CN204234703U - vacuum quantitative tank - Google Patents

Abstract

The utility model discloses a kind of vacuum quantitative tank, comprise the cylinder, bearing block and the tank body that seal serial connection successively, the cavity of described bearing block and tank body is connected formation vacuum cavity; Described bearing block is provided with vacuum port joint, to control the vacuum of vacuum cavity; Described tank base is provided with tank mouth, is provided with the spool for sealing described tank mouth in the cavity of described tank body; The piston rod of described cylinder interior is connected with spool, and described piston rod band movable valve plug moves back and forth the opening and closing controlling tank mouth up and down.Adopting the utility model, by controlling vacuum cavity vacuum and gas cylinder working condition in vacuum quantitative tank, realizing Automatic Extraction and the Automatic-dumping of stoste, stoste sealing transmission, cleannes are high, also can effectively prevent stoste to be oxidized.

Description

Vacuum quantitative tank

Technical field

The utility model relates to a kind of device of Automatic Extraction material, particularly relates to a kind of vacuum quantitative tank.

Background technology

At present, the feed gearbox hand of die casting machine is all use soup ladle to scoop material from the top liquid level of holding furnace, and scoop in die casting machine by raw material by holding furnace, this just inevitably produces defect, dregs floating on first liquid level, and it two is slurry oxidations by air.The product produced so just inevitably has oxidation and slag inclusion to exist, and affects the quality of foundry goods.

Utility model content

Technical problem to be solved in the utility model is, provide a kind of structure simple vacuum quantitative tank, can realize Automatic Extraction and the Automatic-dumping of stoste, sealing is high, effectively ensures the cleannes of stoste.

Technical problem to be solved in the utility model is also, provides a kind of vacuum quantitative tank, by regulating the opening and closing speed of toppling over speed and tank mouth of relevant throttle valve control stoste, effectively avoids stoste to splash, and reduces spool to the impact of tank mouth.

In order to solve the problems of the technologies described above, the utility model provides a kind of vacuum quantitative tank, comprises the cylinder, bearing block and the tank body that seal serial connection successively, and the cavity of described bearing block and tank body is connected formation vacuum cavity; Described bearing block is provided with vacuum port joint, to control the vacuum of vacuum cavity; Described tank base is provided with tank mouth, is provided with the spool for sealing described tank mouth in the cavity of described tank body; The piston rod of described cylinder interior is connected with spool, and described piston rod band movable valve plug moves back and forth the opening and closing controlling tank mouth up and down.

As the improvement of such scheme, the piston rod of described cylinder interior is connected with connecting rod by shaft coupling, and described connecting rod is connected with spool, and described piston rod is moved back and forth up and down by shaft coupling and connecting rod band movable valve plug.

As the improvement of such scheme, bottom described bearing block inwall, bearing is installed; Be provided with sliding tray and air channel in described bearing, described sliding tray is located at the axle center place of described bearing; Described connecting rod is embedded in described sliding tray, slidably reciprocates along described sliding tray inwall.

As the improvement of such scheme, the inwall of described sliding tray is cylindrical, and described air channel equidistant arrangement forms endless loop, and described endless loop is coaxial with sliding tray, and described sliding tray is communicated with air channel.

As the improvement of such scheme, be fixed by upper flange between described cylinder and bearing block, sealed by sealing gasket between described upper flange and cylinder, bearing block; Be fixed by lower flange between described bearing block and tank body, sealed by sealing gasket between described lower flange and bearing block, tank body.

As the improvement of such scheme, described vacuum quantitative tank also comprises the laser range finder of the spacing for measuring holding furnace liquid level and measurement point.

As the improvement of such scheme, described vacuum quantitative tank also comprises the connecting plate for being fixed on by described vacuum quantitative tank on Handling device, and described connecting plate is located on described bearing block.

