DMA De-Superheater Instruction Manual by RMC Process Controls & Filtration, LLC.

Instruction Manual Form 5296 April 2001

Design DMA and DMA/AF

Design DMA and DMA/AF Mechanically Atomized Desuperheaters Contents Introduction

............................... Scope of Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Principle of Operation Installation

1 1 1 2

.................... 2

................................. 3

Maintenance

............................... 6 Servicing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

Parts Ordering . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

7 W6298 / IL

Introduction

Figure 1. Design DMA/AF Mechanically Atomized Desuperheater

Scope of Manual This instruction manual includes installation, maintenance, and operation information for the Design DMA and DMA/AF mechanically atomized desuperheaters.

nozzle and 10:1 with the AF nozzle). These ruggedly constructed devices are capable of maintaining final temperatures to within 6 to 8_C (10 to 15_F) of saturation.

Only personnel qualified through training or experience should install, operate, and maintain a Design DMA and DMA/AF desuperheater. If you have any questions about these instructions, contact your Fisher sales office before proceeding.

The desuperheaters come with either a standard fixed orifice type spray nozzle or the AF nozzle, which can give greater turndown with its variable geometry design. Multiple nozzle units are available with the AF nozzle for higher spraywater quantity applications.

Desuperheaters of the mechanical-atomizing type are generally used for applications with near-constant loads. The Design DMA and DMA/AF mechanically atomized desuperheaters (figure 1) were designed for these applications as well as those requiring moderate turndown ratios (that is, up to 3:1 with the standard

D101617X012

Description

The Design DMA and DMA/AF desuperheaters can be installed in pipe headers, elbows, tees, and other similar pipe fittings. They can be installed directly into the header through an opening as small as a standard 3-inch ANSI raised-face flange connection. Installation causes no appreciable pressure loss due to obstruction of flow. The use of multiple AF nozzles allows for optimum turndown ratio, spraywater quantity, and serviceability.

Design DMA and DMA/AF Table 1. Specifications

Steam Line Sizes J 6 to 60-inch Steam Line Connection Sizes J 3, J 4, and J 6-inch ANSI Class J 150, J 300, J 600, J 900, J 1500, and J 2500 raised-face flange Spraywater Connection Sizes J 1, J 1-1/2, and J 2-inch ANSI Class J 150, J 300, J 600, J 900, J 1500, and J 2500 raised-face flange Maximum Inlet Pressures(1) Consistent with applicable Class 150, 300, 600, 900, 1500, or 2500 pressure-temperature ratings per ASME B16.34.

Inherent Rangeability(2) Design DMA: Up to 3:1 Design DMA/AF: Up to 10:1 Spraywater Pressure Required 3.5 to 35 bar (50 to 500 psi) greater than steam line pressure Minimum Steam Velocity Design DMA: 9.1 m/s (30 feet per second) Design DMA/AF: 6.1 m/s (20 feet per second) Maximum Unit Cv (for Spraywater Flow) Design DMA: 3.8 Design DMA/AF: 15.0 Construction Materials Valve Body: J Carbon steel, J Chrome-moly alloy steel (F11, F22, and F91), or J 300 series stainless steel Nozzle: J 303 or J 316 stainless steel

1. Do not exceed the pressure or temperature limits in this instruction manual, nor any applicable code or standard limitations. 2. Ratio of maximum to minimum controllable Cv.

Specifications Specifications for the Design DMA and DMA/AF desuperheaters are shown in table 1.

Principle of Operation The Design DMA and DMA/AF desuperheaters reduce steam temperatures by introducing cooling water directly in contact with the hot steam. By regulating the water quantity, the degree of cooling can be controlled and final temperature maintained. The rate of vaporization, and/or cooling, is a function of droplet size, distribution, mass flow, and temperature. Steam velocity is critical and should be maintained at 6.1 to 9.1 meters per second (20 to 30 feet per second) as the minimum. Actual minimum steam velocity will vary by application. As steam velocity increases, a longer distance is required to achieve homogeneous mixing and complete vaporization. In both Design DMA desuperheater nozzle styles, the spraywater quantity is controlled by an external control valve which responds to signals received from the temperature control system. The water passes through the main tube of the desuperheater to the spray nozzle and discharges into the steam line as a fine spray (see figure 2.

