DE102016001165B4 - Device for providing thermal and electrical energy for paint shops - Google Patents

Abstract

Device for providing thermal and electrical energy for paint shops, with a block-type thermal power station (2) which, with the interposition of a buffer store (7), has a first line (10) as flow and a second line (11) as return with at least one cabin (12 ) is connected for painting/drying, characterized in that a third line (17) is provided, which is connected between the first and the second line (10, 11), the third line (17) being used both as a flow from the buffer store (7 ) to the at least one cabin (12) and also as a return from the at least one cabin (12) to the buffer store (7).

Description

The invention relates to a device for providing thermal and electrical energy for paint shops according to the preamble of patent claim 1.

Such a device is known from practice. The thermal and electrical energy is obtained via a combined heat and power plant. This is preferably operated at the place where the thermal energy is consumed. Such a combined heat and power plant is based on the principle of combined heat and power generation.

Such a combined heat and power plant usually has an internal combustion engine, preferably a gas-powered Otto engine, as the drive for the generator required to generate the electrical energy. Liquid gas, for example LPG (liquefied propane gas) or natural gas can be used as the gas.

The higher overall efficiency of such a combined heat and power plant results from the fact that the heat (waste heat) generated during power generation can be used directly at the point of origin and can therefore be used in an energetically sensible way. The electrical energy generated with such a combined heat and power unit can be used immediately in the paint shop in question, and can also be fed into the general power grid in the event of overproduction. The generated thermal energy can be used for heating and hot water preparation.

In general, when only one combined heat and power plant is used, either its power output is regulated according to the requirements, or a heat accumulator is used that is charged in interval operation.

It is known to design the output of such a combined heat and power plant in such a way that it covers only part of the maximum thermal energy requirement of the connected consumer in full-load operation, with the required residual heat then being made available with the aid of an additional heat generator. It is also known in the case of devices with buffer storage to operate such a combined heat and power plant with an additional heat generator. In the latter case, there is nevertheless frequent switching on and off of the combined heat and power plant, namely so-called clocking, which impairs the service life of the combined heat and power plant and has negative effects on the overall efficiency.

A high overall efficiency can therefore generally only be achieved with a cogeneration plant if it runs with a high annual number of operating hours in the high load range of the combustion engine. However, this is not possible with return temperatures above 70°C, so that the combined heat and power plant, also abbreviated to CHP in the following, switches off automatically in such cases. This is the reason why a CHP is usually very small compared to the size of the plant. A CHP with a higher output would have an even higher cycle frequency, which, as previously mentioned, has a negative effect on efficiency and service life. Especially during the summer, CHP operation without an additional heat generator is therefore hardly possible, since the return temperature reaches the above-mentioned upper temperature limit of about 70°C even faster, which leads to the CHP plant being switched off automatically.

It is also known from practice to use such a CHP for paint shops, however, with the shortcomings described above.

The pamphlet DE 10 2014 206 474 A1 describes a system for providing heat energy for heat consumers in the form of a so-called combined heat and power unit, with an internal combustion engine, which has an output unit, in particular an output shaft, for providing mechanical energy, and an exhaust gas unit for providing heat energy at a first temperature level having an exhaust flow.

From the DE 29 46 074 A1 is a 3-stage energy production and use system known in which a solar energy supply, directly through suitable collectors and the chem. Energy supply, for example fossil fuels such as coal, oil, gas, but also biogas (solar energy stored indirectly), hydrogen, etc., is converted (produced) into 3 energy levels and used accordingly. A connecting line between high and low temperature is provided, which allows a possible surplus from the 2nd to the 3rd stage. should bring.

The object of the invention is to operate a device of the type mentioned at the outset economically.

This object is achieved according to the invention with a generic device having the characterizing features of patent claim 1 . Advantageous developments are the subject of the dependent claims.

