EP2326905A2 - Tubular heat exchanger for controlling a wide performance range - Google Patents

Abstract

The invention relates to a tubular heat exchanger comprising heating surface pipes (2), the ends of which are held in pipe plates (3, 4), and a pressure shell (6) surrounding the heating surface pipes (2) and forming a shell space (5), wherein a cooling medium flow (8) for cooling a first medium flow (7) conducted through the heating surface pipes (2) can be conducted through the shell space (5), further comprising at least one pipe inlet chamber (9) from which the first medium flow (7) is introduced into the individual heating surface pipes (2), and at least one pipe outlet chamber (10) in which the first medium flow (7) conducted through the heating surface pipes (2) is collected and removed, further comprising two connectors (11, 12) for the inflow and outflow of the cooling medium flow (8) which are disposed at the rear end (15) of the pressure shell (6) adjoining the pipe outlet chamber (10), comprising two connectors (13, 14) for the inflow and outflow of the cooling medium flow (8) which are disposed at the front end (16) of the pressure shell (6) adjoining the pipe inlet chamber (9), further comprising a feed line (17) and a first three-way valve (19) which is disposed thereon and from which a first bypass line (21a) is connected to the first connector (11) at the rear end (15) of the pressure shell (6) and a second bypass line (21b) is connected to the first connector (13) at the front end (16) of the pressure shell (6), and comprising a discharge line (18) and a second three-way valve (20) which is disposed thereon and from which a third bypass line (22a) is connected to the second connector (14) at the front end (16) of the pressure shell (6) and a fourth bypass line (22b) is connected to the second connector (12) at the rear end (15) of the pressure shell (6), wherein one of the two three-way valves (19, 20) is designed so it can be controlled and it conducts the cooling medium flow m0 (8) through the shell space (5), or as controlled partial mass flows m1, m2 of the cooling medium flow m0 (8) through the shell space (5) and through the bypass line(s) (21a, 21b, 22a, 22b) and wherein by means of the further three-way valve (19, 20) the cooling medium flow (8) can be conducted through the shell space (5) in a co-current flow or reverse flow with respect to the first medium flow (7).

Description

 description

Tube bundle heat exchanger for controlling a wide power range

The invention relates to a shell and tube heat exchanger for controlling a wide power range.

For the cooling of medium streams, especially gases in numerous process engineering systems, such. B. gasification plants, thermal and catalytic cracking systems, steam reforming plants, etc., are usually heat exchangers, in particular shell and tube heat exchanger (cooler), used in which flow to be cooled medium flows through straight Heizflächenrohre and thereby the existing heat of the hot medium flow through the pipe wall deliver to the cooling medium surrounding the tubes.

The main object of such a heat exchanger or shell-and-tube heat exchanger, as stated above, is the transfer of heat between two media, wherein one medium (hot medium) dissipates a certain amount of heat and the other medium (cooling medium) is supplied with an adequate amount of heat. The amount of heat transferred is known to depend on the size of the heat exchanger, the heat transfer coefficients of the two media, and the temperature difference between the two media. With single-phase media, the medium temperature changes with the heat supply or heat dissipation. The temperature profile over the length of the apparatus of the heat exchanger is in this case similar to an exponential function.

A shell-and-tube heat exchanger generally comprises a large number of heating surface tubes, a pressure jacket surrounding the heating surface tubes and forming a jacket space, and two tube plates, between which the heating surface tubes are arranged. The one medium flows through the tube inlet chamber of the heat exchanger, then through the Heizflächenrohre and the tube outlet chamber of the heat exchanger. The second medium flows through a nozzle into the shell space of the Heat exchanger, flows around the individual heating surfaces several times tube and then flows through a second nozzle out of the heat exchanger.

The two media can flow in a heat exchanger or tube bundle heat exchanger in the same axial direction of the heat exchanger (DC) or one of the two media in the opposite direction to the other medium (countercurrent) within the heat exchanger. The temperature profile of the heat exchange of the media in the countercurrent and direct current is different and therefore leads to a different high mean logarithmic temperature difference between the two media. The amount of heat transferred between the two media is therefore different for both circuits, i. Countercurrent or DC circuit, different sizes.

The performance of the heat exchanger or shell-and-tube heat exchanger can be changed by fouling (deposits or contaminants within the heating surface tubes) or other influences with the operating time of the shell-and-tube heat exchanger, resulting in a need for control intervention. At the same time there is often the need to adjust the amount of heat to be transferred or the medium outlet temperatures to the desired operating load. For the regulation of the medium outlet temperatures and thus the thermal performance of the tube bundle heat exchanger is often a bypass control, consisting of a bypass line and a three-way mixing valve, that is a controlled three-way valve used. In this case, a part of the medium stream is taken from the main stream before being introduced into the tube bundle heat exchanger and guided or bypassed around the tube bundle heat exchanger. The reduced flow rate of a medium reduces the heat transfer and influences the average logarithmic temperature difference via the changed medium outlet temperature. However, the achievable with this bypass arrangement control range or control intervention is relatively small.

