DE1018439B - Process for temperature control of steam-heated heat exchangers of all kinds - Google Patents

Description

GERMAN

In order to achieve the most economical utilization of the amount of heat supplied to a heating system, it is above all necessary to adjust the temperature of the heat exchangers assigned to the heating system to regulate. In general, this is achieved in that a arranged in the steam supply line Control valve of a thermostat influenced by a temperature of the heat exchanger is monitored. The arrangement works in such a way that when the setpoint value is reached, the the temperature to be controlled, the steam valve is closed and when the temperature falls below the setpoint value the steam valve is opened. The steam valve is therefore as long as the target temperature has not yet been reached is open, so that the steam from the heat exchanger during this operating state Steam supply line is led via the heat exchanger to the condensate line.

Such a temperature control of a heat exchanger now has a number of disadvantages, The relevant experts have been trying to eliminate them for years. To satisfactory results However, one had not yet come here. Apart from the fact that in the case of the aforementioned Heating system in addition to the steam valve also a steam reducing valve and a less reliable one working condensate trap come into use, and Such systems tend to have steam hammer on the water side serious disadvantage that the amount of heat supplied in no way economically ! m heat exchanger is used. There is much to be said here that the temperature of the discharged Condensate is still relatively high compared to the steam temperature.

There are probably control methods for steam-heated preheaters with one arranged in the condensate drain Known control valve, but only from the flow temperature, i.e. from one temperature is monitored, through which an economic utilization of the heat energy supplied does not take place.

In the case of a known milk heater, too, one lying in the condensate line is monitored Control valve only depends on the milk temperature. Accordingly, this control arrangement is also used no favorable utilization of the thermal energy supplied to the milk heater is achieved.

There is also known a method for regulating a steam-heated unit provided with a condensate drain, in which a control valve built into the steam line and a control element that is directly connected to this and built into the condensate line are influenced by a heat sensor, which in one in two Temperature control method
steam-heated heat exchangers of all kinds

Applicant:

W. Balz & Son K.-G.,
Heilbronn / Neckar, Koepffstr. 5

Spaces subdivided housing of the condensate drain is arranged, with an adjustment of the one Control organ also an adjustment of the other control organ takes place in the same sense.

In this control method, there are two control valves are used, both of which are influenced by a heat sensor located in the condensate line and one of which is in the steam line and the other in the condensate line. Except These two control valves are also provided with a specially designed heat sensor housing, which, in divided into two rooms, arranged between the outlet of a drying cylinder and a condensate valve and receives the temperature sensor.

Such a control system accordingly has in particular the disadvantage that their expense for the condensate drain control is large and therefore uneconomical. The invention relates to a method for Temperature control of steam-heated heat exchangers of all types, in which the condensate drain is dependent is monitored by the temperature of the condensate. In particular, it makes itself the task of creating a To create control arrangement, through which with high operational and control security and with the lowest possible

709 758/233

3 4

Expenditure on resources a better utilization of the one in the secondary line of the heat exchanger

Available thermal energy than previously achieved sensors, the entire automatic

will. According to the invention, this is achieved by only seeing temperature control of the heat exchanger

that the condensate outflow is achieved by influencing the condensate outflow, in addition to the condensate,

temperature still of at least one further control 5 whereby it is no longer necessary that the pressure

size is regulated in such a way that only after reaching and the temperature of the supplied steam

the adjusted setpoint of the condensate temperature must be regulated. So it is through the

the other controlled variable in the condensate drain arrangement of a control valve in the condensate line

can intervene regulating the controlling sense. management and through its control in dependence

Another feature of the invention is to determine the condensate temperature and at least one

that the condensate, by appropriate dimensioning of the secondary controlled variable of the heat exchanger, is the

the surface of the heat exchanger is supercooled, the advantage is that a special reduction

and only then condensate from the condensate line valve and a control valve in the steam supply

can escape when the condensate temperature underline is no longer required. Furthermore, through

is cooled, with the other controlled variable in one of the 15 the controlled subcooling of the condensate a better

Condensate drainage controlling senses can act. The heat utilization achieved at the heat exchanger.