As the improvement of such scheme, described vacuum quantitative tank also comprises the air control unit for controlling described vacuum cavity vacuum and gas cylinder working condition; Described air control unit comprises the first magnetic valve, vacuum generator, the second magnetic valve, B/P EGR Back Pressure Transducer EGR, the 3rd magnetic valve, the 4th magnetic valve, first throttle valve, second throttle and the 3rd choke valve; The vacuum port joint of described vacuum quantitative tank, the first magnetic valve, vacuum generator, the second magnetic valve connect successively; Described B/P EGR Back Pressure Transducer EGR is connected with vacuum port joint and with the first magnetic valve; Described 3rd magnetic valve is connected with vacuum port joint and with the first magnetic valve by the 3rd choke valve; One end of described 4th magnetic valve is connected with cylinder respectively by first throttle valve and second throttle, and the other end of described 4th magnetic valve is connected with vacuum generator and the second magnetic valve.

As the improvement of such scheme, described 4th magnetic valve is 3 position-5 way magnetic valve; Described first magnetic valve, the second magnetic valve, the 3rd magnetic valve are two-position two-way solenoid valve; Described first throttle valve, second throttle and the 3rd choke valve are one-way throttle valve.

As the improvement of such scheme, described tank body lower part conically.

Implement the utility model, there is following beneficial effect:

Vacuum quantitative tank is moved up and down by air cylinder driven spool, realize the opening and closing of tank mouth, by the air in vacuum port joint extracting vacuum cavity or pass into air in vacuum cavity, realize the Automatic Extraction of stoste and topple over, the extraction process of stoste is made to complete disengaging manual operation, save a large amount of labours, security is high.

Particularly, by the flexible connection of piston rod, shaft coupling, connecting rod, spool, make the driving between cylinder and spool more stable; Meanwhile, by the unique design of bearing, make the movement locus of air in vacuum cavity more regular, gas flowing steadily, ensure the extraction of stoste in vacuum quantitative tank, topple over more smooth.

Make stoste in extraction process by laser range finder, tank mouth immerses in the stoste of holding furnace all the time, sealing transmission, and cleannes are high, also can anti-oxidation effectively.

Vacuum cavity vacuum and gas cylinder working condition is accurately controlled by air control unit, ensure the precise quantitative of stoste, also by regulating the opening and closing speed of toppling over speed and tank mouth of relevant throttle valve control stoste, effectively avoiding stoste to splash, reducing spool to the impact of tank mouth.

Accompanying drawing explanation

Fig. 1 is the first example structure schematic diagram of the utility model vacuum quantitative tank;

Fig. 2 is the sectional view at A-A place in Fig. 1;

Fig. 3 is the second example structure schematic diagram of the utility model vacuum quantitative tank;

Fig. 4 is the 3rd example structure schematic diagram of the utility model vacuum quantitative tank;

Fig. 5 is the partial enlarged drawing at M place in Fig. 4;

Fig. 6 is the structural representation of the utility model vacuum quantitative tank middle (center) bearing;

Fig. 7 is the sectional view at B-B place in Fig. 6;

Fig. 8 is the 4th example structure schematic diagram of the utility model vacuum quantitative tank;

Fig. 9 is the 5th example structure schematic diagram of the utility model vacuum quantitative tank.

Detailed description of the invention

For making the purpose of this utility model, technical scheme and advantage clearly, below in conjunction with accompanying drawing, the utility model is described in further detail.

Show the first embodiment of the utility model vacuum quantitative tank see Fig. 1 and Fig. 2, Fig. 1 and Fig. 2, described vacuum quantitative tank comprises the cylinder 1, bearing block 2 and the tank body 3 that seal serial connection successively, and the cavity of described bearing block 2 and tank body 3 is connected formation vacuum cavity.Described bearing block 2 is provided with vacuum port joint 4, to control the vacuum of vacuum cavity.Being provided with tank mouth 5 bottom described tank body 3, in the cavity of described tank body 3, being provided with the spool 6 for sealing described tank mouth 5.The piston rod 7 of described cylinder 1 inside is connected with spool 6, and described piston rod 7 moves back and forth with movable valve plug about 6 opening and closing controlling tank mouth 5.