The object of the present invention is to provide a tube bundle heat exchanger with a bypass system, in which the aforementioned disadvantages are avoided or in which the outlet temperatures of the media and the amount of heat to be transferred in a very wide range is regulated. The above object is achieved with respect to the tube bundle heat exchanger by the entirety of the features of claim 1.

Advantageous embodiments of the invention can be found in the dependent claims.

The solution according to the invention provides a shell-and-tube heat exchanger which has the following advantages:

A shell-and-tube heat exchanger with a wide control range is made available, allowing for better control of tube bundle heat exchangers at the cold end of a heat recovery line.

In an advantageous embodiment, the controllable three-way valve is arranged with respect to the cooling medium flow in the discharge side of the tube bundle heat exchanger. The advantage of this arrangement is the exact controllability of the medium outlet temperature. In a further advantageous embodiment, the other three-way valve is formed as a changeover next to a regulated three-way valve. With the three-way valve designed as a reversing valve, the complete cooling medium flow can be clearly directed into the front or rear end of the jacket space or out of the front or rear end of the jacket space and thus a direct or countercurrent flow of the cooling medium to the first medium flow in the jacket space can be achieved.

It is expedient to arrange the three-way valve designed as a reversing valve with respect to the cooling medium flow in the inlet side of the tube bundle heat exchanger.

In an advantageous embodiment of the invention, in addition to the one regulated three-way valve, the other three-way valves also a regulated three-way valve. In this case, control technology can be controlled, which works as a switching valve of both three-way valves.

In a particularly advantageous manner, a flow measuring device is arranged within the bypass line. By means of this flow measuring device (s) For example, the partial flow rates within the bypass line can be precisely recorded and thus act as controlled variables on the control process and the regulated three-way valves.

Conveniently, the nozzle at the rear end of the pressure jacket and / or the nozzle at the front end of the pressure jacket in the direction of the longitudinal axis L of the tube bundle heat exchanger seen are each gleichauf. This results in a short path when flowing through the jacket space in the case of bypassing a partial mass flow of the cooling medium.

Furthermore, an advantageous embodiment of the invention, that the nozzle at the rear end of the pressure jacket and / or the nozzle at the front end of the pressure jacket relative to a lying perpendicular to the longitudinal axis L of the tube bundle heat exchanger level E lie on the latter in each case at an arbitrary angle , As a result, the resistance or the pressure loss of the bypassing partial flow of the cooling medium flow can be reduced or kept small.

Embodiments of the invention with reference to the drawings and the description are explained in more detail below.

It shows:

1 shows a schematic longitudinal section through a tube bundle heat exchanger, in which the cooling medium is passed in countercurrent through the heat exchanger,

FIG. 2 as in FIG. 1, but with a partial flow of the cooling medium flow being guided through the second bypass line,

3 shows a longitudinal section through a tube bundle heat exchanger shown schematically, in which the cooling medium is passed through the heat exchanger in cocurrent, FIG. 4 as in FIG. 3, but with a partial stream of the cooling medium stream being branched off before being passed through the medium of the tube bundle heat exchanger and being supplied to the discharge line, FIG.

5 shows an alternative embodiment to FIG. 2,

Fig. 6 shows a cross section through the tube bundle heat exchanger shown schematically at the level of the nozzle and according to section A-A in Figure 1.

1 shows a tube bundle heat exchanger 1 shown schematically in longitudinal section. Such tube bundle heat exchanger 1 are used in numerous process engineering systems, such. As gasification plants, thermal and catalytic crackers, steam reforming plants, etc., required, in which a process gas, an exhaust gas or the like. Is produced. The tube bundle heat exchanger 1 is generally used for cooling the aforementioned hot gas or a first medium stream 7, which is introduced through a pipe, not shown, in the pipe inlet chamber 9 of the tube bundle heat exchanger 1 and passed from here through a plurality of straight Heizflächenrohren 2 , then collected in the tube outlet chamber 10 of the tube bundle heat exchanger 1 and discharged by means not shown line from the tube bundle heat exchanger 1. The Heizflächenrohre 2, takes place through which an indirect heat exchange with the Heizflächenrohre 2 surrounding cooling medium 8, are each spaced from each other between two tube plates 3, 4 and with these firm and gas-tight - usually welded - connected.

