SU1078916A1 - Automatic apparatus for utilization of condensate of vacuum evaporation units in production of photographic celatine - Google Patents

Abstract

1. AUTOMATIC RECYCLING DEVICE FOR CONDENSATE vacuum evaporators IN MANUFACTURE OF PHOTOGRAPHIC gelatin, comprising serially connected in the condensate line Kontsentratomer, the controller and the first switching valve whose input is connected to the condensate line and outputs connected to lines contaminated and clean condensate Due to the fact that, in order to increase the degree of utilization of condensate, it additionally contains a second switching valve installed on the condensate line, a tank and a pump contaminated condensate sensors, sensors and the first level regulator in the contaminated condensate tank, position sensors of the first switching valve and a pump control unit for the contaminated condensate, the output of the second switching valve connected to the condensate discharge line, the contaminated condensate line The condensate is connected to the contaminated condensate supply pump, the outputs of the level sensors in the contaminated condensate tank are connected to the first level controller The outputs of which are connected to the control unit of the pump for the supply of contaminated condensate and, through the sensors of the position of the first switching valve, are connected to the control input of the second switching class pan. 2. The device according to claim 1, wherein it further comprises a tank and a pump for supplying clean condensate, sensors and a second LEVEL controller in the tank for clean condensate and a control unit for the pump for feeding clean condensate, This line of pure condensate is connected to the tank of pure condensate, whose output is connected to the pump of pure condensate, the outputs of the level sensors in the tank of pure condensate are connected to the second level controller, the output of which is connected to the first level controller.

