DE202016007222U1 - Air compressor with a pressure vessel - Google Patents

Abstract

Air compressor with a pressure vessel (3) with a device for dewatering condensate, a drainage (7) on the underside (6) of the pressure vessel (3) and a drainage opening (7) downstream condensate drain valve (10; 15; 18) characterized in that a compressed air line (9) with an end-side condensate drain valve (10; 15; 18) is connected to the drainage opening (7) of the compressed air tank (3), with a length of the compressed air line such that the condensate drain valve (10; 15; 18) is positionable at a suitable accessible location, spaced from the bottom (6) of the pressure vessel (3).

Description

The invention relates to an air compressor with a pressure vessel according to the preamble of claim 1.

Air compressors are known in a variety of different embodiments for different applications. Among other things, entrained and / or transportable air compressors, for example for construction site applications, are known, for example for the operation of percussion hammers or paint sprayers, etc. Also, stationary, for example, built in workshops or elsewhere or built-in, air compressors are well known. These air compressors regularly have an electric motor or driven by an internal combustion engine compressor unit, which is conveyed in a downstream pressure vessel compressed air and removed from there via a compressed air line for the different applications. Regularly the compressor unit is controlled in operation with a pressure sensor so that it is turned on at a minimum pressure in the pressure vessel and turned off at a maximum pressure, so that in the pressure vessel constantly compressed air is available with sufficient pressure.

During operation of such an air compressor condensed water drops due to the humidity of the intake air in the pressure vessel, which accumulates in the lower region of the pressure vessel.

If too much condensation has accumulated in the pressure vessel, a mist of water is formed in the extracted working air. As a result, connected compressed air tools and possibly the work result are adversely affected, so that unacceptable water droplets form during painting, for example. In addition, the condensation in the pressure vessel and connected metal lines leads to rust formation and in extreme cases to rust through.

Therefore, on most pressure vessels of compressors, there is a drain valve on the bottom of the pressure vessel for dewatering condensate. The drain valves are usually designed as drainage screws and difficult to handle and uncomfortable on the underside of the pressure vessel at a small distance to the ground. Such drainage screws also usually have small openings that can clog quickly in a dewatering process. If these are then completely unscrewed, there is no controlled dewatering process, but the condensate splashes uncontrollably with high pressure on the ground. In addition, compressors are often located in extra rooms and therefore difficult to access.

Because of the usually poor accessibility and arduous handling of drainage valves or drainage screws dewatering is often not sufficiently performed, so that therefore often occur the problems described above.

Although per se known water separators on the compressor reduce the formation of condensation, but bring no fundamental solution to the problem, since still regularly the condensate must be drained. In addition, in the market automatic drainage device usually offered in conjunction with electric solenoid valves, which, however, are also often arranged largely inaccessible to the underside of a pressure vessel and are also complicated and expensive.

The object of the invention is therefore to propose a simpler, most favorable solution for the drainage of a pressure vessel of an air compressor.

This object is achieved in a particularly simple and inexpensive embodiment in that a compressed air line is connected to an end-side condensate drain valve to the drainage opening of the compressed air tank, wherein the length of the pressure line is dimensioned so that the condensate drain valve at a suitable accessible location, spaced from the bottom of the pressure vessel is positionable. The condensate drain valve can be designed here simply as manually operable one-way valve, in particular as a ball valve.

During operation of the compressor, the built-up pressure in the pressure vessel acts on the condensate, which is blown out when the condensate drain valve is opened via the compressed air line during a dewatering process. If only compressed air exits the condensate drain valve, this is closed again and the drainage process is completed. The condensate drain valve can be arranged with a relatively long compressed air line and far away from a compressor, so that a drainage can also be performed, for example, in other rooms away from the site of a compressor. For example, in a portable air compressor, the drain valve may be attached to an easily accessible compressor body away from the bottom of the pressure vessel.

Immediately at the drainage opening of the pressure vessel may be arranged in addition, as before still a container valve as manually operable one-way valve, in particular a ball valve, which can remain open in the rule. In particular, starting from there, a Retrofitting done by connecting a compressed air line according to the invention with an end-side condensate drain valve.