The entire Heizflächenrohre 2 are covered by a jacket 5 forming a pressure jacket 6. In each case at the two ends of the pressure jacket 6, two nozzles for the inlet and outlet of the cooling medium flow 8 in and out of the shell space 5. The better assignment because here is the adjacent to the tube outlet chamber 10 end of the pressure jacket 6 as the rear end 15th and the end of the pressure jacket 6 adjoining the tube inlet chamber 9 is referred to as the front end 16. According to the invention two nozzles 1 1, 12 at the rear End 15 and two ports 13, 14 arranged at the front end 16, wherein the respective first port 11, 13 at the rear and at the front end 15, 16 for the supply of the cooling medium flow 8 in the shell space 5 and the respective second port 12, 14 am rear and at the front end 15, 16 for the discharge of the cooling medium flow 8 from the shell space 5 is used. According to the invention, the two ports 11, 13 for the supply of the cooling medium flow 8 are each connected to a first and second bypass line 21 a, 21 b, both bypass lines 21 a, 21 b lead to a first three-way valve 19 and are each connected to this. As a third line, the feed line 17 is connected to the three-way valve 19, through which the cooling medium flow m ₀ 8 the tube bundle heat exchanger 1 is supplied.

On the outflow side of the tube bundle heat exchanger 1, the two connecting pieces 12, 14 are each connected to a third and fourth bypass line 22a, 22b, whereby both bypass lines 22a, 22b lead to a second three-way valve 20 and respectively to this for the discharge of the cooling medium flow 8 are connected. As a third line, the drain line 18 is connected to the three-way valve 20, through which the Kϋhlmediumstrom m ₀ 8 is discharged from the tube bundle heat exchanger 1. According to the invention, one of the two three-way valves 19, 20 is designed to be adjustable.

Figures 1 and 2 show circuits of the tube bundle heat exchanger 1 according to the invention, in which the cooling medium flow 8 flows through the heat exchanger in countercurrent to the first medium flow 7. Figures 1 and 2 show thereby preferred variants, which provides a three-way valve in the second three-way valve 20 in the discharge line 18 and the first three-way valve 19 in the supply line 17 designed as a change-over valve three-way valve. According to FIG. 1, the three-way valve 19 designed as a reversing valve is controlled in such a way that the inflow of the cooling medium flow 8 through the feed line 17 and the first bypass line 21 a is conducted into the rear end 15 of the jacket space 5 and the three-way valve 20 is controlled such that the complete supplied mass flow m _{0 of} the cooling medium flow 8 passed through the jacket space 5 and is discharged through the third bypass line 22 a and the drain line 18. FIG. 2 shows no change with respect to the circuit of FIG. 1 with regard to the three-way valve 19 configured as a reversing valve, that is, the inlet of the cooling medium flow 8 takes place in the ^

rear end 15 of Mαntelrαumes 5, but now the three-way valve 20 is controlled such that a partial flow m _{2 of} the complete mass flow supplied m _{0 of} the cooling medium flow 8 through the fourth bypass line 22 b and the remaining partial flow m, passed through the shell space 5 and through the third bypass line 22a and both partial flows m, and m _{2 is derived} jointly through the drain line 18. Trained as a switching valve three-way valve 19 is a controlled guide member and passes the supplied cooling medium flow 8 to one of the two existing outputs, as there are the bypass lines 21 a and 21 b.

Figures 3 and 4 show circuits of the tube bundle heat exchanger 1 according to the invention, in which the cooling medium stream 8 flows through the tube bundle heat exchanger 1 in direct current to the first medium flow 7, ie both medium streams 7, 8 have the same direction within the tube bundle heat exchanger 1. Figures 3 and 4 show as before in Figures 1 and 2 preferred variants, which provides a three-way valve in the second three-way valve 20 in the discharge line 18 and the first three-way valve 19 in the supply line 17 designed as a three-way valve. In contrast to FIG. 1, the three-way valve 19 designed as a reversing valve 19 is controlled in such a way that the inflow of the cooling medium flow 8 is conducted through the second bypass line 21b into the front end 16 of the jacket space 5 and the three-way valve 20 is controlled in such a way that the complete supply is effected Mass flow m _{0 of} the cooling medium flow 8 passed through the shell space 5 and then through the fourth bypass line 22 b and through the drain line 18 downstream of the three-way valve 20 is derived. FIG. 4 shows no change with regard to the three-way valve 19 designed as a reversing valve with respect to the circuit of FIG. 3, ie the inflow of the cooling medium flow 8 takes place in the front end 16 of the shell space 5, but now the three-way valve 20 is regulated in such a way that a partial flow m _{2 of} the complete mass flow supplied m _{0 of} the cooling medium flow 8 through the third bypass line 22a between pipe 14 and three-way valve 20 and the remaining partial flow (Ti ₁ through the shell space 5 and the fourth bypass line 22b and passed both streams Pn ₁ and m ₂ together through the drain line 18 is derived. _Q