Description

The invention relates to automatic devices for controlling technological processes and can be used in chemical industry in automating the production of photographic gelatin. A device for condensate utilization is known comprising a condensate line and a switching valve. The closest in technical essence is an automatic device for the utilization of condensate from vacuum evaporators in the production of photographic gelatin, containing a series-connected condensate meter on the condensate line, a regulator and the first switching valve, whose input is connected to the condensate line, and the outputs are connected ly contaminated and clean condensate. A common disadvantage of the known devices is that they only allow to use clean condensate and only by returning it to CHP, whereas in the production of photographic gelatin there are p processes (bone fat, polishing meal, etc.). tea water with an initial temperature of 60-75 ° C and to improve the technical and economic indicators of production, clean condensate with the same temperature is preferable to use these processes directly as hot water or as heat carrier In the corresponding heat exchangers, the absence of as such the disposal of hazardous condensate predetermines the loss of gelatin with condensate, which reduces the technical and economic indicators of production. In addition, during valve switching, the contaminated condensate is mixed with clean and the latter cannot be reused in the technological process due to the danger of escape of heat exchanging equipment and other equipment, and the absence of condensate accumulators or accumulators allows to re-use condensate in the process of arr in vacuum-evaporator units (ILC). The aim of the invention is to increase the degree of condensate utilization. The goal is achieved by the fact that the known automatic device containing a series-connected concentrator on the condensate line, a regulator and a first switching valve, the inlet of which is connected to the condensate line, and the outputs are connected to the contaminated and clean condensate lines, additionally contains a second switching a valve installed in the condensate line, a tank and a pump for supplying contaminated condensate, sensors and the first level regulator in the tank of contaminated condensate, position sensors of the first A switching valve and a pump control unit for contaminated condensate, while the output of the second switching valve is connected to the condensate discharge line, the contaminated condensate line is connected to the contaminated condensate tank, the output of which is connected to the contaminated condensate supply pump, level sensors outputs contaminated condensate is connected to the first level controller, the outputs of which are connected to the control unit of the pump for contaminated condensate and through the sensors of the position of the first reklyuchayuschego valve - to the control input of the second switching valve. In addition, the automatic device further comprises a tank and a pump for supplying clean condensate, sensors and a second level regulator in the tank for pure condensate and a control unit for the pump for supplying clean condensate, while the pure condensate is connected to the tank of pure condensate, the output of which is connected to the pump for supplying clean condensate The outputs of the level sensors in the tank of pure condensate are connected to the second level controller, the output of which is connected to the first level controller. The ingestion of gelatin into the condensate of the IVU occurs when there are inaccuracies in the management and, in the transient processes of the operation of the IVU, and is of a periodic nature. This circumstance, after installing an appropriate IVA condensate analyzer for the content of gelatin in it, as well as other additional devices for switching, blocking and signaling, during those periods of operation of the IVU, when the condensate does not contain gelatin, reuse it for the technological needs of production, and periods of operation of the IVU, when the condensate contains gelatin, feed it for re-evaporation, which, given the high cost of photographic gelatin, will increase the technical and economic performance ate production. Fig. 1 shows a functional diagram of this automatic device using a contaminated condensate tank; Fig. 2 is a functional diagram of an automatic device using contaminated and clean condensate tanks. The device contains concentrator 1 (Fig. 1), condensate line 2, concentration controller 3, first switching valve 4, pure condensate line 5, second switching valve 6, contaminated condensate capacity 7, sensors 8, 9 and 10, respectively, emergency , the upper and lower levels in the tank of contaminated condensate, the first level regulator 1t, the line 12 of the contaminated condensate, the sensors (switches) 13 and 14 of the first switching valve, the sensors 15, 16 and 17 of the light signalization, the sound sensor 18, the pump 19 loading feed Known condensate, contaminant pump control unit (actuator) 20. Condensate discharge line 21. Another version of the automatic device includes a pump 22 (FIG. 2) for supplying pure condensate, a capacity 23 of pure condensate, and sensors 24, 25 and 26, respectively, emergency, upper and lower levels in the capacity of pure condensate. , the second level regulator 27, light signal sensors 28, 29, and 30, the sound alarm sensor 31, and the unit 32 for controlling the pump for supplying clean condensate. The device (figure 1) works as follows. At the moment of time corresponding to the absence of gelatin in the condensate of the inlet, the device elements are in the following state: the valve 6 is given a pneumatic signal in the form of compressed air pressure, in which the valve 6 is in the position corresponding to the flow of condensate to the valve 4 entrance. 1, for example, an automatic refractometer, continuously measures the concentration of gelatin in the IVU condensate. In the absence of gelatin in it, the controller 3 commands the valve 4, which is automatically installed in the position of supplying condensate to the line 5 of pure condensate for recycling in other production processes. In this position of valve A, the contacts of the limit switch 13 included in the valve control circuit 6 are in the open state, and the contacts of the limit switch 14 are closed, which corresponds to the above position of the valve 6. When gelatin appears in the condensate, the regulator 3 gives a command to the valve 4, which begins to move to the position of supplying condensate to the tank 7 — to the line 12. At the moment the valve stem 4 begins to move to a new position, the contacts of the end switch 14 open, which causes the valve to shift and 6 to the condensate supply line 21 to discharge to sewers. This eliminates the possibility of contaminated condensate entering the pure condensate line. In addition, such a valve switching circuit ensures that valve 4 is disconnected from the condensate line (line lines to valves 6 and 4) for short-term (less than the time required for valve 4 to move from one position to another) changes in the composition of the condensate, which also prevents contaminated condensate from entering the pure condensate line and vice versa. If during the switching time of valve 4 the composition of the condensate did not change (gelatin is still present there, then after setting the valve to the position of supplying condensate to the container 7, the contacts of the limit switch 13 are closed. At the same time, the valve 6 switches to the position of supply of the condensate to the valve 4 entrance and then the capacitance 7. The empty state of the capacitance 7 is signaled by the sensor (lamp) 17. when the condensate of the sensor 10 reaches the lower level, the lamp 17 goes out and the pump 19 control circuit is prepared to be turned on When the condensate reaches the top level sensor 9, the alarm lamp 16 triggers and with the guaranteed availability of free and prepared for vacuuming of the inlet, the magnetic actuator 20 automatically starts and the pump 19 switches on the contaminated condensate for re-evaporation. the capacity 7 is reduced, when the lower value of which is reached, the pump is automatically switched off and the corresponding / jg switching of the light sensors takes place ignalizatsii. In the absence of a free IGU, the pump does not turn on and the Sensor 18 is activated, which indicates the need for urgent preparation of IGU for condensate discharge. With a further increase in the level and when the condensate of the sensor 8 reaches the emergency level, the sensors 15 and 18 are triggered and the normally closed contact of the first level regulator 11, which is included in the valve control circuit 6, is opened, which leads to the subsequent switching of the valve 6 to the condensate supply to the cannabisation. Further ingress of contaminated condensate v. Capacity 7 will be prevented by switching valve 6 to the position of supplying condensate to the sewage system until the pump 19 is turned on and the level of condensate in the tank falls below the installation level of sensor 9 of the upper level, then In the event of contaminated condensate, valve 6 will no longer switch to the position of supplying condensate to the sewage system, and contaminated condensate will again begin to flow into tank 7.