Condensate drainage can now depend on. Furthermore, by keeping the pressure constant

of the supercooled condensate temperature and of and the temperature in the condensate drainage

Pressure or the temperature of the flow or heat quantity measurement conceivable in a simple way,

also of the difference between the flow and return 20 Fig. 1 shows a circuit diagram of a previous one

temperature of the heat exchanger can be controlled. usual control arrangement for a steam-heated

The control arrangement for the execution of the heat exchanger system; in the

Driving can be a left in the condensate drain line. Fig. 2 to 5 are exemplary embodiments of the Erringendes Have control valve represented by one of the manure of an electrical control arrangement. The temperature of the condensate was influenced by the heat sensor at 25 Condensate in the open sense and provided by the known control arrangement is in the at least one further steam line 2 connected to the main steam network 1 by another operating system size of the heat exchanger influenced sensors in a reducing valve 3 and a control solenoid valve 4, Keeping the temperature of the heat exchanger constant, the magnet 5 of which is controlled by one in the flow line 6 acting senses is monitored. The second sensor 3 ″ of the heat exchanger 7 lying thermostat 8 can in the flow of the heat exchanger and a third one controls. In the condensate discharge line 9 is a Sensors are arranged in the return. The control float trap 10.

of the heat exchanger can also additionally be through the reducing valve 3 before this

a room or outside heat sensor monitors the vapor pressure lying down, which is of the order of magnitude of 2

will. The room or 35 to 6 atmospheres, for example 0.5 atmospheres, are useful here.

Outside sensor on one of the other sensors in one. changes. While that for the temperature control of the

its setpoint adjusting sense. Heat exchanger 7 serving control valve 4 by means of

It is also conceivable to install the condensate drain thermostat 8 as a function of the flow line a pressure temperature is influenced between the control valve and the nozzle, whereby the control process staten to arrange the control valve in a 4 ° such that the control valve 4 is closed, Maintaining the condensate discharge pressure when the temperature in the flow line 6 is the one acting Affects the senses. In this way, the setpoint is exceeded and the opening is opened, with the control arrangement according to the invention both when the flow temperature is below the setpoint, the condensate temperature as well as the condensate pressure The condensate drain in the condensate line 9 held constant, so that in connection with the we- 45 is of the float of the condensate pot 10 of the control valve also monitors a faultless type of heat that when the set quantity measurement is conceivable. Levels in the condensate trap condensate is discharged,

Manostats or thermostats can be used for the sensors, regardless of the level of the condensate temperature.

be used. With an electrical control arrangement remains.

The sensors are designed as electrical sensors formed, which takes place here essentially with a heat exchanger 7 located in the condensate line interacting solenoid valve. At dnar from the thermostat 8, which depends on the in the flow Pneumatic control arrangement, pneumatic prevailing temperature conditions via the control sensor used, the supply valve 4 with a diaphragm valve to supply or shut off the steam work together. For that in the condensate line 55 causes to the heat exchanger. A scheme of Low control valve can types known per se, but condensate temperature is not used here will. It is advantageous to use it. This known control arrangement required a a multipurpose valve, the actuators of which are reducing valve 3, one of which is controlled by the thermostat 8 the associated sensors work together. ertes control valve 4 and a float trap 10,

The control arrangement according to the invention for steam 60 whereby the temperature control is essentially only heated heat exchanger is now ensured by influencing the steam supply, the known arrangements a number of advantages. In the embodiments according to Figs share. This dispenses with the use of a temperature control of the heat-unstable condensate drain. At their exchanger only by influencing the Kon point occurs a control valve, the structure of which is known to reach 65 densate drain, with the arrangement is already so extensively developed that there is no doubt - a reducing valve and a control valve in the as an extremely reliable regulating device, steam supply is dispensed with. Also occurs here can be. By controlling this at a control valve in place of the condensation trap. Control valve of a also in the condensate The control arrangement according to Fig. 2 now contains an in line lying temperature sensor and at least 70 of the condensate drain line 9 lying control valve 11,

its magnate 12 that over a. Control unit 13 from the thermostat 14 also located in the condensate line 9 is influenced. Here is also the Arrangement made so that the condensate by additional! Dimensioning of the surface of the heat exchanger 7 is hypothermic. The control process takes place in such a way that when the temperature falls below the subcooling temperature of the condensate, the control valve 11 is opened and when the subcooling temperature is exceeded is closed.

The control valve 11 is also still controlled by the thermostat 8 located in the flow line 6 influenced. When held closed by the condensate thermostat 14 solenoid valve 11, however, this has Thermostat 8 has no effect on the actuating element of the control valve 11. Only when the control valve 11 is opened by the condensate thermostat 14, the thermostat 8, if the temperature conditions are in the flow line 6, act on the control valve 11 in the regulating sense.

