DE102010010281A1 - Device for internal cleaning of heat exchanger pipes, has nozzle, which is positioned in heat exchanger tubes, from which scratches are loaded with pressurized water - Google Patents

Abstract

The device has a nozzle (9), which is positioned in the heat exchanger tubes, from which the scratches are loaded with pressurized water. The scratches are compressed through the heat exchanger pipes by pressurized water. The nozzle is provided with a water inlet pipe. A valve and a pump are provided for controlling the water flow.

Description

The invention relates to a device for internal cleaning of heat exchanger tubes, in particular of cooling tubes industrial cooler.

Such coolers occur, for example, in power generators or chemical plants. In power generation plants, the heat exchangers are used in particular as so-called capacitors. He serves there to liquefy the exhaust steam. This allows a closed coolant circuit. Contemporary capacitors in power generation plants exist as water-cooled surface capacitors. They have tube bundles. Through the cooling tubes of Abdampfkondensatoren cold cooling water is performed. The exhaust steam condenses on the outer surface of the cooling tubes. The number of cooling tubes in a condenser can be large. A number of 20,000 cooling tubes is not uncommon for the power plant capacitors. Depending on the design, heating of the cooling water in the cooling tubes should take place at 8 to 10 degrees Celsius.

The cooling water is usually taken from the environment. In order to limit contamination of the capacitors, the cooling water is cleaned before it flows into the cooling tubes.

Cooling of the vapor creates a negative pressure in the condenser, which is regularly referred to as a vacuum, although in the strict sense it is not a vacuum. This negative pressure is of great importance for the efficiency of the steam-powered power plant. The efficiency is determined to a large extent by the pressure gradient between the pressure (in the flow direction of the steam) in front of the steam turbine and the pressure behind the steam turbine. Since the cooling of the steam depends on the heat transfer in the cooling tubes, there is also a dependence of the negative pressure on the heat transfer. At the same time it should be noted that the heat transfer of the cooling tubes is reduced by contamination of the cooling tube inner surface. The contamination of the cooling tube inner surface is inevitable in conventional capacitors despite filtering the cooling water. Therefore, there is always a need for cleaning on conventional capacitors. Depending on the medium to be cooled or heated, which is passed through the cooling tubes, deposits are formed in the cooling tubes despite the filtering. This is true even with water. The main constituent of the deposits from the water is lime, unless the water has been previously descaled. But there are also significant deposits of manganese, iron and silica on cooling pipes made of steel, stainless steel, titanium or brass. Cooling tubes made of copper are also popular. Copper has significant corrosion problems. Upon contact with oxygen, copper oxides form. Oxygen is found in the cooling water, as well as in the steam.

The deposits usually lead to a deterioration of the heat transfer of the cooling tubes. As a result, the cooling performance decreases. However, deposits can be called corrosion or fouling. Therefore, a cleaning of the cooling pipes is not only useful for improving the heat transfer. If the corrosion is ignored, porous deposits form, which can increase the corrosion so that pitting can be talked about.

There are various cleaning devices for internal cleaning of the cooling tubes known, with which the heat transfer is to be improved again and with which the cooling capacity to be raised again. Such devices are described, for example, in: DE 69812512T2 . EP698423A . US2170997 . US2418509 . US 2734208 . US4281432 . DE69507221 T2 . US5153963 . SU1414-482-A . US5305488 . DE69200433T2 . U'S1598771 . DE698121511T2 . US 3604041 , In these documents, scratches are disclosed, which are pushed one or more through the cooling tubes. The scratches have different shapes. Recurring is the shape of resilient hook, the hooks are connected at one end to the scratch and slide with the other, hook-shaped end on the inner wall of the cooling tube. The sharper the hooks, the better the cleaning effect. In part, the hooks at the contact ends are called blades.

In addition, the hooks at their end, with which they touch the inner surface of the cooling tube, adapted to this surface, that is, curved.

There are also scratches that are wholly or partially designed as brushes, as well as scratches, the first tear rips in the deposits in order to be able to remove one after the rest better

The scratches are preferably moved with pressurized water through the cooling tubes. For this purpose, the scratches are formed piston-like at one end. Piston-like, because there is no defined piston clearance. Rather, it must be considered that the deposits have different thickness. The piston-like end has to adapt to that. This is usually done with sealing lips at the end of the scratch. The sealing lips can be distributed at a small distance around the circumference. The permeability to the pressurized water associated with the distances may be beneficial in order to flush the deposits previously scraped off the hooks / cutters forward from the cooling pipe being cleaned.