With the shown in the figures 1 to 4 circuits, it is possible to operate a tube bundle heat exchanger 1 in a very wide control range, since the amount of heat to be transferred or the medium outlet temperatures by changing the flow direction of one of the two media of Gleichin Countercurrent or vice versa can be changed and the other by the regulated three-way valve, the cooling medium flows controlled on the shell space 5 and the bypass line (s) 21 a, 21 b, 22 a, 22 b divided and thus very differentiated regulated the amount of heat to be transferred or the medium outlet temperatures can or can.

In addition to the preferred circuit variants shown in FIGS. 1 to 4, the first three-way valve 19, ie the three-way valve located in the feed line 17, can be designed as a regulated three-way valve and the second three-way valve 20, ie the three-way valve located in the drain line 18, as a three-way valve designed as a reversing valve be formed. FIG. 5 shows this variant, in which the three-way valve 19 regulates the mass flow m _{0 of} the coolant stream 8 flowing through the inlet line 17 by supplying a partial mass flow ITi ₁ through the first bypass line 21a to the jacket space 5 and a partial mass flow m ₂ through the second bypass line 21 b and thus on the jacket space 5 of the tube bundle heat exchanger 1 over and in the front end 16 of the shell space 5 passes. The complete mass flow m ₀ then exits from the tube bundle heat exchanger 1 under the appropriate position of the three-way valve 20 designed as a changeover valve through the third bypass line 22 a and the drain line 18. An advantage of the circuit according to FIG. 5 is that the regulated three-way valve 19 is arranged in the inlet and thus in the cold region of the cooling medium flow 8. This can be advantageous over arrangements in which cooling medium flows 8 emerge very strongly heated at the outlet, since thereby the contact of the regulated three-way valve 19 with the strongly heated cooling medium flow 8 is avoided. In contrast to the arrangements according to FIGS. 1 to 4, the three-way valve 20 embodied as a changeover valve takes up the discharged cooling medium flow 8 in one of the two existing inputs, as there are the bypass lines 22a and 22b. _G

Instead of a switching valve designed as a three-way valve, a further controlled three-way valve can be used, which would mean that both three-way valves 19, 20 are formed regulated. In such a case, however, it makes sense that one of the two controlled three-way valves 19, 20 takes over the function of a pure change-over valve.

According to the figures 1 to 5 are the nozzle 11, 12 at the rear end 15 of the pressure jacket 6 and the nozzle 13, 14 at the front end 16 of the pressure jacket 6 in the direction of the longitudinal axis L of the tube bundle heat exchanger 1, each equal. It is also possible, the respective stub 11, 12 at the rear end 15 and / or the respective stub 13, 14 at the front end 16 in the direction of the longitudinal axis L of the tube bundle heat exchanger 1 to arrange offset.

While in the figures 1 to 5, the nozzle 1 1, 12 at the rear end 15 and the sockets 13, 14 are arranged at the front end 16, at least in the schematic representation in each case opposite, that is. FIG. 6 shows a further possibility in which the connecting pieces 11, 12 are at 45 ° to each other on a plane E which is perpendicular to the longitudinal axis L of the tube bundle heat exchanger 1. This angle between the two nozzles can be designed as desired and depends inter alia on the narrowness of the passages between the Heizflächenrohren 2 within the jacket space 5 from. If the passages are very narrow, one will rather choose a smaller angle between the two ports 11, 12 in order to allow a relatively resistance-free flow and exit for a partial mass flow of the cooling medium flow 8 intended for the bypass line 22b. The above also applies to the nozzle 13, 14 at the front end 16 of the pressure jacket. 6

In order to be able to accomplish the regulation of the mass flows m ₀ or Pn ₁ and m _{2 of} the cooling medium flow 8 through the three-way valve 19, 20 through the jacket space 5 and optionally through the bypass lines 21 a, 21 b, 22 a, 22 b, among others Figures 1 to 5 by way of example in the Bypassieitungen 21 b, 22 b flow measuring devices 23, 24 are arranged. The supplied in the feed line 17 total mass flow m _{0 of} the cooling medium flow 8 is known on the system side ^

and can or must be used for a control-side division into the two partial mass flows ITi ₁ and ITi ₂ accordingly.