It should be noted that, described cylinder 1 inside is provided with piston rod 7, and cylinder 1 piston rod 7 in the vertical direction is formed and moves back and forth up and down, and meanwhile, piston rod 7 is connected with spool 6, makes spool 6 under the drive of piston rod 7, together moves with piston rod 7.When cylinder 1 piston rod 7 moves to minimum point, spool 6 is also in lowest point, and now spool 6 blocks tank mouth; When cylinder 1 piston rod 7 moves upward, spool 6 also moves upward, and opens tank mouth.

During work, sink in the stoste of holding furnace by below vacuum quantitative tank; Cylinder 1 successively piston rod 7 and spool 6 moves upward, and spool 6 opens tank mouth 5; By the air in vacuum port joint 4 extracting vacuum cavity, make vacuum cavity form vacuum state, stoste is inhaled in vacuum cavity under vacuum; After completing the extraction of stoste, stop the air in extracting vacuum cavity; Cylinder 1 successively piston rod 7 and spool 6 moves downward, and spool 6 blocks tank mouth 5, prevents stoste from flowing out; Mobile vacuum quantitative pot, aims at the material receiving port of die casting machine by the tank mouth 5 of vacuum quantitative tank; Cylinder 1 successively piston rod 7 and spool 6 moves upward, and spool 6 opens tank mouth, and vacuum port joint 4 is communicated with air, and destroy the vacuum in vacuum cavity, stoste flows out to material receiving port smoothly, completes stoste by holding furnace to the transmission of die casting machine.

It should be noted that, in stoste extraction process, tank mouth 5 immerses in the stoste of holding furnace all the time, prevents air from being immersed in vacuum cavity by tank mouth 5.

Further, described tank body 3 bottom conically, effectively can guide the stoste in tank body 3 to converge to tank mouth 5 along conical structure, be easier to stoste and flow out smoothly along tank mouth 5.

Show the second embodiment of the utility model vacuum quantitative tank see Fig. 3, Fig. 3, with the first embodiment of the tank of vacuum quantitative shown in Fig. 1 and Fig. 2 unlike, also comprise shaft coupling 8 and connecting rod 9 in the vacuum quantitative tank shown in Fig. 3.

The piston rod 7 of described cylinder 1 inside is connected with connecting rod 9 by shaft coupling 8, and described connecting rod 9 is connected with spool 6, and described piston rod 7 is with movable valve plug about 6 to move back and forth by shaft coupling 8 and connecting rod 9.

It should be noted that, piston rod 7 is fixed with the length of spool 6, therefore, by plugging into of connecting rod 9, realize the connection of piston rod 7 and spool 6, during use, the connecting rod 9 of different length can be selected according to the actual height of tank body 3, to meet when cylinder 1 piston rod 7 moves to minimum point, spool 6 is also in lowest point, blocks tank mouth 5 by spool 6.

Correspondingly, piston rod 7 is connected with connecting rod 9 by shaft coupling 8, effectively can play the effect of buffering, vibration damping to connecting rod 9 and spool 6, and ensure relative displacement not to occur between piston rod 7 and connecting rod 9, improves the dynamic property of spool 6.

Particularly, piston rod 7, shaft coupling 8, connecting rod 9 and spool 6 connect successively.When cylinder 1 piston rod 7 moves to minimum point, spool 6 is also in lowest point under the drive of connecting rod 9, and now spool 6 blocks tank mouth 5; When cylinder 1 piston rod 7 moves upward, spool 6 also moves upward under the drive of connecting rod 9, opens tank mouth 5.

During work, sink in the stoste of holding furnace by below vacuum quantitative tank; Cylinder 1 piston rod 7, piston rod 7 is moved upward by shaft coupling 8 traction bars 9 and spool 6, and spool 6 opens tank mouth 5; By the air in vacuum port joint 4 extracting vacuum cavity, make vacuum cavity form vacuum state, stoste is inhaled in vacuum cavity under vacuum; After completing the extraction of stoste, stop the air in extracting vacuum cavity; Cylinder 1 piston rod 7, piston rod 7 drives connecting rod 9 and spool 6 to move downward by shaft coupling 8, and spool 6 blocks tank mouth 5, prevents stoste from flowing out; Mobile vacuum quantitative pot, aims at the material receiving port of die casting machine by the tank mouth 5 of vacuum quantitative tank; Cylinder 1 again draws spool 6 by piston rod 7 and moves upward, and spool 6 opens tank mouth 5, and vacuum port joint 4 is communicated with air, and destroy the vacuum in vacuum cavity, stoste flows out to material receiving port smoothly, completes stoste by holding furnace to the transmission of die casting machine.

