DE4017797A1 - LIQUID PUMP AND MEASURING DEVICE - Google Patents

Description

The invention relates to an intermittent device pumping or metering or dosing a liquid low to high viscosity, such as a liquid resin, the device via a supply line with a Storage container is connected. Such a container can be such that the liquid is exposed to a Vacuum is degassed in the container, and for support this type of degassing can work as a kind of agitator in the container. Further, when a liquid resin system contains a filler that is mostly abrasive, the agitator can do one more Function that can be seen in the fact that the filler in the Resin is kept in suspension. In addition, such Storage container warmed and using gas or air under pressure be set.

Such a system or such a system is shown in FIG. 3, in which the storage container 41 and the associated arrangement are connected to the metering-pump arrangement 47 . The Vorratsbehäl teranordnung 41 has a vacuum container 43 and a Rührflü gel 44 which moves in the liquid 42 . Furthermore, a vacuum pump 45 is connected to the container 43 and creates a vacuum therein.

The metering-pump arrangement 47 has a vertically arranged cylinder 48 . A vertically movable piston 49 is inserted into the upper end of the cylinder 48 and has a piston rod 50 which extends upwards therefrom, the piston rod 50 being connected to a drive device 51 for executing a reciprocating movement. A sealing part 52 is arranged between the upper end of the cylinder 48 and the piston rod 50 .

A shut-off valve 53 is installed in the lower part of the container 43 , the outlet opening of which is connected to the upper end of the cylinder 48 via an inclined connecting line 54 . Furthermore, a check valve 55 is provided, which enables light that the liquid 42 only flows out of the cylinder 48 in one direction.

When it is desired to meter the liquid 42 , the drive device 51 is actuated to reciprocate the piston 49 . When the piston 49 moves from the lowermost position to the uppermost position, as shown in solid lines, a negative pressure is generated in the lower area of the cylinder 48 . This negative pressure sucks the liquid 42 from the container 43 via the shut-off valve 53 and the line 54 into the lower region of the cylinder 48 . Therefore, when the piston 49 is moved to the lowest position again, as shown with broken lines, the liquid 42 , which is now in the area of the cylinder 48, is discharged via the check valve 45 . The discharge size can be varied by the relative movement of the piston 49 , as a result of which the liquid to be dispensed is metered or metered.

In the conventional design described above, a The device experiences the following difficulties on.

If liquids contain a solid filler, and particularly if they are of a high specific weight, the fillers tend to separate out and settle on the bottom region of the storage container 41 , which makes a partial or complete possible Shutting off the line 54 , the valve 53 , the Zumeßzy cylinder 48 and the check valve 55 is caused. This can obstruct the flow of liquid, and furthermore the filler content in the liquid can change, so that density changes from one sample to the next are obtained.

The invention aims to be a liquid pump and To provide metering device, in which the above mentioned difficulties are overcome.

The invention provides a vertically inclined pump or metering cylinder linder on, which seals tightly in the area of the bottom part NEN container is attached. The top end of the cylinder has open openings above the bottom of the container. The lower end of the metering cylinder has a check valve system, which only allows the liquid at the bottom of the Flows out of the cylinder. A piston is provided between one Position in and outside of the cylinder and above it Cylinder is vertically reciprocating. The Bewe The size of the piston in the cylinder can become a measurement or dosing different liquid volumes change. The piston drive rod is attached to the piston and this is with the help of a drive device outside of Container moved back and forth.

When the piston is moved to the top of the cylinder, the negative pressure generated in the cylinder causes the Liquid is sucked into the cylinder openings from the container becomes. When the plunger goes down and into the openings Cylinder is moved, the piston displaces the liquid, so that this over the lower end of the cylinder and over the One-way valve is issued. If so, this process again picks up runs, the fluid is intermittent in and issued over the cylinder.  

One or more wings rotate around the metering cylinder in the Bottom area of the container while maintaining a very small Distance between the wing and the container, but it it is still possible that the piston is partially from the cylinder can be deducted. The wing rotation is over a turn Drive device reached in on the outside of the container is correspondingly provided and which has a tubular Shaft connects to the wing. The tubular Shaft or hollow shaft surrounds the metering pump piston drive shaft. The reciprocating drive shaft and the itself rotating hollow shafts can be tightly sealed to prevent air, gas or vacuum between the container and in the environment on the outside of the container.

A main purpose of the invention is that the Fillers in a more uniform manner in a liquid are kept in suspension and that you fill a filler avoidation in the area of the lower part of the container, so that clogging the bottom area of the container and the metering cylinder and the one-way valve is prevented.

