shell front view

Left front-lower three-dimensional view of Figure 27 monitor upper shell

Right back-lower three-dimensional view of Figure 28 monitor upper shell

Figure 29 monitor lower house left side view

Figure 30 monitor lower house front-upper three-dimensional view

Left front-upper three-dimensional view of Figure 31 monitor lower house

The right front three-dimensional view of Figure 32 mechanical arm driving relationship

That Figure 33 monitors arm carrier is left front-upper three-dimensional view

Figure 34 monitors arm carrier right back-lower three-dimensional view

Figure 35 synthesizes flow control arm carrying housing front view

Figure 36 synthesizes flow control arm carrying housing X-Y shaft centre line cross section view

Figure 37 synthesizes flow control arm carrying housing A-A cross section view

Figure 38 synthesizes flow control arm carrying housing C-C cross section view

Figure 39 synthesizes flow control arm carrying housing D-D cross section view

Figure 40 flow control module assembly figure

Figure 41 flow control mechanical arm upper shell top view

View under Figure 42 flow control mechanical arm upper shell

Figure 43 flow control mechanical arm upper shell rearview

Right back-lower view of Figure 44 flow control mechanical arm upper shell

Figure 45 flow control mechanical arm lower house is left front-top view

Figure 46 flow control mechanical arm lower house is right front-top view

Figure 47 module carrier front view

Figure 48 module carrier rearview

Figure 49 module carrier left side view

Left front-upper three-dimensional view of Figure 50 module carrier

Left back-upper three-dimensional view of Figure 51 module carrier

Figure 52 uni-drive gear box

Right back-upper three-dimensional view of Figure 53 toothed wheel box cover plate

Left front-upper three-dimensional view of Figure 54 toothed wheel box cover plate

Figure 55 image module three-dimensional view

Figure 56 image module left side view

Figure 57 operation bench housing front view

The right front three-dimensional view of Figure 58 operation bench housing

Figure 59 dropping funnel snap ring three-dimensional view

Figure 60 metallic channel lid three-dimensional view

Figure 61 operates and controls keypad three-dimensional view

Figure 62 outlet

Figure 63 sliding panel three-dimensional view

Figure 64 flow control slip tongue block three-dimensional view

Figure 65 flow control slip tongue block right side view

Figure 66 monitors arm transmitting gear face of gear three-dimensional view

Figure 67 monitors arm transmitting gear fitting surface three-dimensional view

Figure 68 flow control arm transmitting gear face of gear three-dimensional view

Figure 69 flow control arm transmitting gear fitting surface three-dimensional view

