Chemische Verarbeitung

big chemical plant
chemical beakers
aerial view of straws

Die Branche der chemischen Verarbeitung hat auf fast alle produzierten Güter, die wir konsumieren, einen Einfluss.

It is a very large market that encompasses many segments such as basic chemicals (petrochemicals, plastics, rubber, dyes and pigments, printing inks), specialty chemicals (paint, adhesives, flavors), agricultural chemicals, and consumer products.

TVBS liefert der chemisch verarbeitenden Industrie schon seit langem Vakuumpumpen, Verdrängungsgebläse und kundenspezifische Lösungen. Unsere PD-Plus-Verdrängungsgebläsen gehören zu den wenigen in der Industrie, die für die Benutzung mit speziellen chemischen Gasen mit unterschiedlichen Eigenschaften entwickelt wurden, wie beispielsweise entflammbare, korrosive, gefährliche oder durch hohen Druck und hohe Temperaturen gekennzeichnete Gase.

Die Vakuumpumpen der Kinney-Reihe werden seit mehr als 100 Jahren in Betrieben der chemischen Verarbeitung eingesetzt. Diese Vakuumpumpen sind für ihre Langlebigkeit und Robustheit unter rauen Bedingungen bekannt. Dank unserer Erfahrung und praktischen Fachkenntnis können wir unsere Kunden bei der Entwicklung von technischen Systemen unterstützen.


chemical plant with billowing smoke

Low-pressure steam exhaust from industrial operations such as evaporators or cookers is usually vented to the atmosphere or condensed in a cooling tower.

Simultaneously, other plant operations may require intermediate-pressure steam at 20 to 25 PSIG. Instead of letting down high-pressure steam across a throttling valve to meet these needs, low-pressure waste steam can be mechanically compressed or boosted to a higher pressure so that it can be reused.

Vapor recompression involves incorporating a blower to increase the temperature of the latent heat in steam to render it usable for process duties. Recompression with a blower requires only a small fraction of the energy required to raise an equivalent amount of steam in a boiler.

Consider a petrochemical plant that vents 8 PSIG steam to the atmosphere. At the same time, a process imposes a continuous requirement on the boiler for approximately 5,300 pounds per hour (lb/hr) of 23 PSIG steam. A Tuthill M-D Pneumatics™ 9012 PD Plus blower operating at 2100 RPM, 143 BHP (107 kW) accomplishes this task. In addition, approximately 0.6 GPM of 80° F condensate is injected into the blower to eliminate superheating of the steam, resulting in an additional 297 lb/hr of steam to the heating process.

Solvent Handling

chemical plant with big silos

Vacuum systems are used to pump solvent vapors in many chemical and pharmaceutical applications wherever excess solvents must be removed such as processes involving drying, distilling, chemical reactions, synthesis of compounds, separation and purification, cleaning, etc.

Many organic solvents need to be recovered either due to their toxicity, flammability, or environmental impact and dry vacuum pumping systems provide a green vehicle for doing so. Dry vacuum systems have no internal sealing liquid that could be contaminated by incoming solvents or contaminate the outgoing solvents that need to be recovered. The solvent vapors are passed through the dry vacuum system and then usually condensed at the exhaust that provides a closed loop for containing and recovery with no contamination. A typical system would consist of a dry vacuum pump with a shell and tube condenser at the exhaust. If higher capacities are required a booster/dry pump combination could be used.

Tuthill offers rotary screw dry vacuum pumps to select from depending upon the application:

  • SDV series horizontal flow rotary screw dry pump with variable pitch rotors for reduced power consumption and lower exhaust temperatures and C-Face motor are standard. PTFE internal coating is optional.
  • KDP series horizontal flow rotary screw dry pump with constant pitch rotors for simplicity and reliability, and PFA coated internals are standard.

Liquid ring and dry vacuum pumps are normally used for solvent handling applications but the dry vacuum systems offer the advantage of reduced power consumption, decreased coolant usage (lower bhp/acfm and cooling water flow), smaller footprint, and better control of maintaining the solvent as a vapor while passing through the pump so that condensing occurs where desired. Dry pumps are also more easily controlled by using variable frequency drives (VFD) for process pressure control compared to liquid ring pumps where the minimum rpm is determined by the collapsing of the fluid ring. Dry vacuum systems are also capable of handling volatile organic solvents such as methylene chloride, acetone, or methanol where the higher vapor pressures could cause problems for a liquid ring pump. Maintaining a leak tight system that avoids the entrance of air to avoid flammable mixtures or the leaking of process fluid to the environment is more easily handled with a dry vacuum system. Because of the elevated discharge temperatures of the dry vacuum pump the solvent's auto-ignition temperature should always be greater than the dry pump's maximum discharge temperature which normally occurs at the lower inlet pressure range. Tuthill can provide complete dry vacuum systems consisting of dry boosters if necessary backed by any of its three series of rotary screw dry pumps equipped with inert gas purges or with knock out traps, after condensers, protective instrumentation and electrical controls if desired to suit solvent recovery processes.