DE102013109074A1 - Suction dredger for pneumatic intake of suction material - Google Patents

Abstract

The invention relates to a suction dredger (1) in which an air flow (13) which has been heated during passage of a fan (7) is used for heating, keeping warm and thawing already iced components of the suction dredger (1). The air flow (13) can be branched off as a guided air flow (13.1) by means of an air flow diverter (11) from an exhaust air duct (8) and distributed through a return duct (10) with outlets (12) in the suction dredger (1). The suction dredger (1) according to the invention can be operated in a fluidic short-circuit state, in which the air flow (13) in the interior of the suction dredger (1) is circulated.

Description

The invention relates to a suction dredger for the pneumatic intake of suction material in the form of solid or liquid media from an environment of the suction dredger by means of a fast flowing air flow, as this generically from the DE 38 10 932 A1 is known.

There are a whole series of suction dredgers known from the prior art, all as essential components a suction hose with a suction mouth, a separator serving as a collecting container for receiving the separated suction material, a baffle plate, which deflects the material down, a filter unit for cleaning the air flow and at least one fan having a Zuluft- and an exhaust duct for generating the air flow. Such suction dredgers are in the, for example, only given, DE 38 10 932 A1 and DE 200 04 860 U1 described. Based on the basic components mentioned, suction dredgers have been further developed and improved in many details in recent years. This suction dredger for low-damage excavation of z. B. earth in the field of supply lines in construction in recent years has become well known.

Usually generate in the suction dredgers radial fans large, very fast-flowing air currents, which entrain a male material (henceforth suction product), which is located in the region of the suction mouth, with it. However, these fast air currents also cause adverse effects. At temperatures around the freezing point, this leads to a rapid cooling of the fluidically arranged in front of the fan components of the suction dredger. At temperatures around 0 ° C and even slightly above, these air-bearing components of the suction dredge start to freeze. In this case, moist suction material on the walls, such as the suction hose or the separator, freeze. In the suction hose thereby causing a disadvantageous reduction of the suction cross-section.

Likewise, existing ultrafine filter cartridges can freeze the filter system. This is favored by the fast-flowing air currents still. The extremely disadvantageous freezing of the components of the suction dredger potentially occurs in all known suction dredger models when operated at correspondingly low ambient temperatures.

The invention has the object to provide a way to avoid and to eliminate unwanted icing when using a suction dredger at low temperatures.

• – einen Saugschlauch mit einer Saugmündung,
• – einen Abscheider zur Abscheidung des Sauggutes aus dem Luftstrom,
• – eine Filteranlage zur Reinigung des Luftstromes und
• – mindestens einen Ventilator mit einem Zuluft- und einem Abluftkanal zur Erzeugung des Luftstromes.

The object is achieved by a suction dredger for the pneumatic intake of suction material in the form of solid or liquid media from an environment of the suction dredger by means of a fast-flowing air flow, that the heat energy of the air flow in the exhaust duct is supplied to each component or at least temporarily, the suction dredger at least the following components:

• A suction hose with a suction mouth,
• A separator for separating the suction material from the air stream,
• - A filter system for cleaning the air flow and
• - At least one fan with a Zuluft- and an exhaust duct for generating the air flow.

An inventive suction dredger is characterized in that an air flow diverter and a return duct with an input and at least one outlet for ventilating one or more components are provided, wherein the input is connected via the air flow diverter to the exhaust duct.

The return passage serves to return portions of the airflow or the entire airflow to a single component or multiple components of the suction dredge. The return channel can have different cross sections and dimensions, which can also be changed along the path of the return channel. In further embodiments of the suction dredger according to the invention, the return channel can also be designed to be divided and consist entirely or partially of a plurality of individual channels.

By the air flow diverter, which may be formed, for example, as a hinged flap, the guided in the exhaust duct air flow is at least partially deflected in the return duct.

The core of the invention is to use the heat energy of the air flow of the exhaust duct to avoid icing. The airflow can be used for heating, keeping warm and / or drying components as well as thawing already frozen components.

In particular, when using centrifugal fans, the air flow is sucked in, accelerated and compressed. The compression is in high-performance fans in the range of about 0.2 bar. For multi-stage, serially arranged fans this compression value increases per stage. Due to the compression of the air stream, it is heated up to 20 K per fan step.

The fan is preferably a radial fan. It may also be an axial fan or a fan of a different design in further embodiments of the suction dredge according to the invention. There may be several similar or different fans.

The channels such as supply air duct, exhaust duct and return duct are preferably made of metal and can have different cross sections, z. B. round or square, have.