Figure 70 backhaul limit switch three-dimensional view

1 full-automatic gravity vein transfusion monitor

2 drawing lines carrier bars

3 monitor housings

4 synthesis center assembling pipes

5 flow control modules

6 synthesis carrier draw-in grooves

7 operating consoles

8 synthesis operation bench draw-in grooves

9 image modules

10 synthesis battery compartments

11 Synthetic motor carrying draw-in grooves

12 synthesis center cable-through holes

13 operations control keypad

14 operations control button

15 signal receiving antennas

16 power-line plug holes

The spacing nest of 17 retracting motor

Fastening cap on 18

19 times fastening caps

20 backhaul limit switches

21 monitor upper shells

22 monitor lower houses

23 carrier bar wire holes

24 carrier bar upper ends

25 carrier bar lower ends

26 carrier bar entrance holes

27 upper casing center assembling pipes

28 lower casing center assembling pipes

Petal locking head on 29

Outer silk is locked on 30

Fastening cap internal thread on 31

32 times petal locking heads

33 times outer silks of locking

34 times fastening cap internal threads

Draw-in groove on 35 housings

36 housing lower bayonet slots

37 synthesis draw-in groove cable-through holes

38-1 carrier upper left stopper slot

38-2 carrier lower-left stopper slot

38-3 carrier upper right stopper slot

38-4 carrier bottom right stopper slot

Draw-in groove on 39 manipulation table tops

Upper limit ring in 39-1 monitor housing

Lower limit ring in 39-2 monitor housing

40 manipulation table top lower bayonet slots

42-1 operation bench upper limit ring

42-2 operation bench lower limit ring

43 speaker fitting recess

44 loudspeaker switch fitting recess

The protruding platform of 45 speaker nests

46 loudspeaker switch notches

47 outlets

48 trade mark platforms

Round platform table top on 49

50 times round platform table tops

Battery compartment on 51

Upper limit position groove inside 52 retracting motor

Upper limit position groove outside 53 retracting motor

The protruding platform of 54 upper shell motors

55 times battery compartments

Lower limit groove inside 56 retracting motor

Lower limit groove outside 57 retracting motor

The protruding platform of 58 lower house motors

Stopper slot is synthesized inside 59 retracting motor

Stopper slot is synthesized outside 60 retracting motor

The protruding platform of 61 synthesis retracting motor

62 module carriers

63 monitoring machine mechanical arm

64 flow control mechanical arms

65 drive motors

66 uni-drive gear boxes

66-1 case lid installation opening

Loading plate on the left of 67 carriers

Loading plate upper limit bar on the left of 67-1

Loading plate lower limit bar on the left of 67-2

Loading plate on the right side of 68 carriers

Loading plate upper limit bar on the right side of 68-1

Loading plate lower limit bar on the right side of 68-2

69 motor driving shafts

70 left side drive motor axis holes

71 right side drive motors axis holes

72 driven wheels

73 travelling gears

73--1 driving cog wheel bore

74 monitoring arm transmitting gears

74-1 monitors arm gear hole

75 flow control arm transmitting gears

75-1 flow control arm gear hole

76 carrier disjunctor plates

76-1 carrier cable-through hole

77 toothed wheel box cover plates

77-1 driving gearshaft

77-2 monitors arm reach

77-3 flow control arm reach

77-4 upper limit bar notch

77-5 lower limit bar notch

78 monitoring arm loading plate left side pivot holes

Upper shaft hole on the right side of 79 monitoring arm loading plates

80 flow control arm loading plate left side pivot holes

The spacing nest of 80-1 retracting motor

Upper limit bar on the left of 80-2 carrier

Lower limit bar on the left of 80-3 carrier

Upper limit bar on the right side of 80-4 carrier

Lower limit bar on the right side of 80-5 carrier

Lower shaft hole on the right side of 81 flow control arm loading plates

82 monitoring arm carriers

83 monitoring element cards

84 monitoring element position grooves

85 dropping funnel snap rings

86 metallic channels

87 metallic channel lids

88 monitoring arms rotate carrying axis hole

89 gear fixing holes

90 turning gear wheel bore

Reach on the left of 91 monitoring arms

Reach on the right side of 92 monitoring arms

94 flow control motors

95 lead screw motor axles

96 flow control slip tongue blocks

96-1 sliding door drives limited post

96-2 backhaul limit switch post

97 synthesis flow control arm carrying housings

98 gear fixed legs

99 sliding door modules

99-1 sliding door drives

100 synthesis backhaul limit switch grooves

101 synthesis pressure switch grooves

102 flow control mechanical arm upper shells

103 flow control mechanical arm lower houses

Draw-in groove on 104 tube for transfusions

105 tube for transfusion lower bayonet slots

106 synthesis flow control draw-in grooves

Fitting recess under 107 flow control motors

108 flow control slip tongue block gliding grooves

109 sliding door gliding grooves

109-1 sliding door drive post gliding groove

110 spacing lower switch grooves

110-1 limit switch post gliding groove

111 downforce switch grooves

Fitting recess on 112 flow control motors

113 flow control slip tongue block upper hopper chutes

114 sliding door upper hopper chutes

114-1 sliding door drive post upper hopper chute

114-2 synthesizes sliding door drive post stopper slot

The spacing upper switch groove of 115 backhaul

115-1 limit switch post upper hopper chute

115-2 synthesizes limit switch post sliding tray

116 upward pressure switch grooves

117 Synthetic motor fitting recess

118 synthesis flow control slip tongue block chutes

119 synthesis sliding door chutes

Rotational axis hole on the right side of 120 flow control arms

121 synthesis pressure switch grooves

122 sliding panels

123 flow control gear assembling posts

124 slip tongue block silk holes

125 sprocket pilot holes

Folding and unfolding rotational axis hole on the left of 126 flow control arms

Folding and unfolding rotational axis hole on the right side of 127 flow control arms