According to the invention, a third line is provided, which runs between the first, as flow formed line and the second, designed as a return line is connected, wherein the third line can be used both as a flow from the buffer storage to at least one cabin and as a return from the at least one cabin to the buffer storage. This makes it possible to also use the residual heat present in the third line in order to bring the temperature in the return as far below 65°C as possible. On the one hand, this results in the possibility of running the painting operation in the summer without an additional heat generator, which also results in a longer running time of the combined heat and power plant and a significantly reduced or completely eliminated cycle operation. This results in a higher overall efficiency and a longer service life or lower repair costs for the CHP used. Furthermore, the CHP can be optimally used in comparison to the size of the system and can be dimensioned larger than a CHP according to the prior art, which further improves the overall efficiency. Furthermore, it may also be possible to operate the paint shop with only one CHP and not with the help of modular systems.

Ultimately, a feed with a relatively high temperature is available using the first line and a feed with a lower temperature is available using the third line. Such a third line can be used particularly advantageously when--as in paint shops--a higher temperature is required for drying than for painting.

According to a preferred development of the invention, in the case of several cabins with different heat requirements, the third line is designed on the one hand as a return from the cabin with a higher heat requirement and on the other hand as a flow to the cabin with a lower heat requirement. As already indicated above, the thermal energy still present in the return from the cabin with a higher heat requirement can then be used particularly preferably as a flow to the cabin with a lower heat requirement, which has a particularly advantageous effect on the overall efficiency and the operation of the device according to the invention with the lowest possible clock frequency .

According to another development of the invention, the temperature level of the heat carrier, e.g. the water, in the first line is higher than that in the second line and the temperature level in the third line is between that in the first line and that in the second line, with preferably the temperature level in the first line is about 90 to 92°C, the temperature level in the second line is about 35 to 60°C and the temperature level in the third line is about 65 to 80°C. This makes it possible to fall below the critical upper temperature limit of 70° C. on the return to the buffer storage tank as far as possible, so that the CHP used in the device according to the invention is switched off as little as possible and can therefore be used permanently.

According to a preferred development, the first line is connected to the CHP and to the head of the buffer storage and from the head to the at least one cabin, the third line is connected on the one hand preferably via 3-way valves between the first and the second line to the at least connected to a cabin and on the other hand to the buffer storage below its head, the second line being connected on the one hand preferably via 3-way valves to the at least one cabin and on the other hand to the buffer storage below the third line. This allows a particularly pronounced temperature stratification to be implemented in the buffer storage tank, since the temperature of the medium transporting the heat, e.g. B. the water, in the buffer tank from the bottom to the top increases. The lower the temperature of the water, the further down the water can be stratified in the buffer tank. The higher the temperature of the water, the further up the water can be stratified in the buffer tank. With good insulation of the buffer storage, the heat loss can be advantageously reduced to values between 0.2 and 0.5°C/hour. As a result, the temperature gradient of the water in the buffer tank can be largely maintained.

According to another development, a thermal separating plate is arranged in the buffer store between the head of the buffer store and the connection of the third line. This thermal separating plate serves as an insulator between the warmer layers arranged above the separating plate and the cooler layers arranged below the separating plate. In addition, the separating plate slows down turbulence when the return flow is introduced into the buffer storage tank and thus reduces back-mixing of the water in the buffer storage tank. This development also serves to operate the device according to the invention even more economically.

According to a preferred development, the buffer storage has several connections distributed over its height in such a way that the return from the second and third line can be fed into the buffer storage according to its respective temperature level and the return to the combined heat and power plant or the flow to at least one cabin according to the required temperature level can be withdrawn from the buffer memory. This development in turn promotes the previously mentioned stratification or stratification of the what sers in the or the buffer storage according to the respective temperature level. The return of the water takes place in the buffer tank at the point where the water in the buffer tank is at about the same temperature as in the return. Conversely, the flow can also be withdrawn from the buffer tank at the appropriate point, ie with the required temperature level.

• 1 eine schematische Darstellung einer Vorrichtung zum Bereitstellen von thermischer und elektrischer Energie für Lackierbetriebe.

Exemplary embodiments of the subject of the invention are explained in more detail below with reference to the drawing, with all of the described and/or illustrated features forming the subject of the present invention alone or in any combination, regardless of their summary in the claims or their dependency. It shows:

• 1 a schematic representation of a device for providing thermal and electrical energy for paint shops.