In an advantageous development, the condensate drain valve may be preceded by a preferably cylindrical, vertically standing condensate collecting vessel, on the one hand at the top the compressed air line is connected and on the other hand, the condensate drain valve is arranged below. It is also expedient to arrange a condensate separator in an upper region of the condensate collecting vessel in the condensate collecting vessel. As soon as the air compressor is switched on, the condensate is forced into the collecting vessel via the compressed air line with the pressure build-up in the pressure vessel. During operation, when the detected minimum pressure of the compressor is switched on again by means of the pressure sensor, condensate is also pressed as water mist in the condensate collection vessel, which catches in the condensate trap and drips down there. At a pressure drop from the maximum pressure reached (for example, 10 bar) to the minimum pressure (for example, 8 bar) then condensate-free air is pushed back into the pressure vessel, so that there is virtually no condensate or at least very little condensate. The draining of the condensate from the condensate collecting vessel can also be carried out by hand by means of the condensate drain valve, with the condensate drain valve can be designed as a ball valve for easy handling.

Furthermore, two embodiments are proposed, in which the dewatering process can take place automatically and automatically:
In a first automated embodiment, the condensate collecting vessel has a float valve as condensate drain valve, with a condensate discharge opening with sealing ring as valve seat and an associated, above the sealing ring in the condensate collecting vessel recorded float as a movable valve body, preferably as a float ball is trained. When the condensate level in the condensate collecting vessel rises, the float, in particular a float ball, is lifted so that the condensate discharge opening is released and condensate can flow off. This is in any case possible if the air compressor is switched off and no pressure is built up in the pressure vessel. With suitable dimensioning, if appropriate, the buoyancy of the float at a higher condensate level may be greater than the pressure built up in the pressure vessel and thus in the condensate collecting vessel, so that an automatic automatic dehydration can take place. Again, if necessary, in addition to the float valve a hand-operated shut-off valve, in particular a ball valve be arranged downstream.

In a further embodiment for automatic dewatering, the condensate collecting vessel connected downstream, preferably connected to this condensate drain valve, a switchable valve, preferably a switchable solenoid valve may be. This can be controlled, for example, by means of a float switch arranged in the condensate collecting vessel. The valve may be opened for drainage at a certain condensate level detected by the float and closed again at a lower level. Alternatively or additionally, the valve may also be timed and / or clocked to be activated after predetermined time intervals. These embodiments also work, as in the above embodiment, also in the unpressurized state, but can also be functional in printing operation with appropriate dimensioning as stated above.

The two automated dewatering devices operate advantageously fully automatically, without that sequential drains must be scheduled and monitored and carried out by hand.

With reference to a drawing embodiments of the dewatering device according to the invention are further explained.

Show it:

1 a simple embodiment for external drainage,

2 a hand-operated embodiment with a condensate collecting vessel,

3 an automated embodiment with a float valve, and

4 an automated embodiment with a solenoid valve.

In 1 is schematically an air compressor 1 shown with a compressor unit 2 and an associated pressure vessel 3 ,

The air compressor 1 is exemplary here as a mobile, single-axle air compressor with two wheels 4 and a pedestal 5 shown. On the bottom 6 of the pressure vessel 3 there is a drainage opening 7 , which with a (not necessarily required for the further function) designed as a ball valve container valve 8th can be locked. To the drainage opening 7 or the container valve 8th is a relatively long compressed air line 9 connected, which withstands the operational pressures. To the compressed air line 9 End is a condensate drain valve 10 connected, which is designed here as a ball valve.

In the lower inner area of the pressure vessel 3 accumulated condensate can in compressor operation by the pressure vessel 3 established pressure via the compressed air line 9 by hand with the condensate drain valve 10 be discharged (schematically represented by the drops 11 ).

In 2 is one opposite to the embodiment according to 1 around a condensate collection vessel 12 supplemented second embodiment shown. The reference numerals 1 to 11 were retained for the unchanged characteristics.

The condensate collection vessel 12 is cylindrical and arranged vertically, the compressed air line 9 is connected at the top and the condensate drain valve 10 is attached below. In an upper region of the condensate collecting vessel is a plug-shaped, flow-through channels having condensate separator 13 introduced, in which fine water mist can catch and drain as condensate, the condensate level 14 the drained condensate is shown schematically by a wavy line. Collected condensate must also in the second embodiment by hand with the condensate drain valve 10 be drained.

In a third embodiment according to 3 is the embodiment according to 2 through a float valve 15 added, which at the bottom of the condensate collection vessel 12 is arranged. The float valve 15 consists of a condensate discharge opening with a sealing ring 16 as a valve seat at the bottom of the condensate collection vessel 12 and an associated float ball 17 ,

The float ball 17 can with increasing condensate level 14 Float with this, thereby from the sealing ring 16 lift off and drain the condensate 11 automatically release (with the hand-operated condensate drain valve 10 as well as the container valve 8th must be open).