Reach on the left of 128 flow control arms

Reach on the right side of 129 flow control arms

130 operation bench housings

131 operation bench table tops

132 table top liquid crystal display screen windows

133 indicator lamp holes

134 operational and controlled key button holes

135 on and off switch mouths

136 USB port

137 operation bench housing upper limit platforms

138 operation bench housing lower limit platforms

139 on and off switch

140 image element loading plates

141 camera hole

142 light source holes

143 photographic holes

144 fastening cap rounded noses

145 tighten annular mouth

146 outer ring surface tread plates.

Beneficial effect

Full-automatic gravity vein monitor provided by the utility model, it is reasonable in design, and structure is simple, is convenient to manufacture; Volume is little, lightweight, and dependable performance is easy to use; Gravity balance, modern design, both artistic and practical; Its innovative product for manufacturing and designing because of the market demand, extensive market, rigid demand amount are large; Also can support the use with existing equipment interconnection in application, save large number quipments acquisition cost; The work that medical personnel are unnecessary in a large number can be reduced, improve nursing service quality, reduce a large amount of transfusion entourages, reduce Hospital operation cost; Reduce patient painful, improve hospital environment etc.; Its promotion and application have huge economic benefit and social benefit.

Detailed description of the invention

Full-automatic gravity vein transfusion monitor 1(is hereinafter referred to as monitor 1), it assembles the primary structure module compositions such as pipe 4, flow control module 5, operating console 7 by drawing lines carrier bar 2, monitor housing 3, synthesis center; Drawing lines carrier bar 2 is supporting body and the cable tubing of monitor, can assemble one with monitor housing 3, assembles pipe 4 and can be sleeved on drawing lines carrier bar 2, be fixed as one by upper and lower fastening cap with the synthesis center of monitor housing 3 one; The synthesis center cable-through hole 12 synthesized in assembly on center assembling pipe 4 is corresponding with the carrier bar wire hole 23 on drawing lines carrier bar, and data wire can directly be communicated with the power unit in monitor housing 3 with power line; Monitor housing 3 is the carrier of the original paper module such as carrier module, operating console 7, photographing module 9, synthesis battery compartment 10, electron plate; Drawing lines carrier bar 2 is made by metal material, its diameter is suitable with existing transfusion hack lever with length, there is the function of transfusion hack lever, transfusion pole can be replaced to use, its carrier bar lower end 25 can insert sick bed, and transfusion arm-chair, in the drip stand jack of the armarium such as stretcher, because wire is not drawn from the termination mouth of pipe, so the transposition of transfusion hack lever is unaffected; The medicinal liquid hanger bracket of common transfusion frame upper end can be assemblied on the carrier bar upper end 24 of drawing lines carrier bar 2, the carrier bar lower end 25 of drawing lines carrier bar 2 can also be assembled in the thicker carrier bar in common transfusion frame bottom, and hospital's existing equipment can make full use of.

Full-automatic gravity vein transfusion monitor 1, its structural design has taken into full account the environment for use of hospital, the design of its integration is convenient to management and, avoid infusion monitor because of small volume, to take out during use, the tedious work must regained after using, it also avoid because small volume is easily lost, and volume is excessive comparatively takies local more shortcoming.

Full-automatic gravity vein transfusion monitor 1, the circular design of placed in the middle and its housing of its drawing lines carrier bar 2, meet the structural principle of carrying balance and the aesthetic selection of visual angle balance, can not lose because of centre-of gravity shift stable, also can not affect attractive in appearance because of protrusion one side; The draw-in and draw-off function design of its flow control mechanical arm 64 and monitoring machine mechanical arm 63 is just in order to stable center of gravity, reduce volume, it is made to be unlikely to when not using, mechanical arm to a side convex hinder also affect attractive in appearance, what be also unlikely to manufacture takies very greatly place, waste material, inconvenience management, is also unlikely to because small volume has influence on function.