In 1 a device 1 for providing energy, in particular thermal and electrical energy, for paint shops is shown schematically in the form of a flow chart.

The device 1 has a combined heat and power plant 2, also abbreviated CHP, with an internal combustion engine 3, which drives a generator 4. The generator 4 is connected to a power grid 5, into which it feeds the generated electrical energy. The electrical energy generated can be used by the paint shop itself or fed into a public power grid.

The waste heat from the internal combustion engine 3, that is to say the waste heat generated during the generation of electricity by means of the internal combustion engine 3, is available to the paint shop in the form of thermal energy. According to the exemplary embodiment shown, water 6 is used as the source of thermal energy, which water is heated by the waste heat from internal combustion engine 3 in CHP 2 . Other heat carriers such as heat transfer oils can also be used.

The combined heat and power plant 2 is connected to at least one booth 12 for painting/drying via a first line 10 as a flow and a second line 11 as a return with the interposition of a buffer memory 7 . According to the 1 shown embodiment, three cabins are provided, namely a cabin 13 for drying, a cabin 14 for painting and a cabin 15, which is designed as a multi-workstation. For the sake of clarity, the first line 10 from the head 16 of the buffer memory 7 to close to the cabins 13 to 15 is shown in dashed lines and the second line 11 from the buffer memory 7 to close to the cabins 13 to 15 is shown as a dotted line.

Furthermore, a third line 17 is provided, which is connected between the first line 10 and the second line 11 and in 1 is shown in dotted lines. The third line 17 is connected or can be connected to the buffer store 7 on the one hand and to each of the cabins 12 on the other hand, as will be explained in more detail below.

It is pointed out that the painting booth 14 can also be designed as a so-called painting line, in which a workpiece to be painted passes through successive stations. Such flow can be continuous or batchwise or discontinuous. Likewise, the cabin 13 for drying can also be designed as a road.

The third line 17 can be used both as a flow from the buffer storage 7 to the at least one cabin 12 and as a return from the at least one cabin 12 to the buffer storage 7 . this is in 1 symbolized by the double arrow A assigned to the third line 17 .

In the case of several cabins with different heat requirements, in the exemplary embodiment shown these are cabin 13 for drying and cabin 14 for painting, the third line 17 is on the one hand as a return from cabin 13 with a higher heat requirement and on the other hand as a flow to cabin 14 for Paintwork trained with lower heat demand.

In general, the temperature level of the first line 10 is higher than that of the second line 11, the temperature level of the third line 17 being between that of the first line 10 and that of the second line 11. For example, the temperature level of the first line 10 is approximately 90 to 92°C, the temperature level of the second line 11 is approximately 35 to 60°C and the temperature level of the third line 17 is approximately 65 to 80°C. These values apply, for example, in cases when a temperature of approximately 70° C. is to prevail in the booth 13 for drying and a temperature of between 35 and 40° C. is to prevail in the booth 14 for painting.

According to the 1 In the embodiment shown, the first line 10 is connected to the CHP 2 and to the head 16 of the buffer storage 7 and from the head 16 of the buffer storage 7 to the at least one cabin 12 . In the embodiment shown, the line 10 from the head 16 of the buffer storage 7 is connected to all the cabins 13-15. For this purpose, a connecting line 20 is connected on the one hand to the CHP 2 and on the other hand to the head 16 of the buffer store 7 . Apart from losses, the water in the connecting line 20 has the same temperature level as in the first line 10, which runs from the head 16 to the individual cabins 13 to 15 in the exemplary embodiment shown.

The third line 17 is connected on the one hand, preferably via 3-way valves 21, 22 between the first line 10 and the second line 11, to the at least one cabin 12 and on the other hand to the buffer store 7 below its head 16. The 3-way valves 21 are each arranged in the return of the cabins 13 to 15, the 3-way valves 22 in the flow to the cabins 14 and 15. The 3-way valves 21 and 22 are connected to each other on the cabins 14 and 15 via short lines 23 .

According to 1 the second line 11 is connected on the one hand, preferably via the 3-way valves 21, to the at least one cabin 12 and on the other hand to the buffer store 7 below the third line 17. According to the exemplary embodiment shown, the second line 11 is connected to each of the cabins 13 to 15 via the 3-way valves 21 for the return flow.

