DE102014000177A1 - Movable device for the use of energy loss for heating purposes - Google Patents

Abstract

The invention relates to a movable heating device which is suitable to use the energy loss of ovens and process lines to the goods and materials to be processed before entering a downstream oven or other technical device by convection and heat radiation without the additional use of preheat electrical energy or fuel and thereby reduce the energy consumption of the downstream system. The device is designed so that you can move from the work area to a stand-by or maintenance position, without having to be removed or cut through the material to be heated. The use of a heat accumulator compensates for discontinuous loss energy flows or demand peaks.

Description

The invention relates to a movable heating device, which uses the heat loss of a furnace, an incinerator, an exhaust air purification system or more of these devices or their combination to preheat the goods to be processed before entering a downstream process device and thereby their energy consumption to a considerable extent reduce or increase production output

State of the art

Mobile heaters for preheating goods or workpieces are known. The patent application AZ 10 2013 003 251.2 describes a heater that uses exhaust energy of a downstream furnace as the main energy source. As a result, large amounts of energy can be saved.

The compensation of fluctuating energy supply or discontinuous demand is not described in the patent application. Likewise, it is not described that the heater can be moved out collision-free, if there are continuous bands, profiles, pipes or conveyors in the system.

problem

The known movable heating systems for preheating goods or workpieces can only be moved out of the system if continuous bands, profiles or pipes have previously been removed from the device. For endless ribbons or other goods, they have to be cut and later put back together. Continuous conveyor systems must be dismantled. This means a lot of effort, which puts an economic operation of the heater in question.

The energy level of the exhaust gases of one or more downstream furnaces ( 5 ) or downstream process equipment and the resulting heat outputs are in many system configurations not sufficient for the realization of an effective and thus economic preheating of the material to be heated ( 3 ) or the workpieces by a movable heating device ( 1 ). According to the known state of the art, this basically meaningful preheating can therefore not be realized economically in many cases. The technical effort is too large compared to the energy benefits.

Another problem arises from the fact that downstream electrically heated ovens or thermal processes do not give off any burner exhaust air. Known preheating tunnel according to patent application AZ 10 2013 003 251.2 are therefore not suitable for use in combination with electrically heated equipment.

When using the loss energy ( 8th ) in particular from non-downstream furnaces ( 6 ) or facilities, there is the problem that the loss energy supply and the energy requirement of the movable heating device ( 1 ) are not always in sync with each other. Therefore, the system can not be optimally designed for all applications. With reduced production capacity of the energy-supplying plant, their burner output and thus also the resulting exhaust gas output are reduced. This reduces the recoverable heat output of the energy-using device ( 1 ) The reduced power must be compensated in this case by additional fuel-powered or electric heating means. Otherwise, the production output of the energy-using device is reduced.

In particular, metallic materials are fed to the surface treatment of different dipping, spraying or application processes. For many of these surface processes, material heating is required. This heating takes place either by upstream fuel-operated or electric heating devices or by heat transfer from the previously heated process fluid ( 12 ) on the material or workpieces. The required for the heating of the liquid and the material power or fuel consumption is significant.

The surface effect of dipping, spraying or application processes is often effective only when the material to be treated has reached a sufficient temperature. The heating takes place by heat transfer from the process fluid ( 12 ) on the material to be processed. A significant area ( 14 ) of the dipping, spraying or application application is therefore essentially necessary for the heating. Here the surface effect is not optimally effective. Only in the area ( 13 ), in which the material has already reached a sufficient temperature, the optimum effectiveness is achieved.

task

The present invention has for its object to design a heater that can be moved out of the system without previously to remove the material to be heated from the work area to dismantle the conveyor system or divide endless materials.

The present invention is further based on the object of designing a movable heating device so that it can be usefully used if the downstream ovens ( 5 ) or the downstream plants have no usable and sufficient energy loss potentials and energy levels for the supply of a heating device ( 1 ) exhibit.

A further object is to achieve a uniform utilization of the lost energy by the movable heating device ( 1 ) to enable even with fluctuating energy loss level or not constant energy demand.

Another object is to realize heating of predominantly metallic materials or workpieces prior to entering into dipping, spraying, or deposition processes using existing waste energy resources to reduce or increase the electrical energy expenditure or the combustion energy expenditure for the process replace. In addition, the effective surface effect is already on entry into the process to improve and the effective range ( 13 ) to enlarge it.

The continuous supply of continuous materials for dipping, spraying or application processes is often in overrun. In the event of a fault, this leads to a material jam with consequent material deformation and distortion ( 16 ) Therefore, another object is to heat the heater ( 15 ) so that access to the jammed and discarded material for disposal and reinsertion is easily possible.

solution

These objects are achieved by the features recited in claims 1 and by the features set forth in the dependent claims. Advantages, developments and preferred embodiments are described in further dependent claims.

In claim 1 it is stated that the device can be moved out of the system, without having to disassemble the conveyor system and without that the material to be heated must be removed or severed. According to claim 10, the device for this purpose has at least one folding device ( 18 ) ( 21 ) ( 24 ) or a slider ( 26 ) or another device which can release one or more openings for collision-free movement out of the heating device.

A suitable embodiment is a side folding device ( 24 ) or a folding device ( 18 ) ( 21 ) on the bottom. The good to be heated ( 19 ) ( 23 ) remains even when the heater has been moved out ( 17 ) ( 25 ) at the original position ( 20 ) ( 22 ).

Alternatively, in claim 10, a symmetrical or asymmetrical divisible design of the heater ( 27 ) ( 28 ) ( 29 ). In this variant, the two individual components can be driven individually out of the area after division.