For the application of pressurized water usually water pistols are used. The water guns have a front nozzle, with which the guns are pressed by hand into the opening of a cooling tube. At the same time pressed with a dome-shaped sealing part of the gun against the radiator plate in which the cooling tubes are held.

At a water pressure of up to 20bar, depending on the water pressure, a force is required to seal the gun tightly, depending on the area where the pressure develops, which can easily or even exceed much of a cleaning man's body weight. Even if a gun is tilted in a cooling tube, and thus facilitates holding the gun, a tremendous physical effort remains for a cleaning man.

In addition, the physical effort increases as the posture becomes more difficult for the operator. From the difficulties arises a picture, if one realizes that the freedom of movement in front of the cooling tubes can sometimes be very small, for example only 500 mm and / or also requires an attitude of the pistol at head height and even overhead.

In practice, the operators have to pause again and again.

According to another proposal, a significant simplification and ease of cleaning is achieved in that the projecting into the cooling tubes gun end or the projecting into the cooling tubes / heat exchanger tubes part is provided with a spreading mechanism. By spreading the projecting into the cooling tube gun end the gun can be clamped and fixed there, so that the cleaning personnel is fully or partially relieved of the pressure described. With complete relief can be spoken of a complete self-clamping or self-locking against loosening.

The spreading mechanism can have different shapes.

An advantageous embodiment provides for the use of elastic, annular on the projecting into the cooling tube end material before. Compression causes a thickening, which clamps and locks the gun in the cooling tube. The elastic material may be rubber or compliant plastic such as elastomers. The elastic material can be used in the form of conventional O-rings. It is possible to arrange several rings in the axial direction one behind the other. Other profiles can also be used. Particularly advantageous are profiles that show an elongated cross-section in a running in the axial direction section. Such cross sections may, for example, have straight and / or round and angular surfaces. Rectangular cross sections and oval cross sections are included. Preferably find exactly rectangular cross-sections application. Such shapes, like other shapes of appropriate numbers, can be made economically. For small quantities, the molds can be cut from solid material with sufficient strength of the rubber or elastomer. A sufficient strength can be clarified by one or a few tests. For example, sufficient strength is provided by rubber and elastomer, which is standard for commercial hoses DIN 73411 Find application. For example, the molds of the invention may be formed by a tube section. In this case, hoses with a wall thickness of at least 1 mm, preferably of at least 1.5 mm and more preferably of at least 2 mm, and most preferably of at least 2.5 mm are favorable. Such hoses made of rubber and elastomers are commercially available, even with a fiber reinforcement. This prolongs the possible life and increases the usability. The commercially available hoses have nominal widths / wall thicknesses / outside diameters in mm of 10 / 3.5 / 17; 03/13/19; 16 / 3,5 / 23; 04/19/27; 25 / 4,5 / 34; 32/5/42; 38 / 6.5 / 51; 45 / 7,5 / 60; 50 / 7.5 / 65 These include, for example, commercially available cooling tubes with nominal diameters in mm of 15; 20; 25; 32; 40; 50; 65 opposite. After pollution, although the opening width of the cooling tubes is reduced. However, it can be assumed that the nominal diameter, because before positioning a gun in the cooling tubes first the scratches must be pressed into the cooling tubes and the cooling tubes are thereby released on a length required for positioning of the narrowing deposit. As a result, for example, tube sections with the following outer diameters can be used directly or indirectly after machining of the outer sheath for the spreading according to the invention in the tube opening: Tubing diameters Pipe size 17 15; 20; 19 20; 23 20; 25; 27 25; 34 32; 42 40; 51 50; 65 65;

When selecting the starting material for the described production of hose sections and a sufficient play of movement for the insertion of the gun must be considered in the pipeline. The movement can theoretically be small. Preferably, however, at least one clearance (here equivalent to a difference to the inner diameter / nominal diameter of the tube) of at least 0.5 mm, preferably at least 1 mm and more preferably at least 1.5 mm and most preferably provided by at least 2 mm.