In use, because it is applicable to disposable gravity intravenous transfusion device, the market demand potential is huge, because its design does not affect disposable gravity intravenous transfusion device performance, and make use of its potential function and its distinctive structure, its function is obtained and further plays and utilize; Its advantage is mainly manifested in: 1, be first power advantage, vein monitor 1 utilize gravity infusion and non-powered transfusion, completely differently to infuse and pressure injection with power such as infusion pump, its safety is unquestionable, can not produce by force by the situation of air Injection human body, and gravity infusion meets energy-saving principle; 2, be secondly disposable gravity intravenous transfusion device because function singleness, because of the growing demand of patient can not be met, there is the possibility in the progressively ejection market of being eliminated; Current common disposable gravity intravenous transfusion device market use amount is huge, and domestic production ability is huge, once lose the market demand, its huge production capacity, equipment will be huge wastes, the selection that huge labour force troop is also faced with unemployment or reemploys; The use of vein transfusion monitor 1 is promoted, and the potential that common disposable gravity intravenous transfusion device is had and feature are obtained further exploitation, and its science is embodied further, and vitality strengthens further; 3, be again the demand of market to New function, the transfusion process of common disposable gravity intravenous transfusion device is that manpower takes care of the transfusion situation and transfusion process of observing patient for a long time always, because watching over the sick, transfusion occupies a large amount of human resources for a long time, applying of vein transfusion monitor 1 can replace a large amount of human resourcess, the labour force freed can create huge value, also can alleviate hospital's pressure, save operation cost.

In the use of monitor, the operation sequence of medical personnel's conveniently disposable gravity venous transfusion, by the Murphy tube of disposable intravenous infusion set entered under normal infusion state, the monitoring element snap ring 83 putting full-automatic gravity vein transfusion monitor 1 after opening into is interior with in synthesis flow control draw-in groove 106, monitor will moment infusion monitoring situation, and the situation of infusing in real time is sent on the monitor of nurse station, nursing staff just can accurately grasp transfusion situation in nurse station, time accurate assurance, situation processes in time, reduce work unnecessary in a large number, service more puts in place, take good care of more intimate.

Full-automatic gravity vein transfusion monitor, its drawing lines carrier bar 2 uses metal material to make, such as stainless steel tube, not only non-corrosive, and bearing capacity is strong, and existing transfusion hack lever mostly adopts this material; The functions of modules parts such as monitor housing 3, module carrier 62, radio and tape player mechanical arm housing, operating console 7, fastening cap can adopt injection moulding process to be processed into working of plastics respectively, are then assembled into assembly; Moulding manufacture of the present invention is simple, and nearly all moulding can adopt splits mould one-shot forming, and die manufacturing cost is low; Other matched metal part, electronic component etc. all adopt general part, ample supply and prompt delivery, and manufacturability is strong.

Claims (8)