Show the 3rd embodiment of the utility model vacuum quantitative tank see Fig. 4, Fig. 4, with the second embodiment of the vacuum quantitative tank shown in Fig. 3 unlike, bottom bearing block 2 inwall described in the vacuum quantitative tank shown in Fig. 4, bearing 10 is installed.

Particularly, be provided with sliding tray and air channel in described bearing 10, described sliding tray is located at the axle center place of described bearing 10; Described connecting rod 7 is embedded in described sliding tray, slidably reciprocates along described sliding tray inwall.

It should be noted that, the length being connected the haulage gear formed by piston rod 7, shaft coupling 8, connecting rod 9 and spool 6 is successively longer, connecting rod 9 can be effectively guided to slidably reciprocate along described sliding tray inwall in the vertical direction by bearing 10, the movement locus of haulage gear is effectively guided, fixing of retainer shaft center, and reduce the coefficient of friction in power transmission process.

Meanwhile, air channel can make the cavity of bearing block 2 be connected with the cavity of tank body 3 effectively, forms vacuum cavity.

As Fig. 6 and Fig. 7, the inwall of described sliding tray 11 is cylindrical, and described air channel 12 equidistant arrangement forms endless loop, and described endless loop is coaxial with sliding tray 11, and described sliding tray 11 is communicated with air channel 12, forms cavity.

It should be noted that, connecting rod 9 is cylinder, and the columniform inwall of sliding tray 11 can make connecting rod 9 more tight with the laminating of sliding tray 11, and more effectively retainer shaft center is fixing.

Meanwhile, the air channel 12 of equidistant arrangement is connected with sliding tray 11, and the gas in vacuum cavity can be made to transmit equably between bearing block 2 cavity and tank body 3 cavity, makes the stressed more average of bearing 10 surrounding.

Particularly, when passing through the air in vacuum port joint 4 extracting vacuum cavity, the air in vacuum cavity moves to bearing block 2 cavity along the air channel 12 of equidistant arrangement from tank body 3 cavity, makes vacuum cavity form vacuum state; When vacuum port joint 4 is communicated with air, when spool 6 opens tank mouth 5, stoste pouring vessel mouth 5, air moves to tank body 3 cavity along the air channel 12 of equidistant arrangement from bearing block 2 cavity, destroys the vacuum in vacuum cavity.Therefore, in above-mentioned motion process, air evenly, reposefully moves under the guiding of air channel 12, can make the stressed more average of bearing 10 surrounding, effectively ensure the stability of vacuum cavity, and the speed of the extraction of control stoste, outflow is steady better.

During work, sink in the stoste of holding furnace by below vacuum quantitative tank; Cylinder 1 piston rod 7, piston rod 7 is moved upward by shaft coupling 8 traction bars 9 and spool 6, and spool 6 opens tank mouth 5; By the air in vacuum port joint 4 extracting vacuum cavity, the air in vacuum cavity is moved to bearing block 2 cavity from tank body 3 cavity along the air channel 12 of equidistant arrangement, vacuum cavity forms vacuum state, and stoste is inhaled in vacuum cavity under vacuum; After completing the extraction of stoste, stop the air in extracting vacuum cavity; Cylinder 1 piston rod 7, piston rod 7 drives connecting rod 9 and spool 6 to move downward by shaft coupling 8, and spool 6 blocks tank mouth 5, prevents stoste from flowing out; Mobile vacuum quantitative pot, aims at the material receiving port of die casting machine by the tank mouth 5 of vacuum quantitative tank; Cylinder 1 again draws spool 6 by piston rod 7 and moves upward, spool 6 opens tank mouth 5, vacuum port joint 4 is communicated with air, air moves to tank body 3 cavity along the air channel 12 of equidistant arrangement from bearing block 2 cavity, destroy the vacuum in vacuum cavity, stoste flows out to material receiving port smoothly, completes stoste by holding furnace to the transmission of die casting machine.