The tube sections are bulged in the radial direction against the tube inner wall. This happens, for example, by axial compression. So that the end faces of the tube sections are gently pressurized when compressed, at the end faces of the tube sections are preferably provided with a metal cap. The metal cap can be made of thin sheet metal, for example with a thickness of less than or equal to 0.6 mm, preferably less than or equal to 0.4 mm and even more preferably less than or equal to 0.3 mm.

The metal cap preferably covers at least 50%, more preferably at least 70%, and most preferably at least 90% of the associated end face of the hose section.

It is also advantageous if the metal cap comprises the hose section at the associated end with an edge of at least 2 mm, more preferably of at least 4 mm and most preferably of at least 6 mm in the axial direction.

The annular elastic, expandable materials with the elongated cross-sections described above have no appreciable tendency to roll even under extreme water pressures occurring here.

Deformation of the resilient material may be effected by means of a power piston which presses the resilient material against, for example, a flange / flange fixed to the gun against a flange / flange fixed on the gun or the elastic material between two flanges movable on the gun. Squeezes stops or widening of the annular material from the inside causes. Each stop / flange forms a pressure surface and can be formed by existing or additional parts.

It is advantageous to provide a movable sleeve with a stop to provide a movable stop or to form the stop by the movable sleeve. The sleeve can at the same time completely or partially form the nozzle and / or completely or partially form the water pipe of the gun to the nozzle. Alternatively, the sleeve may be arranged in whole or in part on the nozzle displaceable and / or be arranged in whole or in part displaceably on the water pipe of the gun.

Preferably, the following embodiment is provided: the piston arranged in a cylinder. The pressure water supply is flanged in the direction of movement of the piston in front of the piston to the cylinder. The piston rod is hollow and serves as a water supply to the nozzle of the gun. The nozzle sits at the end of the piston rod protruding out of the cylinder. The piston rod penetrates the end wall of the cylinder. On the outside sit on the piston rod a movable sleeve. Between sleeve and nozzle a plurality of axially successively arranged O-rings are provided. The nozzle, the O-rings and the sleeve have an outer diameter which is smaller by so much than the inner diameter of the cooling tubes to be cleaned, as maximum with a contamination of the pipe inner surface is to be expected. A load of the piston with pressurized water causes a movement of the piston and a train over the piston on the piston rod, so that the train also acts on the nozzle and the nozzle moves against the O-rings, while the sleeve rests against the end face of the cylinder and can not escape, so that the O-rings deform as the diameter increases and press against the pipe inner wall.

In the embodiment with the expansion of the expansion of the elastic, annular material, for example, a conical or a different inclined mandrel is suitable, which may also have a sleeve shape and in the central opening of the elastic and preferably axially fixed elastic material acts , The expanding mandrel can in turn be weaved with a piston or other mechanism. It also motors can be used. The motors may be pressurized water driven motors or pneumatic driven motors. The control of the motors can be carried out in the same way via the drive medium or via intermediate valves as in the other variants of the invention.

Optionally, the motor with water or another medium, eg. B. operated with compressed air.

When using water, it can be pressurized water that is generated by the same pump that also supplies the water to move the scratches or to flush the cooling tubes. When using the same water for the movement of the scratches and the operation of the piston valves in the line to the nozzle and in the line to the piston are advantageous, which allow a pressure adjustment. By adjusting the pressure in the nozzle and in the piston, the cleaning operation and the locking of the gun in the cooling tube can be optimized. A good attitude can already be found with a few adjustments. After knowing a good setting, a permanent pressure distribution between nozzle and piston can be used.

The use of a valve in the gun, although known from conventional guns, also the adjustability of the valve and the on-off function of the valve. However, not known is the diversion of pressurized water for the piston and the switching of another valve. Preferably, the diversion of pressurized water for the piston takes place before the valve for regulating the pressure water for the nozzle. As a result, the position of the gun regardless of the cooling tube can be maintained whether the pressurized water to the nozzle is started, interrupted, continued or canceled. If the valve can simultaneously assume an on or off position in the gun supply line to the piston, and if this valve, like the valve in the supply line to the nozzle, can be locked in the desired position, further advantages open up.