1. a full-automatic gravity vein transfusion monitor (1), primarily of drawing lines carrier bar (2), monitor housing (3), synthesis center assembling pipe (4), flow control module (5), synthesis carrier draw-in groove (6), operating console (7), synthesis operation bench draw-in groove (8), image module (9), synthesis battery compartment (10), Synthetic motor carrying draw-in groove (11), synthesis center cable-through hole (12), speaker fitting recess (13), loudspeaker switch mouth (14), loudspeaker switch fitting recess (15), power-line plug hole (16), trademark platform (17), upper fastening cap (18), lower fastening cap (19), the structural members such as signal lamp (20) are formed, it is characterized by drawing lines carrier bar (2) run through be assemblied in by monitor upper shell (21), monitor lower house (22) assemble forms, and the synthesis center that is connected as a single entity of monitor housing (3) assemble and manage in (4), it is assemblied on one section of drawing lines carrier bar in monitor housing (3) carrier bar wire hole (23), and it is corresponding that synthesis center cable-through hole (12) of managing in (4) is assembled at carrier bar wire hole (23) and synthesis center, medicinal liquid bottle hanger can be assemblied on the carrier bar upper end (24) of drawing lines carrier bar (2), carrier bar lower end (25) can be assemblied in the transfusion pole jack being positioned on sick bed, on drip stand or on transfusion chair etc., carrier bar between carrier bar wire hole (23) and carrier bar lower end (25) there is carrier bar entrance hole (26), the basic configuration of monitor upper shell (21), monitor lower house (22) is cylindrical, and its columniform side disc is excessively outwards the round platform of fan cambered surface, monitor upper shell (21), monitor lower house (22) assembling one is cylindrical in the middle of forming, and two ends is symmetry synthesis monitor housing (3) of fan cambered surface truncated cone-shaped, upper casing center assembling pipe (27) and upper round platform table top (49), lower casing center assembles and are managed (28) and lower round platform table top (50) and to be connected as a single entity respectively structure, upper and lower casing assembling one formation monitor housing (3) assembles with synthesis center and manages (4), the internal diameter at synthesis center assembling pipe (4) is greater than the external diameter of drawing lines carrier bar (2), upper casing center assembling pipe (27) of monitor upper shell (21), is symmetrical in lower casing center assembling pipe (28) of monitor lower house (22), the upper petal locking head (29) of the exterior pipe end of its housing, is symmetrical in the lower petal locking head (32) of the exterior pipe end of housing, upper petal locking head (29) silk (30) outer with the upper locking on the excessive pipe of monitor upper shell (21), is symmetrical in lower petal locking head (32) silk (33) outer with the lower locking on the excessive pipe of monitor lower house (22), be sleeved on the upper fastening cap (18) on petal locking head (29), be symmetrical in the lower fastening cap (19) be sleeved on lower petal locking head (32), upper fastening cap internal thread (31) is meshed with the outer silk (30) of upper locking, is symmetrical in lower fastening cap internal thread (34) and is meshed with the outer silk (33) of lower locking, monitor upper shell (21) side with draw-in groove (35) and monitor lower house (22) side on the housing of assembling cross section orthogonal with the housing lower bayonet slot (36) of assembling cross section orthogonal, upper and lower casing assembling integrally time form upper and lower through synthesis carrier draw-in groove (6), synthesis draw-in groove cable-through hole (37), carrier upper left stopper slot (38-1), carrier lower-left stopper slot (38-2) is had in synthesis carrier draw-in groove (6), carrier upper right stopper slot (38-3), carrier bottom right stopper slot (38-4), the flow control module (5) be made up of module carrier (62), monitoring machine mechanical arm (63), flow control mechanical arm (64), drive motors (65) and uni-drive gear box (66) is assemblied in synthesis carrier draw-in groove (6), the side that on monitor upper shell (21) and housing, draw-in groove (35) is adjacent has and manipulates draw-in groove (39) on table top, monitor lower house (22) and housing lower bayonet slot (36) adjacent side have and manipulates table top lower bayonet slot (40), and upper and lower casing assembling one forms synthesis operation bench draw-in groove (8), and operating console (7) assembles wherein, described image module (9) is assemblied in flow control module, and (on the housing of 5 upper ends in draw-in groove (35), the lower end of its loading plate (9-1) to be stuck on module carrier (62) and housing between draw-in groove (35), operation bench upper limit ring (42-1) is had inside the upper shell of synthesis operation bench draw-in groove (8) top, inside the lower house of synthesis operation bench draw-in groove (8) below, the case inside at operation bench lower limit ring (42-2) place, has speaker to assemble nest (43), loudspeaker switch fitting recess (44), monitor housing (3) outer surface has the protruding platform (45) of speaker nest and loudspeaker switch notch (46), the housing outer surface of the opposite side symmetrical with the protruding platform (45) of speaker nest there is outstanding outlet (47), on the lower side body face that monitor lower house (22) is corresponding with battery compartment, oriented lower convexity trade mark platform (48).