The outputs of the return channel may be formed, for example, as holes or slots.

The return channel may have flow-conducting and / or flow-blocking elements. Flow-conducting elements may for example be arranged in the feed channel baffles. Flow blocking elements can, for. B. slides, flaps or valves. The flow-conducting and / or flow-blocking elements may advantageously be controllable in order to set different ventilation states of the components. The flow-conducting and / or flow-blocking elements of the return channel or further flow-conducting and / or flow-blocking elements can also be assigned to one or more outputs. The control of the flow-conducting and / or flow-blocking elements can be realized mechanically, electrically, hydraulically or pneumatically. A control can also be manually possible in addition to computer-based or loop-based controls.

In a first embodiment of a suction dredge according to the invention, at least one outlet can be arranged at a distance in front of the suction mouth. By such a design, a proportion of the warm air flow in front of the suction orifice can be conducted and is sucked back into the suction hose to a large extent during operation of the suction dredge. The warm air flow heats the suction hose, which reduces or completely prevents icing of the suction hose. In order to be able to respond to different ambient temperatures and working conditions of the suction dredger, the distance of the output of the suction orifice can be adjustable.

The air flow switch is preferably controllable. It is advantageous if the air flow switch can be controlled, so that metered between 0 and 100% of the air flow in the exhaust duct can be routed as a supplied air flow in the return channel. If the entire air flow is passed as supplied air flow in the return channel to the inner components of the suction dredger, the suction dredger is operated in an internal flow circuit (fluid short circuit condition). If the entire air flow is directed outwards to the suction orifice, this is only a partial short circuit, since outside air is always drawn in as well. The air flow is circulated inside the suction dredge and further heated. This operating state of the suction dredger is particularly suitable for thawing already frozen components and to warm components of the suction dredger. For this purpose, the suction dredger can remain at his work and must not be spent for thawing to another place. As a result, efficient use of a suction dredge according to the invention is also supported at low ambient temperatures. After sufficient heating of the components by driving the air flow switch and optionally the flow-conducting and / or the flow blocking elements again a conveying state as the operating state of the suction dredger reached in which a proportion of the air flow, or the entire air flow is blown through the exhaust duct into the environment or wholly or partially is guided to the suction mouth. The air flow diverter and the return duct are advantageously usable for heating the one or more components, wherein heat of the supplied air flow is transmitted to the one or more components. The heating of the components takes place by heat conduction, heat transfer and convection. Another advantage of the suction dredger according to the invention is that in the return duct heating elements are installed, so that a further increase in the air temperature is achieved. This makes it advantageous to use a suction dredge according to the invention at lower temperatures than previously possible. A further advantage of the suction dredger according to the invention is that wet-cleaned fine filters can be dried again particularly easily in short-circuit operation.

The invention will be explained in more detail with reference to figures and embodiments. Show it:

1 a first embodiment of a suction dredge according to the invention in the conveying state and

2 the first embodiment of the suction dredge according to the invention in the short-circuited state.

As essential elements of a suction dredge according to the invention 1 are in 1 a suction hose 2 with suction mouth 2.1 , a separator 3 , a filter system 4 , a fan 7 , an exhaust duct 8th with exhaust duct opening 9 , an air flow switch 11 and a return channel 10 with outputs 12 shown.

With the fan running as a radial fan 7 is an airflow 13 generated from an environment of the suction dredger 1 through the suction mouth 2.1 in the suction hose 2 and from there to the separator 3 arrives. This is due to the air flow 13 dirt in 5 from the vicinity of the suction mouth 2.1 carried away. In the separator 3 the airflow slows down 13 and loses transportability. The suction material 5 falls out of the air stream 13 off and remains in the separator 3 while the airflow 13 through the filter system 4 occurs and via a supply air duct 6 to the fan 7 arrives. From this is the air flow 13 in the exhaust duct 8th pressed. In the exhaust duct 8th opens the return channel 10 with his entrance. At the confluence of the return channel 10 in the exhaust duct 8th is the air flow switch 11 arranged movable and controllable. Shown is the air flow switch 11 in half open position. About half of the airflow 13 is through an exhaust duct opening 9 the exhaust duct 8th blown into the environment. The other half of the airflow 13 is through the air flow switch 11 as supplied airflow 13.1 in the return channel 10 directed. In the return channel 10 are outputs 12 present, through which a portion of the supplied air flow 13.1 from the return channel 10 exit. The exits 12 are on the filter system 4 and in the separator 3 directed. In the return channel 10 are also flow-conducting and / or flow-blocking elements 14 in the form of individually controllable flaps available. The control of the air flow switch 11 and the flow-conducting and / or flow-blocking elements 14 takes place hydraulically via a controller 15 (shown greatly simplified). Depending on the control state of the flow-conducting and / or flow-blocking elements 14 is a proportion of the supplied air flow 13.1 through the exits 12 directed. Are both flow-conducting and / or flow-blocking elements 14 opened, is a proportion of the supplied air flow 13.1 up to an exit at the suction mouth 12.1 guided and blown out to the area. It can also have at least one exit 12 through a wall of the suction hose 2 into the interior of the suction hose 2 be directed.