It can be several pistols operated by a cleaning person at the same time. This multiplies the performance of this cleaning person.

It is favorable if the valves are at the same time provided with a pressure limiter. The pressure limiter allows the gun to react automatically when a blockage occurs. Then the pressure limiter can respond to an increase in pressure and bring the valve in the off position, in which the pressure water supply to the nozzle is interrupted. Thereafter, an attempt can be made to eliminate the scratch by pulsating pressure and / or with an increase in pressure by valve actuation or valve adjustment before the scratch is otherwise shaken or even a cumbersome backward movement of the scratch is initiated.

Similarly, the pressure limiter can respond to a pressure drop when a scratch has fallen out of the cooling tube after the cleaning end. With such a pressure drop, the valve in the supply line to the nozzle is also triggered and the pressure water supply is interrupted.

The shaking loose the scratch can be done with two guns according to the invention, when the valves on both pistols, a valve position is provided in which the pressurized water supply is interrupted and in which the water supply to the nozzle is released. Then the second gun can be used at the cooling tube inlet and operated in alternation with the gun at the cooling tube inlet, so that the stuck scratches can be applied alternately from the one side and the other side with pressurized water. According to the invention, when the pressure is applied to the one side, a ventilation of the line to the nozzle on the other side is provided. Optionally, the valve actuation can be electrically / electronically controlled. With a chip, various functions of the valves can be controlled.

The controller can respond to specific operating pressures in front of and behind the valve. The controller can effect the necessary pressure changes for a shaking operation. The controller may also respond to the particular operating pressure discussed above, which occurs when the scratches are a cooling tube have migrated and have leaked out of the cooling tube. Then the controller can respond faster and safer than the operator and set the gun to Off, so that a pressure loss is avoided. This is important if a single cleaning person handles several guns at the same time.

The controller may also include a safety shutdown, which will be effective when a gun has not yet found a sufficient seat in a pipe. Then the gun with a high-pressure jet could pose a danger to the cleaners.

The controller may also visually and / or acoustically and / or by vibration indicate each operating condition. The optical displays can be formed by light-emitting diodes. The vibration through magnets, the acoustic through miniaturized speakers. In addition, with the help of pressure sensors each operating pressure can be measured and processed with the controller. Furthermore, the controller can be linked to displacement sensors. This can be used, among other things, to shut down the gun if the gun does not reach the correct position in a cooling tube.

Commercially available chips are able to accommodate the necessary programs. The power consumption of these chips is so low that a button cell is sufficient. The controller can be enclosed in the gun, permanent or openable. The power source in the form of the button cell or other form is preferably interchangeable and moisture proof in the gun. The moisture protection is achieved by means of appropriate sealing rings.

All guns can be supplied with pressurized water by the same pump. Conveniently, a pump system with a pressure vessel arranged between the pump and pistols. As a result, the pressure conditions even out with irregular demand for pressurized water.

In the variant of the invention, is provided for the operation of the piston compressed air, in addition to the specific nozzle for the pressure water supply to the gun still a compressed air supply to the piston of the gun is provided. Compressed air is usually available for larger operating systems. Optionally, the compressed air is also generated by a compressor. An advantage is a compressed air tank between the compressor and guns. This equalizes the pressure conditions and facilitates the connection of different guns.

A further variant of the invention provides that, instead of pistons and rings in the front region, with which the gun projects into a cooling tube, provided an inflatable or inflatable bellows. The bellows simplify the construction effort of the guns. The bellows can like the piston with pressurized water or compressed air are applied and controlled.

Optionally, the guns according to the invention with the expandable region on the input side sit so far in the cooling tubes, that there is a distance from the input-side plate, in which the cooling tube are held together.

Optionally, the seat of the guns according to the invention in the cooling tubes is also chosen so that the spreadable range extends beyond the input-side plate of the radiator. The result is a relief of the cooling tube from the spreading pressure, because the spreading pressure is absorbed to a substantial extent by the input-side plate.

With the water pistols according to the invention, the cooling pipes are accessible even in the narrowest space. For example, the pistols can be positioned with a rod or with long tongs. With the rod or extended pliers, the guns can also be operated from some distance.