The heat transfer medium, for example the water, is conveyed to the cabin 13 to 15 in question by means of pumps 24 arranged in the flow. Each cabin 13 to 15 is therefore assigned its own pump 24 . As also in 1 shown, sits a motor / line regulating valve (shutoff valve) or mixer valve 25 in the respective line between the cabin 13 to 15 and the 3-way valve 21 for the return.

According to a particularly preferred embodiment of the invention, as in 1 shown, a thermal separation plate 26 is arranged in the buffer memory 7 between the head 16 of the buffer memory 7 and the connection 27 of the third line 17 . This separating plate serves as a thermal insulator between warmer layers of water located above the separating plate and cooler layers of water located below the separating plate. This separating plate 26 extends largely but not completely over the cross section of the buffer storage tank 7, so that the water flows over an annular section 30 between the outer edge of the thermal separating plate 26 and the inner wall 31 of the buffer storage tank 7 from the section of the buffer storage tank 7 arranged above the separating plate 26 can flow into the section of the buffer tank arranged below the partition plate 26 and vice versa, should this be necessary or desired.

The buffer tank 7 has several connections 27, 33 to 35 distributed over its height 32 in such a way that the return from the second and third line 11, 17 can be fed into the buffer tank 7 according to its respective temperature level and the return to the combined heat and power plant 2 or Lead to at least one cabin 12 can be deducted from the buffer storage 7 according to the required temperature level. Since the temperature level of the water at connection 27 of the third line on the buffer tank is lower than the temperature level of the water in the connecting line 20 or the first line 10 at the head 16 of the buffer tank, but higher than the temperature level of the water at connection 33 for the return through the second line 11, the connection 27 is located on the one hand below the head and on the other hand above the connection 33 for the second line 11.

In the exemplary embodiment shown, only one connection 33 is provided for the return flow of the second line to the buffer memory. It is pointed out that several connections can be provided, so that the return can be introduced through the second line 11 into the buffer storage tank according to its temperature level in such a way that the temperature of the water introduced corresponds approximately to the temperature level of the water in the buffer storage tank at the level of the relevant connection . Analogous statements also apply to connection 27 of the third line to the buffer store. Here, too, several connections can be provided so that the water at the required temperature can be withdrawn from the buffer storage 7 as a flow to one of the cabins or fed into the buffer storage as a return at a height such that the temperature of the water fed in corresponds to the temperature of the in turn corresponds to the water present in the buffer tank at the level of the relevant connection.

As shown, several connections 34, 35 are provided for the return of the water from the buffer storage 7 to the CHP 2, so that the temperature of the water conveyed to the CHP can be varied within wide limits and the water can be drawn off from the buffer storage accordingly. It is pointed out that the line 36 between the buffer storage 7 and the CHP 2 can also be connected to the buffer storage via only one connection or via more than two connections.

It is clear that, in particular, numerous other control, regulation or delivery devices can be provided on the CHP 2, which are not explained in more detail here.

Preferably, the temperature between the head and the separating plate 26 in the buffer tank is about 90 to 92°C, the temperature at the level of the connection 27 of the third pipe 17 is about 70 to 80°C, the temperature of the water in the buffer tank cher at the level of the connection 34 about 60 ° C and the temperature of the water in the buffer storage at the level of the connection 35 and thus close to the bottom 37 of the buffer storage 7 about 40 to 50 ° C. It is therefore clear that, for energy reasons alone, the water should preferably be taken from the buffer storage at the required temperature level or, conversely, should be fed into the buffer storage at the point at which the corresponding temperature of the water in the buffer storage is present. This procedure has the advantage that the temperature gradient of the water from the top 16 to the bottom 37 of the buffer store is largely retained.

Below is the flow chart according to 1 , which relates to the different wiring of the lines with the cabins 13 to 15, explained in more detail.