When the gelatin is extinguished in the condensate, the IVU regulator 3 commands the valve 4, which begins to move to the position of supplying the condensate to the pure condensate line. At the moment when the valve stem 4 begins to move to a new position, the contact of the limit switch 13 opens and the valve 6 is set to the position of supplying condensate to the sewage system if it is already in this position. This eliminates the possibility of pure condensate entering the tank 7. If during the switching time of valve 4 the composition of the condensate did not change (there is still no gelatin in it), then after the valve is placed in the position of supplying condensate to the clean condensate line, the switch 14 closes and switching valve 6 to the position of supplying condensate to the inlet of valve 4 and further to the line of pure condensate.

In this way, the selective nature of the valve switching is realized, ensuring the following algorithm of operation: valve 6 is in the condensate discharge position 20 25

and while the valve 4 is in intermediate positions, the valve 6 is persected to the position of condensate discharge into the sewage system, which is necessary to eliminate the possibility of contaminated condensate entering the line of pure condensate and pure condensate in the contaminated condensate tank and mixing them with each other.

The switching of valves 4 and 6 can also be controlled manually by remote from the switchboard, instrumentation and automation by means of bypass guides. The pump 19 can be turned on and off manually using the control key and local and remote buttons. Thus, the device provides automatic control of switching valves 4 and 6 and filling the tank 7, signaling the set values of the condensate in the tank, protecting, blocking and controlling the pump: ohm 19 supplying contaminated condensate to re-evaporation; and

Manual remote control of valves 4, 6 and pump t9.

The device (Fig. 2) works in a similar way and the above listed functions allow automated sewage in the absence of both compressed air supply and power supply of the device, which is dictated by the technological protection and blocking requirements. The 6 g valve switches to the position of condensate supply to the sewage system during overflow tanks, which eliminates the overflow of contaminated condensate and contributes to the observance of sufficiently rigid sanitary and technological norms of production; switching of valve 6 to the position of supplying condensate to the input of valve 4 and further occurs only after installation of valve 4 in one of the extreme positions, and at the moments of the start of switching

Cache control of filling the tank 23 with clean condensate, signaling the level setpoints in the tank, protecting, blocking and controlling the pump 22 for supplying clean condensate for secondary use. The economic effect is achieved by reducing the loss of gelatin with condensate and eliminating the discharge of water into the sewage system, and eliminating the cost of wastewater treatment.

FIG. /

Claims (2)

1. AUTOMATIC DEVICE FOR DISPOSAL OF VACUUM-EVAPORATION CONDENSATE CONDENSATE IN THE PRODUCTION OF PHOTOGRAPHIC GELTINE; comprising a series-connected concentrator on the condensate line, a regulator and a first switching valve, the input of which is connected to the condensate line, and the outputs are connected to the contaminated and clean condensate lines, characterized in that, in order to increase the degree of condensate utilization, it further comprises a second switching valve installed on the condensate line, a tank and a pump for supplying contaminated condensate, sensors and a first level regulator in a tank of contaminated condensate, position sensors of the first a switching valve and a contaminated condensate pump control unit, wherein the output of the second switching valve is connected to a condensate discharge line, the contaminated condensate line is connected to the contaminated condensate tank, the output of which is connected to the contaminated condensate pump, the outputs of the level sensors in the contaminated condensate tank are connected to the first level regulator, the outputs of which are connected to the control unit for the pump for supplying contaminated condensate and through the position sensors of the first switching th valve - with the control input of the second switching valve. 2. The device according to claim 1, characterized in that it further comprises a tank and a pump for supplying pure condensate, sensors and a second level controller · in the tank for pure condensate and a control unit for the pump for supplying pure condensate, while the line for pure condensate is connected to of pure condensate tank, • the output of which is connected to the pump for supplying pure condensate, the outputs of the level sensors in the tank of pure condensate are connected to the second level controller, the output of which is connected to the first level controller. SU „„ 1078916