A distance from the outlet at the suction mouth 12.1 from the suction mouth 2.1 is manually adjustable. In a further embodiment, the distance may also be pneumatically, electromotively, hydraulically or mechanically adjustable.

In other embodiments of the suction dredge invention, other numbers and gradients of return channels 10 , as well as other numbers and orientations of outputs 12 to be available.

At the in 2 shown short-circuit state of the suction dredger 1 is the air flow switch 11 completely closed, so that the entire air flow 13 the exhaust duct 8th as supplied airflow 13.1 in the return channel 10 is directed. The flow-conducting and / or flow-blocking element 14 , which is arranged in the flow direction last, is closed. The supplied air flow 13.1 is through the outputs 12 towards the filter system 4 and in the separator 3 directed. In the separator 3 is due to the structural and fluidic conditions of the separator 3 and the supplied airflow 13.1 a circulating flow of airflow 13 causes. This circulating flow flows through the filter system 4 and the supply air duct 6 back to the fan 7 and is there again compressed, heated and in the exhaust duct 8th pressed. To further increase the efficiency can be in the return channel 10 Install heating elements, which is a further increase in temperature of the supplied air flow 13.1 cause. The control 15 can in further embodiments of the suction dredge according to the invention 1 associated with measuring means (not shown) such as icing sensors, humidity sensors and / or temperature sensors.

LIST OF REFERENCE NUMBERS

1

Saugbagger

2

suction

2.1

suction mouth

3

separators

4

filter system

5

dirt in

6

supply air duct

7

fan

8th

exhaust duct

9

Exhaust duct opening

10

Return channel

11

Air flow switch

12

output

12.1

Output at the suction mouth 2.1

13

airflow

13.1

supplied air flow

14

flow-conducting and / or flow-blocking element

15

control

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3810932 A1 [0001, 0002]
• DE 20004860 U1 [0002]

Claims (10)

Suction dredger for the pneumatic absorption of suction material in the form of solid or liquid media from an environment of the suction dredger by means of a fast-flowing air flow, the suction dredger comprising at least the following components: - a suction hose with a suction mouth, - a separator for separating the suction material from the air flow, A filter system for cleaning the air flow and at least one fan with a supply air duct and an exhaust air duct for generating the air flow, characterized in that the heat energy of the air flow in the exhaust duct ( 8th ) individual or all components at least temporarily be fed. Suction dredger according to claim 1, characterized in that an air flow diverter ( 11 ) and a return channel ( 10 ) with one input and at least one output ( 12 ) are present for venting one or more components, wherein the input via the air flow switch ( 11 ) with the exhaust duct ( 8th ) connected is. Suction dredger according to claim 2, characterized in that at least one outlet at the suction mouth ( 12.1 ) at a distance in front of the suction mouth ( 2.1 ) is arranged. Suction dredger according to claim 3, characterized in that the distance is adjustable. Suction dredger according to one of claims 2 to 4, characterized in that the exits ( 12 ) flow-conducting and / or flow-blocking elements ( 14 ) exhibit. Suction dredger according to one of claims 2 to 5, characterized in that the return duct ( 10 ) flow-conducting and / or flow-blocking elements ( 14 ) having. Suction dredger according to claim 5 or 6, characterized in that the flow-conducting and / or the flow-blocking elements ( 14 ) are controllable. Suction dredger according to one of the preceding claims, characterized in that the air flow diverter ( 11 ) is adjustable so that the air flow ( 13 ) of the exhaust duct ( 8th ) partially or completely as supplied air flow ( 13.1 ) in the return channel ( 10 ) is conductive. Suction dredger according to one of the preceding claims, characterized in that in the return duct ( 10 ) Heating elements are present. Use of the air flow switch ( 11 ) and the return channel ( 10 ) according to one of the preceding claims for heating one or more components of the suction dredger ( 1 ), wherein heat of the supplied air stream ( 13.1 ) is transferred to one or more components.

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