2. full-automatic gravity vein transfusion monitor (1) according to claim 1, is characterized by monitor upper shell (21) interior with on the housing of draw-in groove (35) adjacent side on housing, has draw-in groove on operation bench (39); In monitor upper shell (21), there is upper battery compartment (51) side corresponding with draw-in groove on housing (35); On its housing, another sides adjacent of draw-in groove (35) has upper limit position groove (53) outside upper limit position groove inside retracting motor (52) and retracting motor, and its hull outside has the protruding platform (54) of the upper shell motor corresponding with upper limit position groove inside retracting motor (53); On the housing of side adjacent with housing lower bayonet slot (36) in monitor lower house (22), there is manipulation table top lower bayonet slot (40); In monitor lower house (22), there is lower battery compartment (55) side corresponding with housing lower bayonet slot (36); Its housing lower bayonet slot (36) another sides adjacent to have inside retracting motor lower limit groove (57) outside lower limit groove (56) and retracting motor, and its hull outside has lower house motor projection platform (58) corresponding with lower limit groove (57) outside retracting motor; In the monitor housing (3) that monitor upper shell (21) and monitor lower house (22) are formed, draw-in groove (35) on housing, corresponding with housing lower bayonet slot (36) form synthesize carrier draw-in groove (6); On manipulation table top, draw-in groove (39) forms with manipulation table top lower bayonet slot (40) corresponding matching and synthesizes operation bench draw-in groove (8); Upper battery compartment (51) and lower battery compartment (55), corresponding matching forms synthesis battery compartment (10); Lower limit groove (57) corresponding matching outside lower limit groove (56), retracting motor inside upper limit position groove (53) and retracting motor outside upper limit position groove (52), retracting motor inside retracting motor, forms to synthesize outside stopper slot (59), retracting motor inside retracting motor and synthesizes stopper slot (60); The protruding platform (54) of the upper shell motor in the outside that upper limit position groove (53) is corresponding outside retracting motor, the protruding platform (58) of lower house motor in the outside corresponding with lower limit groove (57) outside retracting motor, corresponding matching forms the protruding platform (61) of synthesis retracting motor.

3. full-automatic gravity vein transfusion monitor (1) according to claim 1, the module carrier (62) that it is characterized by flow control module (5) is formed primarily of loading plate (68) on the right side of loading plate on the left of carrier (67), carrier and carrier disjunctor plate (76), uni-drive gear box (66), toothed wheel box cover plate (77), its structure is that a longitudinal edge of loading plate (67) on the left of carrier is connected with a longitudinal edge of carrier connecting plate (76), on the right side of its carrier, a longitudinal edge of loading plate (68) and another longitudinal edge of carrier carrier connecting plate (67) connect and compose module carrier (62), on the left of its carrier, there is monitoring arm loading plate left side pivot holes (78) top of loading plate (67), there are flow control arm loading plate left side pivot holes (80) and left side drive motor axis hole (70) in below, and on the left of carrier, there is on the left of the spacing nest of retracting motor (80-1) and carrier lower limit bar (80-3) on the left of upper limit bar (80-2), carrier in the outside of loading plate (67), on the left of carrier on the left of upper limit bar (80-2), carrier lower limit bar (80-3 coordinates with carrier upper left stopper slot (38-1) in carrier draw-in groove, carrier lower-left stopper slot (38-2) in carrier draw-in groove, the right side drive motors axis hole (71) that on the right side of its carrier, there is upper shaft hole (79) on the right side of monitoring arm loading plate the top of loading plate (68), there are lower shaft hole (81) and centre on the right side of flow control arm loading plate in below, on the right side of carrier, there is on the right side of uni-drive gear box (66) and carrier lower limit bar (80-5) on the right side of upper limit bar (80-4), carrier in the outside of loading plate (68), carrier disjunctor plate (76) there is carrier cable-through hole (76-1), drive motors (65) is assemblied in the spacing nest of retracting motor (67-1) in loading plate on the left of carrier (67) outside, its motor driving shaft (69) is by the left side drive motor axis hole (70) on loading plate on the left of carrier (67), right side drive motors axis hole (71) on the right side of carrier on loading plate (68) and the driven wheel (72) in uni-drive gear box (66), travelling gear (73), monitoring arm transmitting gear (74), flow control arm transmitting gear (75) is communicated with, with monitoring machine mechanical arm (63), flow control mechanical arm (64) forms driving relationship, toothed wheel box cover plate (77) can embed in the case lid installation opening (66-1) of uni-drive gear box (66), and the driving gearshaft (77-1) on it, monitoring arm reach (77-2), flow control arm reach (77-3) are matched with in driving cog wheel bore (73-1), monitoring arm gear hole (74-1), flow control arm gear hole (75-1) respectively, right side loading plate upper limit bar (68-1) on the right side of carrier on loading plate (68), right side loading plate lower limit bar (68-2) coordinate with the carrier upper right stopper slot (38-3) in synthesis carrier draw-in groove (6), carrier bottom right stopper slot (38-4) through the upper limit bar notch (77-4) on toothed wheel box cover plate (77), lower limit bar notch (77-5).