In the event that the heating energy ( 2 ) of the downstream furnace ( 5 ) or the downstream ovens is not sufficiently available, the device according to claim 2 is designed so that the energy loss ( 8th ) of a non-downstream furnace or multiple non-downstream furnaces or one or more non-downstream thermal processing equipment serves as its main energy resource. The energy loss is preferably in the form of burner exhaust or kiln exhaust or recooling energy or as a combination thereof.

In the opposite case, claim 3 refers to a downstream main energy resource.

In order to still allow the most continuous heating process at fluctuating energy loss level of the device supplying energy loss, a heat storage or heat buffer is used according to claim 4. For this purpose, according to claim 9 are particularly memory of ceramic materials or latent heat storage, using the converted at the phase transition of the storage medium energy potential.

Achieved benefits

The features listed in the claims, it is possible to drive out the loss of energy-driven heaters collision-free from the plant, without having to do elaborate and therefore costly work.

Furthermore, it is possible to effectively operate loss-driven movable heating devices even in cases where the loss energy of downstream ovens or devices is not sufficient. This also applies to downstream electrically operated stoves.

In the reverse case, the use of the energy loss of downstream ovens and facilities is possible.

The use of a heat accumulator compensates for discontinuous loss energy flows or demand peaks. Thus, it is also possible, the asynchronous energy attack and to compensate for the energy requirements of independent installations.

Further embodiment

The energy and cost-saving preheating of the workpieces prior to entry into immersion, spraying or application processes is realized by the properties set out in claim 5. As special cases, the applications for pickling and bonder systems are set forth in claims 6 and 7.

The important access for this application to jammed and deformed material ( 16 ) can be easily realized, since the heating device according to claim 1 and claim 10 from the area of material jam in another a position ( 15 ) can be moved.

By enlarging the effective area ( 13 ) offers the possibility for a given process time to increase the conveying speed and thus the production output

The heating power of the movable preheater ( 1 ) respectively. ( 11 ) can be increased by fuel or electrically operated heating means according to claim 8. These heating means can also be used for the use of subsidized energy supply.

List of Related Drawings:

Drawing 1

Drawing 2

Drawing 3

Drawing 4

LIST OF REFERENCE NUMBERS

1

heater

2

Energy loss from the downstream oven by heater

3

Good to be heated for the heater and the downstream oven

4

Warmed good behind oven

5

Downstream furnace / downstream ovens

6

Non-downstream oven / non-downstream ovens

7

Good to be heated for the non-downstream oven

8th

Loss energy from the non-downstream oven for use by the heater

9

Conveying direction for the material to be heated

10

Loss energy flow from the non-downstream oven for use by the heater

11

heater

12

process liquid

13

Area for the surface effect fully effective

14

Area primarily effective for material heating

15

Heating device - moved out of the system

16

Material accumulation with consequent material deformation

17

Heating device, moved upwards in standby position

18

Folding device at the bottom, open

19

Good to be heated remains below the heater

20

Good to be heated within the heater in heating position

21

Folding device at the bottom, shown closed.

22

Good to be heated within the heater in heating position

23

Good to be heated remains next to the driven to the side heater

24

Folding device laterally, open

25

Heating device, laterally moved away in standby position

26

Sliding device, shown open

27

Symmetrically divided heater, left and right part

28

Asymmetrically split heater, left and right parts

29

Asymmetrically split heater, upper and lower part

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

• AZ 102013003251 [0002, 0006]

Claims (10)

Heating device characterized in that it is arranged individually or in combination with other heating devices during heating in the vicinity of a furnace or a dryer or a process device and the material to be heated after leaving the heater delayed or not delayed in this oven or dryer or the process device arrives. and characterized in that the energy is transferred to the material to be heated substantially by convection or by heat radiation or by a combination of convection and thermal radiation. and characterized in that the loss energy of another device or devices preferably serves as its main energy resource in the form of combustion exhaust gases or furnace exhaust gas or recooling energy, and characterized in that the heater is moved out or out of the heating position into at least one other, outside the heating position located position is possible without that parts of the conveyor system for the material to be heated must be dismantled and without the material to be heated must be removed or cut. Heating device according to claim 1, characterized in that the loss energy of a non-downstream device or more non-downstream devices preferably in the form of combustion exhaust gases or furnace exhaust gases or recooling energy serves as their main energy resource. Heating device according to claim 1, characterized in that the energy loss of a downstream device or more downstream devices preferably in the form of combustion exhaust gases or furnace exhaust gases or recooling energy serves as their main energy resource. Heating device according to claim 2 or 3, characterized in that the energy used for heating is supplied before use in the heating device completely or partially to a heat storage device. Heating device according to claim 2 or 3, characterized in that the heating device is arranged in the vicinity of a dipping, spraying or application process in order to preheat the material or the workpieces before entering the process. Heating device according to claim 5, characterized in that the heating device is arranged in the vicinity of a Bonderprozesses to preheat the bonder before entering the Bonderapplikation. Heating device according to claim 5, characterized in that the heating device is arranged in the vicinity of a pickling process in order to preheat the pickled material before entering the pickling. Heating device according to claim 2 or 3, characterized in that it is equipped with at least one electrically or fuel-powered heating device, which serves as an additional or temporarily as an exclusive source of heat when needed. Heating device according to claim 4, characterized in that the heat storage device consists essentially of ceramic material or is designed as a latent heat storage. Heating device according to claim 2 or 3, characterized in that it is designed symmetrically or asymmetrically divisible or at least one folding device or at least one sliding device or at least one folding device or a combination of these variants has with the help of the consequent opening or openings a collision-free retraction to allow the heating devices.

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