The invention also has the task of simplifying and facilitating the cleaning. The invention is based on the recognition that the introduction of scratches considerable effort. The scratches are in fact introduced in front of the gun in the respective pipeline to be cleaned. In this case, the resistance must be overcome, put the deposits in the cooling tube to introduce the scratches. It is common to hit the scratches in the cooling pipes with a mallet. This too is extremely exhausting, because you usually have to work within a tight space. The cleaning person involved in hammering the scratches can not arbitrarily pick out.

According to the invention, a substantial relief of the work is achieved by means of a pneumatic chisel or with the aid of a hydraulically operated chisel hammer or with the aid of an electric hammer. Commercially available hammers can be used for this purpose. As explained above, stands Pressurized water due to the described cleaning with scratches and pressurized water available. Therefore, there is no need for another source of pressurized water for the hammer. To adapt to the permissible for the operation of the hammer pressure relief valves are provided. Compressed air is usually available in large operating systems. Alternatively, compressed air can be easily generated with a portable compressor. The same applies to electricity for driving an electric hammer. The current is optionally generated by a generator.

On the selected commercial chisel hammer whose chisel is replaced with a special tool for driving in the scratches or converted into a special tool.

The conversion of the chisel takes place in pointed chisels in that a sleeve or a rod is made with a blind hole. The inner diameter of the sleeve and the diameter of the blind hole are adapted to the Spitzmeißeldurchmesser so that they can be mounted on conventional pointed chisels. Instead of the pointed chisel, other commercially available chisels can be used. These include, in particular flat chisel, which are processed at the cutting edge so that they fit into a blind hole described above or the pipe opening described above. The conventional bits are hardened or tempered, so that machining is difficult. Nevertheless, other editing options are available. These include, for example, grinding and spark erosion.

The attachment of the sleeve or rod on the pointed chisel or other machined to this, commercial chisels can be done by bolts. The sleeve or rod can also be shrunk onto the corresponding bit end.

Preferably, however, the sleeve or rod is glued to the corresponding bit end. For this purpose, various adhesives are suitable. Suitable adhesives include, for example, cyanoacrylate adhesives such as those used for threadlocking. The cyanoacrylate adhesives are chemically curing adhesives. There are also physically setting adhesives. The right glue can be selected with just a few application attempts.

The combination of a sleeve or rod with a conventional chisel, an advantageous combination of tools is created, firstly fulfills the desired function, namely the impressions of the scratches in the tubes, and secondly fulfills the desired function, namely the trouble-free and secure tool holder in the chisel hammer. The second function is obtained by using the corresponding with the tool holder in the chisel hammer bits.

It is also advantageous if the sleeves or rods are adapted to the scratch side of the shape of the corresponding scratch end. Most scratches are profiled on the contact surface where the scratches are conventionally beaten into the cooling tubes. The profiling has different reasons. The invention takes advantage of the profiling to guide the scratches when introduced into the cooling tubes and to prevent tilting. Tilted scratches can easily get stuck. The elimination of such errors causes extreme workload. In addition, the scratches may be unusable after removal of such error. Also, regardless of the sticking is from the tilting the risk of damage to the scratches. Damaged scratches no longer have the same cleaning effect as undamaged scratches.

A further advantage can be obtained by giving the tool according to the invention a length at the end projecting from the chisel hammer which is at least equal to the minimum length with which the pistol must penetrate into the cooling pipes in order to scratches in the above-described form to drive the cooling pipes. So far, it has been found that the minimum length is not complied with the conventional hammering the scratches.

Optionally, the minimum length is maintained by providing the sleeve or rod with a collar which can be brought into abutment with the end of the cooling tube by the chisel hammer. The front end of the sleeve or rod in front of the collar then defines the extent to which the scratches have been driven into the tube. Preferably, the collar is located on the hammer-side sleeve end or rod end.

That a tool according to the invention is able to drive different scratches, which are intended for the same cooling tubes, in these cooling tubes, is in the expectation. In addition, it is already an advantage that the same tool is also suitable for driving scratches in at least one other cooling tube with a larger or smaller nominal size. It is advantageous if the sleeve or rod at the end, which is intended to penetrate into the cooling tubes, the smallest occurring Scratch diameter is adjusted so that all other scratches can be driven with the tool according to the invention in the existing cooling tubes.