4. full-automatic gravity vein transfusion monitor (1) according to claim 1, it is characterized by the monitoring machine mechanical arm (63) of flow control module (5), by monitoring arm carrier (82), monitoring element snap ring (83), monitoring element stopper slot (84), dropping funnel snap ring (85), metallic channel (86), metallic channel lid (87), monitoring arm rotate carrying axis hole (88), gear fixing hole (89), transmitting gear (73), transmitting gear axis hole (73-1), gear fixed leg (90-2), left side reach (91), right side reach (92) formation; The external end head of monitoring arm is monitoring element snap ring (83), rotation carrying axis hole (88) of monitoring arm, turning gear wheel bore (90) by left side reach (91), right side reach (92 with module carrier (62) on monitoring arm loading plate on the left of upper shaft hole (78), monitor upper shaft hole (79) and module carrier (62) on the right side of arm loading plate and assembles integrally; (89 are assemblied in the gear fixing hole (89) of monitoring arm the gear fixed leg of transmitting gear (73); Transmitting gear (73) and the gears meshing in uni-drive gear box (66); Monitoring element is assemblied in monitoring element stopper slot (84); Dropping funnel snap ring (85) is assemblied in monitoring element snap ring (83); Metallic channel lid (87) is assemblied in metallic channel (86).

5. full-automatic gravity vein transfusion monitor (1) according to claim 1, the flow control mechanical arm (64) that it is characterized by flow control module (5) is formed primarily of flow control motor (94), lead screw motor axle (95), flow control slip tongue block (96), synthesis flow control arm carrying housing (97), flow control arm transmitting gear (98), sliding door module (99), synthesis backhaul limit switch groove (100), synthesis pressure switch groove (101), synthesis slide drive post chute (100-1), synthesis limit switch post chute (100-2), synthesis flow control arm carrying housing (97) has flow control mechanical arm upper shell (102), flow control mechanical arm lower house (103) upper and lower corresponding is assembled, there is draw-in groove on tube for transfusion (104) the external end head side of flow control mechanical arm upper shell (102), there is tube for transfusion lower bayonet slot (105) the external end head side of flow control mechanical arm lower house (103), and its assembling one of upper and lower casing forms synthesis flow control draw-in groove (106), flow control motor lower limit groove (107), flow control slip tongue block gliding groove (108), sliding door gliding groove (109), sliding door drive post gliding groove (109-1), spacing lower switch groove (110), limit switch post gliding groove (110-1), backhaul downforce switch groove (111) is had in flow control mechanical arm lower house (103), symmetrical flow control motor upper limit position groove (112), flow control sliding shoe upper hopper chute (113), sliding door upper hopper chute (114), sliding door drive post upper hopper chute (114-1), the spacing upper switch groove (115) of backhaul, limit switch post upper hopper chute (115-1), upward pressure switch groove (116) is had in flow control mechanical arm upper shell (102), flow control mechanical arm upper shell (102) and flow control mechanical arm lower house (103) assembling one, form Synthetic motor stopper slot (117), synthesis flow control slip tongue block chute (118), synthesis sliding door chute (119), synthesis slip door pillar stopper slot (114-2), synthesis backhaul limit switch groove (120), synthesis limit switch post sliding tray (115-2), synthesis pressure switch groove (121), flow control motor (94) is assemblied in Synthetic motor stopper slot (117), the lead screw motor axle (95) of flow control motor is assemblied in slip tongue block silk hole (124), flow control slip tongue block (96) is assemblied in synthesis flow control slip tongue block chute (118), (sliding panel (122) on 99 is assemblied in synthesis sliding door chute (119) sliding door module, sliding door drives limited post (96-1) to be assemblied in synthesis slip door pillar stopper slot (114-2), backhaul limit switch (120) is assemblied in synthesis backhaul limit switch groove (100), backhaul limit switch post (96-2) is assemblied in synthesis limit switch post sliding tray (115-2) and sliding door drives in (99-1), pressure switch is assemblied in synthesis pressure switch groove (121), gear assembling post (123) on flow control arm transmitting gear (75) is assemblied in the sprocket pilot hole (125) on synthesis flow control mechanical arm carrying housing (97), flow control arm transmitting gear (75) and the gears meshing in uni-drive gear box (66), flow control arm left pivot movement axis hole (126) is corresponding with flow control arm loading plate left side pivot holes (80), on the right side of flow control arm, turning gear wheel bore (126) and flow control arm loading plate right side pivot holes (81) on right side loading plate (68) are with corresponding, assemble one by reach (129) on the right side of reach (128) on the left of flow control arm and flow control arm and module carrier (62).