Water 6 with a temperature between about 40 and about 60° C. is usually routed via the connections 34 , 35 and the line 36 to the CHP 2 , heated there and conveyed via the connecting line 20 to the top 16 of the buffer storage 7 . A further pump 40 can be provided for this purpose. From the head 16 of the buffer tank 7, the water passes through the line 10 to one of the cabins 13 to 15, for example initially by means of the pump 24 to the cabin 13 for drying. For example, the water reaches the cabin 13 at a temperature between 90 and 92°C. There the water releases its temperature for heating the dryer and then reaches the 3-way valve 21 at a temperature between 65 and 80°C. This temperature level can be used in the booth 14 for painting, in which a temperature between 35 and 40°C is required, by directing the water from the 3-way valve 21 via the third line 17 to the short line 23 and via the 3-way valve 22 and pump 24 to cabin 14. In the return flow from the cabin 14, the water still has a temperature between 35 and 60°C and then reaches the buffer tank 7 via the 3-way valve 21 of the cabin 14 and the second line 11 and by means of the connection 33.

If a high heat requirement is required in the cabin 13, for example during the heating-up phase, the water in the return flow from the cabin 13 can also have a temperature between approximately 35 and 60°C. In this case, the water from the return of the cabin 13 via the 3-way valve 21 would not be directed into the third line 17 but into the second line 11 and again via the connection 33 into the buffer storage.

If the temperature of the water in the return from the cabin 14 still has a temperature level that can be used in subsequent cabins, the return from the cabin 14 via the 3-way valve 21 is not in the second line 11 but in the third line 17, about which it is in 1 to the right towards booth 15. The water can then enter the cabin 15 via the 3-way valve 22 and the pump 24 via the short line 23 between the 3-way valves 21 and 22 of the cabin 15 . The water in the return flow from the cabin 15 then reaches the 3-way valve 21 and via the second line 11 and the connection 33 into the buffer tank.

It is also possible, if desired, to fill the cabins 14 and 15 directly with the water from the first line 10, that is to say with water which is at a temperature of approximately between 90 and 92°C.

If, on the other hand, the water leaves the cabin 14 at a temperature below 60 °C, it is immediately fed into the buffer tank via the 3-way valve 21 and the connection 33 .

For example, if only one cabin is to be operated, the water can be routed via the first line 10 to this cabin as a feed and from this cabin as a return through the third line 17 via the connection 27 back to the buffer storage tank 7 . It is also possible to withdraw the water from the buffer tank via the connection 27 and the third line 17 at a temperature level between about 65 and 80°C and to pump it as a flow via the 3-way valve 22 to the cabin in question and that To lead water in the return from the cabin in question via the 3-way valve 21, the second line 11 and the connection 33 back to the buffer tank.

According to the invention, an additional third line is therefore provided between the individual cabins or the at least one cabin and the buffer store. For the drying process in the cabin 13, water with a temperature of about 90 to 92° C. is usually required in the flow. The temperature of the water in the third line for supplying the booths for painting or as a high-temperature return from the drying process is around 65 to 80°C. The temperature in the return, that is to say in the second line 11, is approximately 35 to 60° C. as the low-temperature return from the drying booth heating or as the return from the booth 14 for painting.

The control behavior in the cabin 13 for drying can thus be described in such a way that the temperature of the water in the first line 10 is approximately 90 to 92°C. If the water return has a temperature above 65°C, the water is pumped through the 3-way valve into the third line 17. If the temperature of the water in the return is less than 65° C., for example while the chamber 13 is being heated, the water is immediately pumped into the second line 11 through the 3-way valve.

The control behavior in the case of using the booth 14 for painting or the booth 15 designed as a multi-workstation, in the latter booth a painting process as well as a drying process is possible in the same booth, takes place in such a way that during the drying operation in the booth 15 the control behavior corresponds to that of cabin 13. During the painting process in the booth 15, the flow of this booth switches from the first line 10 to the third line 17, since the temperature level of this line is sufficient for the painting process. This ensures that this temperature level is also used in an energy-efficient manner, since it is otherwise too cool for the drying process but too high for the motor cooling of the combined heat and power plant. The return flow from this process then arrives via the second line 11 back to the buffer store.