In the drawing, an embodiment of the invention is shown.

The cleaning device according to the invention only roughly reminds us of conventional water pistols for cleaning cooling tubes. In the drawing is a cooling tube 15 shown in dashed lines. The cooling tube 15 belongs to a variety of identical cooling tubes, which are arranged together in a radiator. This is the right end of the cooling tube in the view 15 held with the same ends of the other cooling tubes in a plate, not shown, of the radiator. The cooling tube 15 is shown shortened in the view. The left end of the cooling tube in the view 15 is held with the same ends of the other cooling tubes in another plate. In the exemplary embodiment, the cooling tubes are traversed by water inside and flows around the outside of flue gases of a combustion, not shown. The flue gases emit a significant part of their heat through the cooling pipes to the water. During the cooling operation, deposits occur in the cooling tubes, which necessitate internal cleaning of the cooling tubes. For internal cleaning scratches, not shown in the right in the view of the end of the cooling tube 15 pressed, as in the DE 69507221T2 are shown. The scratches are filled with pressurized water through the cooling tube 15 pressed until the scratches on the left end of the cooling tube 15 from the cooling tube 15 fall out.

The pressurized water is mixed with one in the cooling tube 15 self-clamping device in the cooling tube 15 pressed. The self-clamping device includes a cylindrical housing 16 with a pressurized water connection 12 , as well as with a pipe 17 that has an entrance opening 18 for the pressurized water and into the cooling pipe 15 to a conical nozzle 9 enough. The nozzle 9 has a larger outside diameter than the tube 17 , It is a screw connection of the nozzle 9 with the pipe 17 provided that a replacement of the nozzle 9 allowed. The replacement is required to adapt the device to other cooling tubes that have a smaller or larger inner diameter. The parts to be replaced also include O-rings 5 and passport sleeves 10 and 19 , These parts also sit on the tube 17 , The fitting sleeves determine the position of the O-rings and their distance to the housing 16 established. For cooling tubes with low strength, the O-rings 5 be moved in the area of the input-side plate in which the cooling tubes are held. This plate then takes a substantial part of the forces from the clamping of the device in the cooling tube 15 on.

The pipe 17 at the same time forms a piston rod for a in the cylindrical housing 10 slidably arranged piston 20 , The piston 20 in turn has an O-ring that separates the gap between pistons 20 and housing 16 seals.

The housing 16 is at the left end in the view 3 openable or with a lid 4 locked. In addition, the piston protrudes 20 with a pen 11 through the lid 4 therethrough.

The device according to the invention also includes a control block with a switch 13 and an operating lever 2 that hinged to the switch 13 is held and in working condition on the pen 11 supported.

For a cleaning process, the device with the nozzle 9 in the cooling tube 15 pushed until the case 16 to the plate, in which the cooling tube 15 is held on the input side. Subsequently, the operating lever 2 placed in the position shown, opened in a valve, not shown, and pressurized water into the housing 16 flows. The pressurized water fills the housing interior and penetrates the pressurized water through the opening 18 in the tube designed as a piston rod, the pressurized water to the nozzle 9 passes. There, the pressurized water comes out of the nozzle 9 in the cooling tube 15 out. As soon as a pressure builds up, there is a piston movement in the view to the right towards the lid 4 out. The piston rod is moved along and become the O-rings 5 between the sleeves 10 and 19 pressed together. The can deform only due to their arrangement between the sleeves and on the piston rod outside. This causes a spreading of the device and a self-clamping of the device in the cooling tube.

Due to the self-clamping, the device according to the invention no longer has to be held by the cleaning staff during operation. This not only relieves the cleaning staff of the heavy physical work. This is especially true for hard to reach cooling tubes. It also opens up the possibility of parallel operation of multiple devices by a single cleaning person. In addition, you can work with water pressures that were previously uncontrollable when cleaning the cooling tubes. This applies, for example, for pressures greater than or equal to 30 bar. Advantageously, with the inventive Device also water pressures of 100 bar manageable. The potential increase in water pressure is not only of great importance for the purification of deposits which are particularly difficult to remove. With the increase in water pressure and stuck scratches can be moved again.