Furthermore, the invention aims at the pump and the pump drive arrange device inclined in a vertical position, whereby the piston rod shaft lies above the liquid level. Here there is sufficient space between the liquid surface and the seal in place, so that no contact between the liquid and the seal and between the on the Piston rod and the seal adhesive liquid is given. This can cause difficulties in connection with the Overcome wear and tear and leakage from a seal as this is not in contact with the liquid.

Further details, features and advantages of the invention emerge preferred from the following description Embodiments with reference to the accompanying drawings. In it show:  

Fig. 1 and 2, a preferred embodiment of the invention, wherein

Fig. 1 is a full side view with sectional view and

Fig. 2 is an enlarged sectional view of the embodiment of FIGS. 1 and

Fig. 3 is a full side view with a sectional view corresponding to FIG. 1 to illustrate a common embodiment.

In Figs. 1 and 2 is shown an apparatus, a filler-containing liquid is effected by means of heating, a stirring, degassing and metering. In the figures of the drawing, reference numeral 1 denotes the body of the device which has a container 2 made of sheet metal, which has a hopper 3 and a container cover plate 4 , which is intended to close the opening of the hopper.

A vertically arranged, tubular agitator shaft 6 , which passes through the cover plate 4 , is mounted in a bearing 7 and has a plurality of agitator blades 8 , which are fixedly attached to this. Above the cover plate 4 , an electric stirrer motor 9 is arranged, with which the stirrer shaft 6 is connected via a belt drive device 10 . Furthermore, a first seal 11 is arranged between the agitator shaft and the bearing 7 .

A liquid 12 is contained in the container 2 . This liquid 12 is a mass which comprises substances with different specific weights, such as a thermosetting liquid silicone resin, and a highly abrasive alumina filler with a resulting high viscosity.

When the electric motor 9 is turned on, the agitator blades rotate according to arrow A via the drive belt device 10 and the agitator shaft 6 . As a result, the liquid 12 is stirred and mixed.

Reference number 13 denotes a liquid supply line for supplying the liquid into the container 2 . A vacuum line and a shut-off valve 14 are connected to a vacuum pump 15 and the container 2 with the aim of degassing the liquid 12 . The outer surface 3 of the container 2 is covered with a heater 16 which heats the liquid 12 . By the reference numeral 17 a pressure gauge is denoted that detects a vacuum in the container. 2

The lower region of the container 2 is conical, a vertically arranged cylinder 18 being attached to the lower end of the container. The cylinder 18 has a cylinder body 19 , which is attached to the lower end of the container 2 , and a cylinder sleeve 20 , which is provided coaxially therewith and can be removed from the cylinder body 9 . A cover plate 21 , which prevents the cylinder liner 20 from slipping out of the cylinder body 9 , is detachably attached to the lower end of the cylinder body 19 by means of screws 22 . Thereof coaxially to the cylinder body 9 and in the extension of a body extension 23 is provided, while the upper end of the cylinder liner 20 prolongation having a cylinder socket 24 is provided coaxially to the cylinder liner 20th

The body extension 23 and the socket extension 24 are each arranged in such a way that the openings 25 are aligned with one another. The openings 25 are circular, and the base of the openings are flush with the inner surface of the base of the container 3 . The upper end of the cylinder liner 20 opens to the base of the container 3 through the openings 25 .

Furthermore, if the liquid 12 contains an abrasive filler, the cylinder liner 20 is made of an abrasion-resistant, ceramic material instead of steel or plastic as alternatives.

A piston 28 is inserted tightly closed and can also reciprocate in the vertical direction in the cylinder liner 20 and the cylinder liner extension 24 . This piston 28 is connected to a piston rod 33 , which runs coaxially with and within the agitator shaft 6 . The piston rod 33 is connected at the upper end to a drive device 29 for the reciprocating movement, which has an electric motor 80 and a speed reduction device 31 . Therefore, when the electric motor is turned on, the piston 28 is reciprocated in the vertical direction in the cylinder 20 and in the cylinder liner extension 24 via the piston rod 33 over an adjustable movement path and an adjustable speed.

A second seal 34 is arranged between the agitator shaft 6 and the piston rod 33 . The second sealing part 34 and the first sealing part 11 adjoin the cover plate 4 and serve to keep the container 2 airtight. The level of the liquid 12 in the container 2 is located just below the level of the sealing parts 11 and 34 and at a point where there is no liquid 12 which can adhere to the piston rod 33 so that it does not come into contact with the seals and 33 comes and can damage it when the piston rod 33 assumes its uppermost position.

A one-way valve 35 only allows the liquid 12 to flow downward and away from the cylinder liner 20 . In this case, the one-way valve can be a mechanical valve that is electrically controlled to open when the piston 28 moves down and to close when the piston 28 is moved up.