LIST OF REFERENCE NUMBERS

1 tube bundle heat exchanger

2 heating surface pipe

3 tube plate, input side

4 tube plate, output side

5 cloak room

6 pressure jacket

7 First medium flow

8 cooling medium flow

9 tube inlet chamber

10 tube outlet chamber

11 First connection at the rear end of the pressure jacket

12 Second connection at the rear end of the pressure jacket

13 First nozzle at the front end of the pressure jacket

14 Second connection at the front end of the pressure jacket

15 Rear end of the pressure jacket

16 Front end of the pressure jacket

17 supply line

18 drain line

19 First three-way valve

20 Second Three-Way Valve 21a First Bypass Line 21b Second Bypass Line 22a Third Bypass Line 22b Fourth bypass line

23 Flow measuring device

24 flow measuring device

Claims

 Pαtentα nsprϋche

Shell-and-tube heat exchangers with heating surface tubes (2), the ends of which are in tube plates

(3, 4) and one surrounding the Heizflächenrohre (2) and a

Sheath space (5) forming the pressure jacket (6), wherein a cooling medium flow (8) for cooling a guided through the Heizflächenrohre (2) first

Medium flow (7) through the jacket space (5) can be conducted, with at least one tube inlet chamber (9), from which the first medium flow

(7) is introduced into the individual Heizflächenrohre (2) and at least one

Pipe outlet chamber (10) in which the through the Heizflächenrohre (2) passed through the first medium flow (7) is collected and discharged, with two nozzles (1 1, 12) for the inlet and outlet of the cooling medium flow (8), the on the Pipe outlet chamber (10) adjacent rear end (15) of the

Pressure jacket (6) are arranged, with two nozzles (13, 14) for the inlet and outlet of the cooling medium flow (8), at the front of the pipe inlet chamber (9) adjacent the end (16)

Pressure jacket (6) are arranged, with a feed line (17) and a first three-way valve arranged thereon

(19), from which a first bypass line (21a) with the first port (11) at the rear end (15) of the pressure jacket (6) and a second bypass line

(21 b) with the first port (13) at the front end (16) of the pressure jacket

(6) is connected, and with a drain line (18) and a second arranged thereon

Three-way valve (20), from which a third bypass line (22 a) with the second

Stub (14) at the front end (16) of the pressure jacket (6) and a fourth

Bypass line (22b) with the second port (12) at the rear end (15) of

Pressure jacket (6) is connected, wherein one of the two three-way valves (19, 20) is formed adjustable and this the cooling medium flow m ₀ (8) through the jacket space (5) or as regulated

Partial mass flows m "m _{2 of} the cooling medium flow m ₀ (8) through the shell space

(5) and through the bypass line (s) (21 a, 21 b, 22 a, 22 b) passes and by means of the further three-way valve (19, 20) of the cooling medium flow (8) in DC or in countercurrent to the first medium flow (7) through the Mαntelrαum (5) durchleitbαr.

2. Rohrbündel-Wärmetαuscher according to claim 1, characterized in that the controllable three-way valve (19, 20) with respect to the cooling medium flow (8) in the discharge side of the tube bundle heat exchanger 1 is arranged.

3. tube bundle heat exchanger according to claim 1, characterized in that in addition to the one regulated three-way valve (19, 20), the further three-way valves (19, 20) is designed as a changeover valve.

4. tube bundle heat exchanger according to claim 3, characterized in that the switching valve designed as a three-way valve with respect to the cooling medium flow (8) in the inlet side of the tube bundle heat exchanger (1) is arranged.

5. tube bundle heat exchanger according to claim 1, characterized in that in addition to the one regulated three-way valve (19, 20) the further three-way valves (19, 20) is also a controlled three-way valve.

6. tube bundle heat exchanger according to claim 1, characterized in that within the bypass line (21 a, 21 b, 22 a, 22 b) a flow measuring device (23, 24) is arranged.

7. tube bundle heat exchanger according to claim 1, characterized in that the connecting pieces (11, 12) at the rear end (15) of the pressure jacket (6) and / or the nozzle (13, 14) at the front end (16) of the pressure jacket ( 6) in the direction of the longitudinal axis (L) of the tube bundle heat exchanger (1) each lie gleichauf.

8. tube bundle heat exchanger according to claim 1 or 8, characterized in that the connecting pieces (1 1, 12) at the rear end (15) of the pressure jacket (6) and / or the connecting pieces (13, 14) at the front end (16) of the pressure jacket (6) based on lie perpendicular to the longitudinal axis (L) of the tube bundle heat exchanger (1) plane (E) on this each at an arbitrary angle to each other.