In a fourth embodiment according to 4 for a likewise automatic emptying is in place of the float valve 15 from 3 a solenoid valve 18 used as a condensate drain valve. The solenoid valve 18 is with an outlet pipe 19 fluidly with the bottom of the condensate collection vessel 12 connected and depending on the switching position lock or release the drain of condensate.

The solenoid valve 18 is with an electrical primary supply line 20 connected, and is via a secondary supply line 21 with a float switch 22 controlled, the floating element according to the condensate level 14 is moved. With rising condensate level 14 the float switch switches 22 the solenoid valve 18 in its open position, thus condensate 11 can drain away. For a lower condensate level 14 becomes the solenoid valve 18 with the float switch 22 closed again. To prevent too frequent switching on the solenoid valve here, it may be appropriate to run the controller in addition via a timer, so that the solenoid valve 18 can only be activated within a released period of time, for example once or possibly more often on the day after predeterminable time intervals. Even a mere control via a timer is conceivable in principle.

Alternatively, the solenoid valve 18 only timed without float switch 22 clocked at predetermined time intervals for a predetermined discharge time to be activated and opened.

Claims (11)

Air compressor with a pressure vessel ( 3 ) with a device for dewatering condensate, a drainage ( 7 ) on the bottom ( 6 ) of the pressure vessel ( 3 ) and one of the drainage opening ( 7 ) downstream condensate drain valve ( 10 ; 15 ; 18 ), characterized in that to the drainage opening ( 7 ) of the compressed air tank ( 3 ) a compressed air line ( 9 ) with an end condensate drain valve ( 10 ; 15 ; 18 ) is connected to a length of the compressed air line such that the condensate drain valve ( 10 ; 15 ; 18 ) at a suitable accessible location, spaced from the bottom ( 6 ) of the pressure vessel ( 3 ) is positionable. Air compressor according to claim 1, characterized in that the pressure vessel ( 3 ) at the drainage opening ( 7 ) a manually operable container valve ( 8th ) is arranged, to which the compressed air line ( 9 ) directly or indirectly the end condensate drain valve ( 10 ; 15 ; 18 ), is connected. Air compressor according to claim 1 or claim 2, characterized in that the condensate drain valve ( 10 ) and possibly the container valve ( 8th ) is a manually operable one-way valve, in particular a ball valve. Air compressor according to claim 1 or claim 2, characterized in that the condensate drain valve ( 10 ; 15 ; 18 ) a preferably cylindrical condensate collecting vessel ( 12 ) upstream of the compressed air line ( 9 ) and on the other hand at the bottom the condensate drain valve ( 10 ; 15 ; 18 ) is arranged. Air compressor according to claim 4, characterized in that in the condensate collecting vessel ( 12 ) a condensate separator ( 13 ) is arranged, wherein in a vertically oriented, cylindrical condensate collecting vessel ( 12 ) a plug-shaped, flow-through channels having condensate separator ( 13 ) in an upper region of the condensate collecting vessel ( 12 ) is arranged. Air compressor according to claim 4 or claim 5, characterized in that the condensate collecting vessel ( 12 ) downstream, preferably attached to this condensate drain valve ( 10 ) is a hand-operated ball valve. Air compressor according to claim 4 or claim 5, characterized in that the condensate collecting vessel ( 12 ) as a condensate drain valve a float valve ( 15 ), with a condensate discharge opening with sealing ring ( 16 ) as a valve seat and an associated, above the sealing ring ( 16 ) in the condensate collecting vessel ( 12 ) float, preferably a float ball ( 17 ) as a movable valve body. Air compressor according to claim 7, characterized in that after the condensate drain opening a hand-operated shut-off valve ( 10 ), preferably a ball valve is mounted. Air compressor according to claim 4 or claim 5, characterized in that the condensate collecting vessel ( 12 ) downstream, preferably connected to this condensate drain valve a switchable valve, preferably a switchable solenoid valve ( 18 ) is. Air compressor according to claim 9, characterized in that the valve ( 18 ) by means of a condensate collecting vessel ( 12 ) arranged float switch ( 22 ) is controllable, in particular at a certain condensate level detected by the float ( 14 ) is apparent. Air compressor according to claim 9 or 10, characterized in that the valve ( 18 ) is time-controlled and / or clocked after predetermined time intervals can be activated.

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