In the buffer tank itself, the water should be mixed as little as possible. By selectively activating the individual valves provided on the cabins or on the buffer tank, the water can be stratified in an energy-efficient manner at the various temperature levels according to the requirement. The lower the temperature, the lower the water is stratified in the buffer tank, the higher the temperature , the further up the water is stratified in the buffer tank.

In the case of a drying process carried out in the cabin 15, there could therefore be a return temperature of 55 to 60 °C during the winter, so that the water would be fed into the second line 11 in this case, while with such a process in the summer the return temperature would be 65 to 60 °C would be 70°C, so that the water would be fed into the third line 17 at such a temperature.

Preferably, the internal combustion engine 3 of the CHP 2 is a gas-powered engine.

It is therefore possible by means of the invention to increase the running time of the block-type thermal power station, ie to reduce clocking as completely as possible. This is possible due to the lower internal combustion engine cooling temperatures that are present in the cooling water. The cabins mentioned can be operated without additional heat generators, since a high temperature level can be guaranteed by the specific activation of the respective cabin by means of the first line 10 . Due to the technical separation of drying and painting, the specific stratification of the water in the buffer storage and the high total buffer volume in the buffer storage, a constantly cool water with a temperature between 50 and 60°C is made possible for cooling the combustion engine of the CHP even in the summer months. The total buffer volume of the buffer store is preferably more than 5000 liters, particularly preferably at least 10,000 liters.

It is thus possible according to the invention to use a more powerful CHP, so that it can be possible to reduce the operating costs of the paint shop by 40 to 60% through optimal integration and regulation.

The electrical output of the combined heat and power plant 2 can be 1 device 1 shown is 33 kW/hour, the thermal output is 70 kW/hour. If only one cabin 15 is used as a multi-workstation, the electrical output of the combined heat and power plant can be 7.5 kW/hour and the thermal output can be 23 kW/hour.

This creates a device for providing energy for paint shops, which works very economically.

Claims (7)

Device for providing thermal and electrical energy for paint shops, with a block-type thermal power station (2) which, with the interposition of a buffer store (7), has a first line (10) as flow and a second line (11) as return with at least one cabin (12 ) is connected for painting/drying, characterized in that a third line (17) is provided, which is connected between the first and the second line (10, 11), the third line (17) both as a flow from the buffer store ( 7) to the at least one cabin (12) and also as a return from the at least one cabin (12) to the buffer store (7). device after claim 1 , characterized in that in the case of several cabins (13 to 15) with different heat requirements, the third line (17) is designed on the one hand as a return from the cabin (13) with a higher heat requirement and on the other hand as a flow to the cabin (14) with a lower heat requirement . Device according to one of Claims 1 until 2 , characterized in that the temperature level of the first line (10) is higher than that of the second line (11) and the temperature level of the third line (17) is between that of the first line (10) and that of the second line (11). device after claim 3 , characterized in that the temperature level of the first line (10) is about 90 to 92°C, the temperature level of the second line (11) is about 35 to 60°C and the temperature level of the third line (17) is about 65 to 80°C . Device according to one of the preceding claims, characterized in that the first line (10) is connected to the combined heat and power plant (2) and to the head (16) of the buffer store (7) and from the head (16) to the at least one cabin (12). the third line (17) is connected on the one hand, preferably via 3-way valves (21, 22) between the first and the second line (10, 11), to the at least one cabin (12) and on the other hand to the buffer store (7 ) below its head (16) and the second line (11) on the one hand preferably via 3-way valves (21) to the at least one cabin (12) and on the other hand to the buffer storage (7) below the third line (17) connected. device after claim 5 , characterized in that in the buffer store (7) a thermal separating plate (26) is arranged between the head (16) of the buffer store (7) and the connection (27) of the third line (17). Device according to one of the preceding claims, characterized in that the buffer store (7) has a plurality of connections (27, 33 to 35) distributed over its height (32) in such a way that the return flow from the second and third line (11, 17), can be introduced into the buffer storage (7) according to its respective temperature level and the return to the combined heat and power plant (2) or the flow to at least one cabin (12) can be drawn off from the buffer storage (7) according to the required temperature level.

Images