The embodiment according to FIG. 3 corresponds essentially to that according to FIG. The pressure element 16 is influenced by the manostat 18 located in the flow 6 and the temperature element 17 by the thermostat 14 located in the condensate line 9. The mode of operation of this control arrangement takes place in the same way as that of the arrangement according to Fig. 2. Only in this case is ^i::: ht flow temperature, but the flow pressure used for control.

According to Fig. 4, the multi-purpose valve 15 located in the condensate line 9 is provided with a pressure adjustment member 19 provided which is controlled by a manostat 21 located in the condensate discharge line 20; in this way, a constant pressure is also maintained in the condensate line. So there in the Condensate line regulates the condensate both at constant pressure and at constant pressure Temperature takes place, a heat quantity measurement can be achieved due to these conditions in that the control valve 15 is also used to control a heat meter 22. 4-5

Fig. 5 shows an arrangement in which the aforementioned influencing of a thermostat 23 by a thermostat 24 takes place. The training can be made here such that, for example a resistance of the outside thermostat 24 accordingly the outside temperature is adjusted, with a current assigned to this value causes a proportional adjustment of the setpoint in the thermostat 23.

The control arrangement according to the invention can be used wherever steam is used as a heat transfer medium serves, i.e. for cooking, heating or drying purposes, such as in distillation columns, Drying rolls of paper machines, milk heaters and the like

Claims (17)

Patent claims: 1. Process for temperature control of steam-heated heat exchangers of all types, in which the The condensate drain is monitored depending on the temperature of the condensate, characterized in that that the condensate drain apart from the condensate temperature also from at least one further controlled variable is regulated in such a way that the Condensate temperature regulating the other controlled variable in the sense of controlling the condensate drain can intervene. 2. Control method according to claim 1, characterized in that the condensate by appropriate Sizing the surface of the heat exchanger is supercooled and only then condensate can escape from the condensate line when the condensate temperature is subcooled, whereby the other controlled variable can act in a sense that blocks the condensate drain. 3. Rule method according to claims 1 and 2, characterized in that the condensate drain depending on the subcooled condensate temperature and the flow temperature of the heat exchanger being affected. 4. Control method according to claims 1 and 2, characterized in that the condensate drain depending on the subcooled condensate temperature and the flow pressure of the heat exchanger being affected. 5. Control method according to claims 1 and 2, characterized in that the condensate drain depending on the subcooled condensate temperature and the difference between the pre- and Return temperature of the heat exchanger is influenced. 6. Control method according to claims 1 and 2, characterized in that the condensate discharge pressure is kept constant. 7. control arrangement for performing the method according to claim 1, characterized in that that a control valve lying in a known manner in the condensate drain line of a heat sensor influenced by the condensate temperature in the case of subcooled condensate in the opening Sense and of at least one other, of a different operating variable of the heat exchanger influenced sensors in keeping the temperature of the heat exchanger constant Senses is monitored. 8. Control arrangement according to claim 7, characterized in that the second sensor in the lead of the heat exchanger. 9. Control arrangement according to claim 8, characterized in that a third sensor is arranged in the return. 10. Control arrangement according to claim 7, characterized in that the control of the heat exchanger also from. a RaumwämKif takes place worse. 11. Control arrangement according to claim. 7, thereby characterized in that the regulation of the heat exchanger is also of. an outside heat sensor he follows. 12. Control arrangement according to claims 7, 10 and 11, characterized in that the Raumbzw. Outside sensor acts on one of the other sensors in a sense that adjusts its setpoint. 13. Control arrangement according to claim 7, characterized in that the control valve of one Manostat is influenced in the condensate drain line between the control valve and a nozzle is arranged. 14. Control arrangement according to claims 7 and 9, characterized in that the sensor as Thermo- or manostats are designed. 15. Control arrangement according to claim 9, characterized in that the sensors are designed as electrical sensors and cooperate with a solenoid valve located in the condensate. 16. Control arrangement according to claim 9, characterized in that the sensors are pneumatic Sensors are designed and work together with a membrane valve located in the condensate line. 17. Control arrangement according to claim 7, characterized in that the control valve is designed as a multi-purpose valve, the actuators of which work together with the associated sensors. Considered publications:
German Patent Nos. 407 296, 873 929;
Swiss Patent No. 239982;
British Patent No. 590,336. 1 sheet of drawings