6. full-automatic gravity vein transfusion monitor (1) according to claim 1, it is characterized by operating console (7) and have operation bench housing (130), operation bench table top (131), table top liquid crystal display screen window (132), indicator lamp hole (133), operational and controlled key button hole (134), on and off switch mouth (135), USB port (136), operation bench housing upper limit platform (137), operation bench housing lower limit platform (138) are formed; The front of operation bench housing (130) is operation bench table top (131), and the middle top of table top panel is table top liquid crystal display screen window (132), the panel under liquid crystal display screen window has indicator lamp hole (133), operational and controlled key button hole (134); Operation bench left lateral sides there are on and off switch mouth (135), USB port (136); There are operation bench housing upper limit platform (137), operation bench housing lower limit platform (138) in the upper side of operation bench housing (130) and downside; Operation bench housing (130) is corresponding with synthesis table top draw-in groove assembles one, and in operation bench housing upper limit platform (137), operation bench housing lower limit platform (138) and monitor housing, in upper limit ring (39-1), monitor housing, lower limit ring (39-2) coordinates fixing.

7. full-automatic gravity vein transfusion monitor (1) according to claim 1, is characterized by image module (9) and is made up of image element loading plate (140), camera hole (141), light source hole (142), photographic hole (143); On the monitor housing that the upper end of image element loading plate (140) is assemblied in carrier upper end in draw-in groove, loading plate lower end to be stuck on carrier and monitor housing between draw-in groove; Camera hole (141) is corresponding with the dropping funnel in monitoring arm snap ring; Light source hole (142), photographic hole (143) are positioned at the below both sides of camera hole (141) corresponding to dropping funnel, corresponding with the dropping funnel in monitoring snap ring.

8. full-automatic gravity vein transfusion monitor (1) according to claim 1, upper fastening cap (18) is by fastening cap internal thread (31), and fastening cap rounded nose (144), deflation annular mouth (145), outer ring surface tread plate (146) are formed; Fastening cap internal thread (31) and center are assembled the outer silk (30) of upper locking of managing on (4) and are engaged; The fastening cap rounded nose (144) that it is characterized by fastening cap (18) is the spherical calotte with fastening cap equal diameters; Tightening annular mouth (145) is the cross section mouth being less than radius with the ballhead of fastening cap equal diameters; Fastening cap outer ring surface there is outer ring surface tread plate (146); Belonging to vein transfusion monitor (1), its lower fastening cap (19) is symmetry equivalent with upper fastening cap (18), is two identical parts.