As described in Fig. 4 and Fig. 5, be fixed by upper flange 13 between described cylinder 1 and bearing block 2, sealed by sealing gasket between described upper flange 13 and cylinder 1, bearing block 2; Be fixed by lower flange 14 between described bearing block 2 and tank body 3, sealed by sealing gasket between described lower flange 14 and bearing block 2, tank body 3.

Particularly, cylinder 1 is arranged on the top of bearing block 2 with bolt by upper flange 13, and tank body 3 and bearing block 2 pass through, together with lower flange 14 bolted, to ensure the Stability Analysis of Structures between cylinder 1, bearing block 2, tank body 3.

Preferably, described sealing gasket comprises: be located at upper flange 13 and the cylinder packing 15 on the horizontal contact face of cylinder 1, be located at upper flange 13 and the side O sealing ring 16 on the vertical contact surface of cylinder 1, be located at upper flange 13 with the lower O RunddichtringO 17(on bearing block 2 contact surface see Fig. 5), be located at lower flange 14 and the upper sealing gasket 18 on bearing block 2 contact surface, be located at lower seal pad 19(on lower flange and tank body contact surface see Fig. 4), by described cylinder packing 15, side O sealing ring 16, lower O RunddichtringO 17, upper sealing gasket 18 and lower seal pad 19, can effectively ensure cylinder 1, bearing block 2, air-tightness between tank body 3, make the vacuum that vacuum cavity keeps good under vacuum conditions, prevent stoste from overflowing.

See Fig. 8, Fig. 8 shows the 4th embodiment of the utility model vacuum quantitative tank, with the 3rd embodiment of the vacuum quantitative tank shown in Fig. 4 unlike, the vacuum quantitative tank shown in Fig. 8 also comprises the laser range finder 20 of the spacing for measuring holding furnace liquid level and measurement point.

It should be noted that, in stoste extraction process, tank mouth 5 need immerse in the stoste of holding furnace all the time, prevents air from being immersed in vacuum cavity by tank mouth 5.Correspondingly, the sinkage of tank mouth 5, can get as required liquid measure number, holding furnace sectional area calculate and determine, to guarantee that vacuum quantitative tank is drawn in stoste process, after liquid level declines, tank mouth 5 immerses in the stoste of holding furnace all the time, prevents tank mouth 5 from leaking gas.

Particularly, the sinkage needed for tank mouth 5 can be precalculated, and corresponding predeterminable range value is set; Then, detect the real-time distance S between holding furnace liquid level a and test point b by laser range finder 20, when distance S reaches predeterminable range value in real time, then represent that the submergence depth of now tank mouth meets and extract requirement.

Further, described vacuum quantitative tank also comprises the connecting plate 21 for being fixed on by described vacuum quantitative tank on Handling device, and described connecting plate 21 is located on described bearing block 2.

It should be noted that, can vacuum quantitative tank will be fastened on Handling device by connecting plate 21, vacuum quantitative tank can be realized at holding furnace and to the flexible movement between die casting machine by Handling device.

See Fig. 9, Fig. 9 shows the 5th embodiment of the utility model vacuum quantitative tank, with the 4th embodiment of the vacuum quantitative tank shown in Fig. 8 unlike, the vacuum quantitative tank shown in Fig. 9 also comprises the air control unit for controlling described vacuum cavity vacuum and cylinder 1 duty.

Described air control unit comprises the first magnetic valve 22, vacuum generator 23, second magnetic valve 24, B/P EGR Back Pressure Transducer EGR 25, the 3rd magnetic valve 26, the 4th magnetic valve 27, first throttle valve 28, second throttle 29 and the 3rd choke valve 30.