If it is desired to dispense the liquid 12 which has been stirred by means of the vanes 8 in the container 2 , the piston 28 is moved from its position A in the cylinder liner 20 to its uppermost position in the cylinder liner extension 24 , so that a negative pressure is built over the open openings 25 , which are now no longer blocked by the piston 28 . This vacuum causes the liquid 12 is sucked in through the openings 25 and into the cylinder liner 20 . When the piston is moved down and past the openings 25 into the cylinder liner 20 , the piston displaces the liquid 12 so that it exits through the cylinder liner 20 and through the one-way valve 35 . As the piston 28 continues to reciprocate, the cycle of dispensing and displacement is repeated.

In the aforementioned case, the cylinder 18 is attached to the base part of the container 2 , and the displacement of the filler portion itself takes place at this point and not later in a feed system in which sedimentation could occur due to the lack of a stirring movement.

Furthermore, since the cylinder liner 20 and the cylinder liner extension 24 have a common axis and the inner circumferential surfaces are aligned with one another, the movement of the piston takes place from the displacement bore to the refill bore. This design gives the following advantages.

When the piston is moved to the uppermost position 49 in the conventional design form according to FIG. 3, it exits from the upper end of the cylinder 48. If piston 49 is lowered down to enter cylinder 48 , any misalignment of piston rod 50 may result in damage or wear between piston 49 and cylinder 48 , or lumps and uneven concentrations of fillers at the cylinder's inlet 48 can also occur.

However, even if, in the preferred embodiment, piston 28 is in the uppermost position, it is still within cylinder liner extension 24 and misalignment with cylinder liner 20 cannot occur. Further, since the base of the openings 45 is flush with the base of the container 2 , all of the liquid can be effectively drained from the container 2 , or these openings 25 can be slightly above or partially below the bottom part of the container 2 .

In deviation from the piston rod seal 52 in Fig. 3, the piston rod seal 34 in Fig. 1 is not below or within half of the liquid rise height, so that it has more favorable working conditions with regard to the sealing behavior and the life of the seal. Any malfunction of this device will not allow air to be introduced into the liquid in the form of bubbles, possibly causing it to be pumped out within the liquid, as shown in Fig. 3, but rather will be in an area above the liquid level sucked off the container according to Fig. 1.

In Fig. 2, the piston 28 is raised past the openings 25 ben, the liquid 12 flows into the cylinder liner under its own weight regardless of any negative pressure, which is caused by a refilling action by the upward movement of the piston. Therefore, even if the liquid in the container 12 is degassed, the liquid 12 may in turn be introduced into the cylinder 28 .

Although the above explanations are based on the example shown, treatment of a liquid 12 in the container 2 does not necessarily have to be carried out by evacuating and degassing the liquid, in which case the first and second sealing parts 11 and 34 are then not provided need.

Claims (4)

1. Liquid pumping and metering device in a container ( 2 ), in which liquid ( 12 ) is received, marked by a vertically arranged cylinder ( 18 ) which is attached to the bottom part of the container ( 2 ) and to the bottom area of the Container ( 2 ), a one-way valve ( 35 ) attached to the base part of the cylinder ( 18 ) for dispensing the liquid from the cylinder ( 18 ) in one direction only, a piston ( 28 ) in the cylinder ( 18 ), which can move back and forth in the cylinder ( 18 ), and a piston rod ( 33 ) which connects the piston ( 28 ) with a Antriebseinrich device ( 29 ) which is provided above the upper container part ( 4 ). 2. Liquid pumping and metering device according to claim 1, characterized in that a sealing part ( 11 , 34 ) for sealing with respect to the pressure or vacuum in the container ( 2 ) is provided when the parts in the upper part ( 4 ) of the container ( 2nd ) take their position and surround the piston rod ( 33 ), and that the seals ( 11 , 34 ) above the liquid level in the container ( 2 ) at a distance between the respective surface of the liquid in the container ( 2 ) and the cover part ( 4th ) of the container are provided to prevent liquid adhering to the piston rod ( 33 ) from coming into contact with the sealing part ( 11 , 34 ). 3. Flüssigkeitspump- and metering device according to claim 1 or claim 2, characterized in that the piston cylinder liner (20) comprises a coaxial and extending in a line upper extension cylinder liner (24), said piston (28) in the upper extension of the cylinder liner (24 ) is retractable, and that the upper and lower cylinder liners ( 23 , 24 ) laterally opening openings ( 25 ) between them, which are rich with the Bodenbe of the container ( 2 ) in connection. 4. liquid pumping and metering device according to claim 3, characterized in that the base of the laterally opening openings ( 25 ) between the upper and lower sections ( 23 , 24 ) of the piston cylinder ( 18 ) in wesent union flush with the inner surface of the bottom region of the container ( 2 ) closes.