JPS626082B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a steam accumulator, and particularly to a steam accumulator for recovering and utilizing thermal energy of low pressure steam released from an autoclave or the like.

Conventional steam accumulators take in excess steam, or high pressure steam, from the boiler and store its thermal energy as high pressure hot water.In the event of an overload or emergency, when the steam supplied from the boiler alone is insufficient. It was designed to release steam and replenish it. Therefore, conventional steam accumulators exclusively take in high-pressure steam and
It was made to emit steam, and could not handle low pressure steam of 10 kg/cm ² or less.

However, the steam emitted from steam-using machines, especially those used at steam pressures of 5 to 10 kg/ ^cm2 , such as autoclaves, has enormous thermal energy even at low pressures, and currently, Some of the water is used to heat boiler feed water using a regular heat exchanger, or for space heating in the winter, but most of it is simply thrown away. This is because, as mentioned above, a steam accumulator that could collect and utilize low-pressure steam intensively was not available, but partial recovery results in poor recovery efficiency, from the point of view of effective energy use. It must be said that the situation is extremely worrying.

The present invention has been developed based on the above-mentioned viewpoints, and its purpose is to recover a large amount of low-pressure steam released from steam-using machines such as autoclaves and to make effective use of it. steam·
The goal is to provide an accumulator.

Therefore, the gist of the present invention is to provide a steam blowing device for taking the released steam from an autoclave or the like into the main body of a steam accumulator and blowing it into the water stored in the main body. At the same time, an economizer pipe consisting of a heat exchange serpentine pipe is installed to preheat boiler feed water or heat water for other purposes by using hot water heated by blowing steam. . In such a case, the water passed through the economizer pipe will be heated more stably with less fluctuation than when using a normal heat exchanger,
On the other hand, since a certain amount of heat is always removed from the hot water in the accumulator by the water in the economizer pipe, the thermal energy of the steam blown into the tank can be smoothly absorbed and recovered. Furthermore, the steam generated in the steam accumulator can be stably supplied to chemical reaction tanks and other low-pressure steam-using machines after drying, and the thermal energy of the steam released from autoclaves etc. is wasted. It will be possible to use it without any restrictions.

If the pressure of steam released from an autoclave etc. drops to such a level that it becomes difficult to feed it into the steam accumulator using just that pressure, a pre-installed steam jet device will be used to , it is recommended to entrain it into high-pressure steam from a boiler and feed it.

Hereinafter, the configuration of the present invention will be explained in detail using the drawings.

FIG. 1 is a flowchart showing an embodiment of a piping system when installing a steam accumulator according to the present invention, and FIG. 2 is a longitudinal sectional view showing an embodiment of the steam accumulator according to the present invention. FIG. 3 is its XX sectional view.

In Figure 1, 1 is a boiler, 2 is a header, 3A to 3F are autoclaves, 4A to 4F are on-off valves provided at the inlets of each autoclave, 5
A to 5F and 6A to 6F are on-off valves installed at the outlet of each autoclave to switch the flow path of released steam, and 7A to 7F are on-off valves 5A.
8 is a steam accumulator according to the present invention, 8a is a steam blowing device in the accumulator 8, and 8b is a heat exchange serpentine pipe (economizer pipe) in the accumulator 8. , 9 is a check valve, 10 is a steam jet, 11 is an on-off regulator for the steam jet 10, 12 is an on-off valve, 13 and 14 are dryers and other machines using low pressure steam, 15 is a water tank,
16 is a pump, 17 is an economizer attached to the flue of boiler 1, and 18 is an autoclave 3A.
Cooling recovery cylinder for steam released from 3F to 3F, 1
9 is its cooling water supply source, and 20 is a water receiving tank.