Particularly: vacuum port joint 4, first magnetic valve 22, vacuum generator 23, second magnetic valve 24 of described vacuum quantitative tank connect successively; Described B/P EGR Back Pressure Transducer EGR 25 is connected with vacuum port joint 4 and with the first magnetic valve 22; Described 3rd magnetic valve 26 is connected with vacuum port joint 4 and with the first magnetic valve 22 by the 3rd choke valve 30; One end of described 4th magnetic valve 27 is connected with cylinder 1 respectively by first throttle valve 28 and second throttle 29, and the other end of described 4th magnetic valve 27 is connected with vacuum generator 23 and the second magnetic valve 24.

Before work, get as required liquid measure number, holding furnace sectional area calculate and determine the sinkage of tank mouth 5, and predeterminable range value is set; During work, vacuum quantitative tank bottom is sunk in the stoste of holding furnace by Handling device, laser range finder 20 detects the real-time distance S between holding furnace liquid level and test point in real time, and when distance S reaches predeterminable range value in real time, Handling device controls vacuum quantitative tank transfixion; Second magnetic valve 24 obtains electric, and the 4th magnetic valve 27 lower electromagnet obtains electric, and cylinder 1 successively piston rod 7, shaft coupling 8, connecting rod 9 and spool 6 moves upward, and spool 6 rises, and opens tank mouth 5; Meanwhile, the first magnetic valve 22 obtains electric, and vacuum generator 23 starts the air in extracting vacuum cavity by vacuum port joint 4, and make vacuum cavity form vacuum state, stoste is inhaled in vacuum cavity along tank mouth 5 under the effect of vacuum; When the vacuum in vacuum cavity reaches setting value, B/P EGR Back Pressure Transducer EGR 25 sends signal, controls the first magnetic valve 22 dead electricity, and vacuum generator 23 stops vacuumizing, time delay 2s; Now, on the 4th magnetic valve 27, electromagnet obtains electric, and cylinder 1 successively piston rod 7, shaft coupling 8, connecting rod 9 and spool 6 moves downward, and spool 6 closes tank mouth 5, prevents stoste from flowing out, and completes the extraction of stoste; Handling device Mobile vacuum quantitative pot, aims at the material receiving port of die casting machine by the tank mouth 5 of vacuum quantitative tank; 4th magnetic valve 27 lower electromagnet obtains electric, and cylinder 1 drives spool 6 to rise again, opens tank mouth 5; 3rd magnetic valve 26 electric, vacuum port joint 4 is communicated with air, destroys the vacuum in vacuum cavity, makes stoste flow out to material receiving port smoothly along tank mouth 5, completes stoste by holding furnace to the transmission of die casting machine; Finally, vacuum quantitative tank is moved to holding furnace place by Handling device again, prepares the work of next working cycles.

It should be noted that, by regulating the aperture size of the 3rd choke valve 30, the speed that air enters vacuum cavity can be controlled, thus control the speed of stoste pouring vessel mouth 5, avoid stoste to splash; Meanwhile, by regulating the aperture size of first throttle valve 28 and second throttle 29, the opening and closing speed of spool 6 can be driven by control cylinder 1, reducing the impact of spool 6 pairs of tank mouths 5.

Further, described 4th magnetic valve 27 is 3 position-5 way magnetic valve, by control upper electromagnet and lower electromagnet in 3 position-5 way magnetic valve /power failure state, the duty of control cylinder 1, thus control spool 6 opens or closes tank mouth 5.Described first magnetic valve 22, second magnetic valve 24, the 3rd magnetic valve 26 are two-position two-way solenoid valve, during energising, and valve open; During power-off, valve closing.Described first throttle valve 28, second throttle 29 and the 3rd choke valve 30 are one-way throttle valve, realize one-way throttle.

As from the foregoing, the extraction process of stoste can be made to depart from manual operation by vacuum quantitative tank, save a large amount of labours, security is high.Meanwhile, in stoste extraction process, by laser range finder 20, tank mouth 5 is immersed in the stoste of holding furnace all the time, can not extract dregs floating on liquid level, stoste sealing transmission, cleannes are high, also can anti-oxidation effectively.In addition, effectively control vacuum cavity vacuum and cylinder 1 duty by air control unit, realize Automatic Extraction and the Automatic-dumping of stoste, ensure the precise quantitative of stoste.Correspondingly, also by regulating the opening and closing speed of toppling over speed and tank mouth 5 of relevant throttle valve control stoste, effectively avoiding stoste to splash, reducing the impact of spool 6 pairs of tank mouths 5.