2 shows the situation when inserting a scratch in a cooling tube 39 that with other cooling tubes in a plate 40 is held.

In the cooling tube 39 a scratch should be introduced, from which a plastic lips 37 and a thorn 38 are shown. The plastic lips 37 are formed by a cross-sectionally W-shaped material whose outer edge is slotted on the circumference several times, so that the edge can fold when the scratch in the cooling tube 39 is pressed. The plastic lips slide 37 on the cooling tube inner wall.

The plastic lips 37 are centered on the thorn 38 riveted. The thorn 38 carries in a manner not shown various metallic tools for cleaning the pipe inner wall of deposits.

In the exemplary embodiment, the scratch by means of a sleeve 34 in the cooling tube 39 pressed. The sleeve 34 has a head 36 , which is adapted to the corresponding end of the scraper and helps in centering the scratch when the scratch in the cooling tube 39 penetrates. The sleeve 34 includes the working end of a pointed chisel 33 , This is a cyanoacrylate adhesive 35 between pointed chisels 33 and sleeve 34 intended. The glue 35 contributes in the exemplary embodiment, the product name locktite and is known as a securing means against the loosening of screws.

The pointed chisel 33 sits with his other end in the tool holder 31 a pneumatic hammer 30 , The tool holder engages with a key, not shown, in a groove 32 of the tool end. The pneumatic hammer 30 pushes the scratch into the cooling tube without significant operator effort. When the scratch is pressed in, the deposits on the tube end in the cooling tube are removed.

The impressions are finished as soon as the barge 41 the sleeve 34 against the end of the cooling tube 39 arrives. In the position is ensured that the 1 described pistol finds there sufficient support for the above-described clamping after insertion into the pipe end.

The pneumatic hammer is in the embodiment, a small hammer of 1.4 kg weight called Yokota BRH 6 , The mounting hole on the hammer for the bit has a standard diameter of 10.2 mm. The tool according to the invention has hammer side the same dimensions as the otherwise provided chisel. That is, like a 10-piece chisel shaft. The sleeve 34 has in the exemplary embodiment an outer diameter of 14 mm and thus smaller than the nominal diameter 15 (Including tolerances occurring), so that the sleeve is suitable for most existing cooling tubes. The collar 41 However, is determined in diameter larger than the nominal size of the cooling tubes, for which the tool

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 69812512 T2 [0006]
• EP 698423A [0006]
• US 2170997 [0006]
• US 2418509 [0006]
• US 2734208 [0006]
• US 4281432 [0006]
• DE 69507221 T2 [0006, 0055]
• US 5153963 [0006]
• SU 1414-482 A [0006]
• US 5305488 [0006]
• DE 69200433 T2 [0006]
• US 1598771 [0006]
• DE 698121511 T2 [0006]
• US 3604041 [0006]

Cited non-patent literature

• DIN 73411 [0016]

Claims (7)

Internal cleaning of heat exchanger tubes, wherein scratches or the like are pressed by means of pressurized water through the heat exchanger tubes and wherein the scratches are first introduced into the heat exchanger tubes and then a nozzle is positioned in the heat exchanger tubes, from which the scratches are acted upon by the pressurized water, characterized in that the Scratch with a pneumatic hammer or a hydraulic hammer or an electric hammer in the cooling tubes is beaten. Cleaning according to claim 1, characterized by the use of tools which are adapted to one end of the bit holder of the hammer and adapted to the other end of the corresponding end of the scraper. Cleaning according to claim 1 or 2, characterized by the use of a tool which is provided at a distance from the scratch-side end with a collar, wherein the distance is at least equal to the minimum dimension for the insertion of the scratches. Cleaning according to one of claims 1 to 3, characterized by the use of a hammer with a receptacle for a 10 mm tool shank and with a collar diameter which is greater than the nominal size of the largest cooling tube, for which the tool is intended. Cleaning according to one of claims 1 to 4, characterized by the use of a commercial chisel, the scratch side is surrounded by a sleeve or sitting in the blind hole of a rod. Cleaning according to claim 5, characterized by a bonding of the bit with the sleeve or the rod. Cleaning according to claim 4 or 5, characterized by using a sleeve or rod with an outer diameter which is smaller than the nominal diameter 15 mm of a cooling tube.

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