The high pressure steam generated in the boiler 1 is pressure-adjusted and distributed by the header 2, and then supplied to the autoclaves 3A to 3F. A predetermined vapor pressure is maintained within the autoclave for a certain period of time, and this vapor pressure is usually 5 to 10 kg/cm ² .
After a predetermined pressure holding time has elapsed, the steam inside the autoclave is released, but normally the valve 5A is closed.
5F are open, and the discharged steam is blown through the check valve 9 into the steam accumulator 8 according to the invention. The steam pressure inside the accumulator 8 is normally maintained at 4 to 6 Kg/cm ² , and if the steam pressure released from the autoclave is, for example, 7 Kg/cm ² or more, which is sufficiently high compared to the internal pressure of the accumulator, the steam will flow through the check valve. It is sent smoothly using only 9. However, when the discharged vapor pressure reaches around 6 kg/cm ² and becomes approximately equal to the internal pressure of the accumulator, the blowing speed rapidly decreases or stops. Then,
In such a case, the regulator 11 is used to operate the steam jet device 10 so that high pressure steam from the header 2 is used to blow. The steam jet device 10 is a device that jets high-pressure steam in parallel to a low-pressure steam outlet, causes the low-pressure steam to be engulfed in high-pressure steam, and conveys the steam together, and is commonly referred to as a thermo compressor and is commercially available. It is. The regulator 11 that controls the opening and closing of the steam jet device 10 is configured, for example, by a circuit that performs PID operation, and uses the autoclave discharged steam and the accumulator internal pressure as data, for example, when the discharged steam pressure is 6.5.
The steam jet is operated when the pressure is below Kg/ ^cm2 , and closed when the internal pressure of the accumulator is above 5.5Kg/ ^cm2 . That is, the steam jet device is opened and activated when the discharge steam pressure of the autoclave is 6.5 kg/cm ² or less and the accumulator internal pressure is 5.5 kg/cm ² or less. Since the internal pressure of the accumulator is suppressed to about 6 kg/cm ² , if the released steam pressure is 6.5 kg/cm ² or more, steam is sent through the check valve 9 and there is no need to use the steam jet device 10. do not have. When the internal pressure of the accumulator reaches 5.5 kg/cm ² or more, the supply of steam to the accumulator is stopped, valves 5A to 5F are closed and valves 6A to 6F are opened to guide the released steam to the cooling recovery cylinder 18. The regulators 7A to 7F are circuits that perform, for example, a P operation or a PD operation, and switch between the valves 5A to 5F and the valves 6A to 6F according to the discharge steam pressure or the discharge steam flow rate. Of course, the regulator 11 and regulators 7A to 7F
The pressure setting value is selected depending on the type of steam-using machine, the capacity of the accumulator, the internal pressure, etc.

Since the water in the accumulator 8 is turned into hot water by the steam blown in from the steam blowing device 8a, this thermal energy is utilized for preheating the boiler feed water in this accumulator. That is, boiler water is supplied from the water supply tank 15 to the heat exchange flexible pipe 8b in the accumulator 8 by the pump 16, and is preheated to about 150°C. Unlike ordinary heat exchangers, heat exchange is performed using a sufficient amount of hot water as a heat medium, so preheating of boiler feed water can be performed stably at high temperatures as described above. The boiler feed water heated in this way is further heated to about 175°C by an economizer 17 using the boiler flue, etc.
supplied to Furthermore, although the water in the water supply tank 15 is normally about 18°C, if the condensate from the cooling recovery tube 18 is stored in the water receiving tank 20 and guided to the water supply tank 15 again, the heat recovery rate can be improved. will further improve.

Note that the steam in the accumulator 8 is removed by a dryer,
It is used in machines 13 and 14 that use low-pressure steam, such as chemical reaction tanks.