W6310-1

Figure 2. Detail of Design DMA/AF Desuperheater

Design DMA and DMA/AF STEM

Installation

BODY SPRING

WARNING PLUG

SPRAY ANNULUS A7191 / IL

NUT PIN SWIRL CHAMBER

WATER INJECTION HOLES (COMPOUND ANGLED ORIFICES)

Figure 3. Design DMA Desuperheater AF Nozzle

The particular nozzle in the sprayhead is tailored to meet a specific set of operating conditions. The nozzle design optimizes the spraywater particle size so that when combined with reasonably high steam velocity it results in complete vaporization and excellent temperature control. The Design DMA desuperheater uses a fixed geometry nozzle, while the Design DMA/AF desuperheater uses a variable geometry AF nozzle. In the AF nozzle design (see figure 3), water enters the swirl chamber via compound angled orifices, thus creating a rotational flow stream. This flow stream is further accelerated as it is forced up and out through the spray annulus. The cone-shaped plug varies the geometry of the spray annulus using a force balance principle between water pressure and the preload exerted by a helical spring. This variable geometry design sprays a thin hollow cone over a wide range of flow rates, which results in excellent temperature control over a wide range of operating conditions.

Personal injury or equipment damage caused by sudden release of pressure may result if the desuperheater is installed where service conditions could exceed the limits given in table 1 or on the nameplate. To avoid such injury or damage, provide a relief valve for over-pressure protection as required by government or accepted industry codes and good engineering practices.

CAUTION

When ordered, the desuperheater configuration and construction materials were selected to meet particular pressure, temperature, pressure drop, and fluid conditions. Do not apply any other conditions to the desuperheater without first contacting your Fisher sales office.

Design DMA and DMA/AF 1. Mount the Design DMA or DMA/AF desuperheater in a ’’Tee’’ piece at the desired location in the pipe, in accordance with standard piping practice. The nozzle should be positioned at approximately the center of the pipe (see figure 4 for the proper ‘‘T’’ length dimension). 2. Clean and flush out the cooling water line before connecting to the desuperheater. Use only clean sources of cooling water. Use of clean water decreases wear and prevents clogging of the nozzle by solid particles.

Note Fisher recommends installation of a strainer and an isolating valve on the water line between the desuperheater and the water control valve. Failure to do so may result in clogging of the desuperheater by solid particles, thus hampering temperature control of the steam. 3. A straight run of pipe is required downstream of the desuperheater to ensure complete vaporization of

cooling water. Consult the desuperheater certified drawing for the required distance of straight pipe. 4. The temperature sensor should be mounted according to the manufacturer’s instructions. Minimum distance to the sensor is 30 feet (9.1 meters) downstream of the desuperheater. This distance changes with higher velocity steam flow and the percentage of spraywater required. Consult the desuperheater certified drawing for this distance. 5. There should be no branching out from the steam line to divide the steam flow between the temperature sensor and the desuperheater. 6. A typical installation is illustrated in figure 5. A temperature sensor (TE) measures changes in temperature and transmits a signal to a remote temperature-indicating controller (TC) or distributed control system (DCS). The output signal from the controller is sent to the positioner on the spraywater control valve. The positioner output signal is piped to the actuator. The actuator strokes the stem/plug of the spraywater control valve, as required, to supply the required cooling water to the desuperheater to maintain temperature setpoint.

Design DMA and DMA/AF

203 (8.0)

MOUNTING FLANGE (ANSI RF FLANGE (WATER) SAME SIZE AND PRESSURE CLASS AS BODY FLANGE)

DIMENSION A mm

Inches

360

14.19

448

17.63

524

mm (INCH)

20.63

D (Nominal Pipe Size), Inches

T mm

Inches

6(1) 8 10 12 14 16 18

273 248 216 279 267 241 216

10.75 9.75 8.50 11.00 10.50 9.50 8.50

20 22 24 >24

267 241 216 216

10.50 9.50 8.50 8.50

1. Design DMA only. Note: For 6-inch and 8-inch (Design DMA/AF only) mounting flange, add 69.6 mm (2.75 inches) to the A and T dimensions. For ANSI Class 2500 mounting, consult your Fisher sales office. Refer to the certified drawing to verify the inside-diameter requirements of mounting for Design DMA/AF.

A5094-1 / IL

INSTALLATION CONFIGURATION (1 GASKET REQUIRED) NOTE: ALL FLANGE BOLT HOLES STRADDLE STEAM PIPE CENTERLINE

Figure 4. Design DMA and DMA/AF Dimensions

FISHER DESIGN DMA DESUPERHEATER

B2317 / IL

Figure 5. Typical Design DMA or DMA/AF Desuperheater Installation

Design DMA and DMA/AF Table 2. Troubleshooting Guide Problem

Corrective Action