The above is preferred embodiment of the present utility model; it should be pointed out that for those skilled in the art, under the prerequisite not departing from the utility model principle; can also make some improvements and modifications, these improvements and modifications are also considered as protection domain of the present utility model.

Claims (10)

1. a vacuum quantitative tank, is characterized in that, described vacuum quantitative tank comprises the cylinder, bearing block and the tank body that seal serial connection successively, and the cavity of described bearing block and tank body is connected formation vacuum cavity;

Described bearing block is provided with vacuum port joint, to control the vacuum of vacuum cavity;

Described tank base is provided with tank mouth, is provided with the spool for sealing described tank mouth in the cavity of described tank body;

The piston rod of described cylinder interior is connected with spool, and described piston rod band movable valve plug moves back and forth the opening and closing controlling tank mouth up and down.

2. vacuum quantitative tank as claimed in claim 1, it is characterized in that, the piston rod of described cylinder interior is connected with connecting rod by shaft coupling, and described connecting rod is connected with spool, and described piston rod is moved back and forth up and down by shaft coupling and connecting rod band movable valve plug.

3. vacuum quantitative tank as claimed in claim 2, is characterized in that, be provided with bearing bottom described bearing block inwall;

Be provided with sliding tray and air channel in described bearing, described sliding tray is located at the axle center place of described bearing;

Described connecting rod is embedded in described sliding tray, slidably reciprocates along described sliding tray inwall.

4. vacuum quantitative tank as claimed in claim 3, it is characterized in that, the inwall of described sliding tray is cylindrical, and described air channel equidistant arrangement forms endless loop, and described endless loop is coaxial with sliding tray, and described sliding tray is communicated with air channel.

5. vacuum quantitative tank as claimed in claim 1, be is characterized in that, be fixed between described cylinder and bearing block by upper flange, is sealed between described upper flange and cylinder, bearing block by sealing gasket;

Be fixed by lower flange between described bearing block and tank body, sealed by sealing gasket between described lower flange and bearing block, tank body.

6. vacuum quantitative tank as claimed in claim 1, is characterized in that, also comprising the laser range finder of the spacing for measuring holding furnace liquid level and measurement point.

7. vacuum quantitative tank as claimed in claim 1, it is characterized in that, also comprise the connecting plate for being fixed on by described vacuum quantitative tank on Handling device, described connecting plate is located on described bearing block.

8. vacuum quantitative tank as claimed in claim 1, is characterized in that, also comprising the air control unit for controlling described vacuum cavity vacuum and gas cylinder working condition;

Described air control unit comprises the first magnetic valve, vacuum generator, the second magnetic valve, B/P EGR Back Pressure Transducer EGR, the 3rd magnetic valve, the 4th magnetic valve, first throttle valve, second throttle and the 3rd choke valve;

The vacuum port joint of described vacuum quantitative tank, the first magnetic valve, vacuum generator, the second magnetic valve connect successively;

Described B/P EGR Back Pressure Transducer EGR is connected with vacuum port joint and with the first magnetic valve;

Described 3rd magnetic valve is connected with vacuum port joint and with the first magnetic valve by the 3rd choke valve;

One end of described 4th magnetic valve is connected with cylinder respectively by first throttle valve and second throttle, and the other end of described 4th magnetic valve is connected with vacuum generator and the second magnetic valve.

9. vacuum quantitative tank as claimed in claim 8, is characterized in that,

Described 4th magnetic valve is 3 position-5 way magnetic valve;

Described first magnetic valve, the second magnetic valve, the 3rd magnetic valve are two-position two-way solenoid valve;

Described first throttle valve, second throttle and the 3rd choke valve are one-way throttle valve.

10. the vacuum quantitative tank as described in any one of claim 1 ~ 9, is characterized in that, described tank body lower part conically.