Next, one embodiment of the steam accumulator according to the present invention will be described using FIGS. 2 and 3. In the figure, 21 is the main body of the accumulator, 22 is the steam distribution pipe, 23 and 23 are the steam blowing nozzles attached to the steam distribution pipe 22, and 24 and 24 are the circulation cylinders respectively attached around the steam blowing nozzles.
25 is a rail supporting the steam distribution pipe 22, 26 is a steam inlet stop valve, 27 is an inlet check valve, 28 is a heat exchange corrugated pipe (economizer pipe), 29, 29 is a corrugated tube support frame, 30 is a steam outlet header, 31 is an outlet stop valve, 32 is an outlet check valve, 33 is a water supply pipe to the accumulator, 34 is a water level gauge, 35 is a pressure gauge, 36 is a safety valve, 37 is a drain stop valve, and 38 is a fixed frame that supports the accumulator body. , 39, 39 are sliding frames, and 9 and 10 are a check valve and a steam jet, respectively, which perform the same functions as those shown in FIG. Although not shown in the figure, the outer surface of the main body portion 21 is covered with a heat insulating material.

Steam released from a steam-using machine such as an autoclave passes through the check valve 9 or the steam jet 10, passes through the check valve 27 and the stop valve 26, and is sent into the distribution pipe 22, where it is blown into the distribution pipe 22. Nozzle 23,2
3 is injected into the water inside the accumulator. The steam injection nozzles 23, 23 are known nozzles commonly used in steam accumulators. Circulation tubes 24, 24 are attached around the nozzle,
Uniformly heats water by promoting water convection. The heat exchange serpentine pipe 28 branches into two parts inside the accumulator, and each has a U-shaped bolt 29a, 29a.
It is attached to the support frames 29, 29 by using a screwdriver, and is arranged in a meandering manner over substantially the entire length of the accumulator. Water such as boiler feed water is introduced into the pipe from the inlet 28a of the flexible pipe 28, is sufficiently preheated with hot water inside the accumulator, and then sent out from the outlet 28b.

The steam in the accumulator is supplied to a low-pressure steam-using machine via a header 30 as required.

To give an example of the specifications of the main parts of this accumulator, the total length of the main body 21 is 27,140 mm, its diameter is 2,800 mm, and the length of the heat exchange corrugated pipe from the right end to the left end in the figure is 24,740 mm. (Therefore, the total length of the pipe that branches into two and makes 5 reciprocations is 247,400mm), the type of pipe diameter is 2l/2B, and the material is STPG38 (JIS-G-
3454), the number of steam blowing nozzles 23, 23 installed is 10. With such specifications, approximately 3× per day
It is possible to recover and utilize 10 ⁷ Kcal of heat.

The structure of the steam accumulator according to the present invention is not limited to the above-mentioned embodiments. For example, by appropriately extending or shortening the overall length of the heat exchange coiled pipe in the accumulator, boiler feed water preheating and low pressure It is also possible to change the ratio of the amount of steam supplied to steam-using machinery, or to use the high-efficiency steam blowing device disclosed in Utility Model Registration Application No. 76709 of 1974, for example, as the steam blowing device. It is possible.

Furthermore, it goes without saying that the water to be passed through the flexible pipe is not limited to boiler supply water, but may also be water for other purposes such as heating.

Since the present invention is constructed as described above, it is possible to provide an excellent steam accumulator that can efficiently recover and utilize the thermal energy of relatively low-pressure steam released from an autoclave or the like. It is something that

[Brief explanation of the drawing]

FIG. 1 is a flowchart showing an embodiment of a piping system when installing a steam accumulator according to the present invention, and FIG. 2 is a longitudinal sectional view showing an embodiment of the steam accumulator according to the present invention. FIG. 3 is its XX sectional view. 1...Boiler, 3A, 3B, 3C, 3D, 3
E, 3F...Autoclave, 8...Steam
Accumulator, 9...Check valve, 10...Steam jet, 21...Steam/accumulator main body, 22...Steam distribution pipe, 23, 23...Steam blowing nozzle, 28...Heat exchange flexible pipe .

Claims (1)

[Claims] 1. In a steam accumulator that stores thermal energy as pressurized hot water, inside its main body,
A steam accumulator, characterized in that it is provided with a steam blowing device consisting of a steam distribution pipe and a steam blowing nozzle, a heat exchange flexible pipe, and a steam jet device is provided at the steam intake port of the steam distribution pipe.