SE530611C2 - Exothermic energy recovery in the production of formaldehyde - Google Patents

Description

530 B'I'l Exhaust gases from the process are recycled to some extent while the remaining part is incinerated.

The exothermic reactions in the formaldehyde plant, including the combustion process, thus generate large amounts of excess friend. This heat can produce quite large amounts of high pressure water vapor. It is known to use this water vapor for heating in, for example, industrial processes.

It would be advantageous if the pressure from the exothermic energy from the factory could be used more directly in the process and thus reduce the need for an external energy source.

SUMMARY OF THE INVENTION The object of the present invention is to radically reduce the need for an external source of pressure to effect pressurization of the process. The invention thus relates to a process as well as an apparatus for producing formaldehyde where the formaldehyde is produced in a reactor and where exotic energy is a result of the process. The reactor is pressurized by means of a compressor and exothermic energy from the process is used to supply energy to the compressor. This enables an increase in pressure in the reactor with a minimum of necessary power supply from an external source.

DETAILED DESCRIPTION OF THE INVENTION The reactor is pressurized by means of a compressor and the exothermic energy from the process is used to supply energy to the compressor. This enables an increase in pressure in the reactor with a minimum of necessary power supply from an external source. According to a preferred embodiment of the invention, the method further comprises the step of burning exhaust gases and that this exhaust combustion results in exothermic energy which is used to supply energy to the compressor. The exothermic reaction results in an increase in the fl volume and this increase in the används volume is used to drive a turbine.

According to an embodiment of the invention, the turbine drives a generator. The generator can then drive the compressor. The turbine speed can be regulated by means of a sidestream. Alternatively, the 530 E11 turbine speed can be regulated by means of a pinch valve. The power from the generator to the compressor can then be conducted in a known manner.

According to an embodiment of the invention, the turbine drives a generator. The generator can then drive the compressor. The turbine speed can be regulated by means of a sidestream. Alternatively, the turbine speed can be regulated by means of a throttle valve. The power from the generator to the compressor can then be conducted in a known manner.

According to another embodiment of the invention, the turbine drives the compressor via a shaft.

The turbine speed is then regulated by means of a sidestream. Alternatively, the turbine speed can be regulated by means of a throttle valve. The turbine speed can also be regulated by means of a throttle valve and a sidestream. Although the increase in the volume of fate resulting from the exothermic energy is used in the process of the present invention, according to one embodiment of the invention it is an object that the exothermic energy is also used to produce water vapor.

The formaldehyde is then produced in an apparatus comprising a reactor where exothermic energy is a result of the process. The reactor is pressurized by means of a compressor and the exothermic energy from the process is used to supply energy to the compressor. Pressure cooling is achieved in the reactor with a minimum of necessary power supply from an external source.

According to a preferred embodiment of the invention, the apparatus further comprises a device for burning exhaust gases and that the exhaust gas combustion contributes to the exotic energy used to supply energy to the compressor. In an even more preferred embodiment of the invention, the dry combustion device stands for exhaust gases for the exothermic energy used to supply energy to the compressor. The exotic reaction results in an increase in the fl volume and this fl volume is used to drive a turbine. 530 According to one embodiment of the invention, the turbine drives a generator. This generator can then drive the compressor. The turbine speed can be regulated by means of a sidestream.

Alternatively, the turbine speed can be regulated by means of a throttle valve. The power from the generator to the compressor can then be conducted in a known manner.

According to another embodiment of the invention, the turbine drives the compressor via a shaft.

The turbine speed is then regulated by means of a sidestream. Alternatively, the turbine speed is regulated by means of a throttle valve. The turbine speed can also be regulated by means of a throttle valve and a sidestream. Although part of the increase in the volume of fate resulting from the exothermic energy is used in the process of the present invention, according to an embodiment of the invention it is an object that the exothermic energy is also used to generate water vapor.

According to the present invention, the power from the turbine feeds the compressor either directly via a shaft or via a generator / motor device. In either case, it may be necessary to control the speed of the turbine to protect it from reaching a critical speed. This can be accomplished in known ways, of which the following non-limiting examples are given; - It is possible to regulate the tangential speed of the turbine via a throttle valve and / or a sidestream device. A sidestream device is then suitably placed in a grouping so that both the turbine and the compressor are provided with sidestreams. This will facilitate the start and close of the process.

- It is also possible to use a generator as a brake to continuously regulate the tangential speed of the turbine. The generated force can of course be used in steps both inside and outside the process. A resistor battery can be used as a backup in cases where energy from the generator for various reasons is higher than the consumption speed. 530 BH - It is alternatively possible to use a mechanical brake to protect the turbine against exceeding safe tangential speed. However, this should be considered as a safety device and is not so suitable for continuous operation.

- It is also possible to use any combination of the control methods mentioned above.

In one embodiment of the process, formaldehyde age is provided with recirculation så so that a semi-closed loop is formed. It is then advantageous to place a blow-out valve after the circulation för to facilitate the initiation of the process. A throttle valve in the circulation stream is also advantageous. The main products from the reactor are formaldehyde and exhaust gas. Parts of the exhaust gas are part of the recirculation while the remaining part of the exhaust gas is fed to an emission control system.

Fresh air is fed into the recirculation loop, preferably before the circulation spout. The fresh air is supplied by means of a compressor according to the present invention. This compressor pressurizes the process. To facilitate the start and shutdown of the process, the compressor is equipped with an overflow valve that allows the compressor to reach a suitable working speed in a controlled manner. As mentioned above, the compressor is driven directly or indirectly by means of a turbine. The gas fate that feeds this turbine is obtained with the help of exothermic energy at one or more stages of the process. The outlet from the turbine is then preferably fed through a steam generator where additional amounts of energy can be extracted. The steam generator can also be fitted with an overflow valve which is suitably regulated by the temperature on the pressure side of the turbine. The turbine is suitably equipped with an overflow valve which is used during start-up and shut-down. This overflow valve can also be used to control the tangential speed of the turbine. The overflow flow valve can be regulated by the pressure in the circulation loop of the formaldehyde reactor. In addition, a fresh air stream can be taken from the pressure side of the compressor and fed via a valve, regulated by the Og levels after the compressor in the formaldehyde reactor circulation loop and into the turbine overflow valve.

SEG B'l'l The invention is not limited to the embodiments shown as these can be varied in different ways within the scope of the invention.

Claims (1)

A process for producing formaldehyde, wherein the formaldehyde is produced in a reactor and exothermic energy is a result of the process characterized in that the reactor is pressurized by means of a compressor and that the exothermic energy from the process is used to supply energy to the compressor thereby enabling a pressure increase in the reactor with a minimum of necessary energy supply from an external source. A method according to claim 1, characterized in that the process further comprises the step of combustion of exhaust gases, that this exhaust combustion results in the exothermic energy used to supply energy to the compressor. Process according to Claim 1 or 2, characterized in that the exothermic reaction results in an increase in lethal volume and that this lethal volume increase is used to drive a turbine. Method according to claim 3, characterized in that the turbine drives a generator. Method according to claim 4, characterized in that the generator drives the compressor. Method according to claim 3, characterized in that the turbine drives the compressor via a shaft. Method according to one of Claims 3 to 6, characterized in that the turbine speed is regulated by means of a sidestream. Method according to one of Claims 3 to 6, characterized in that the turbine speed is regulated by means of a throttle valve. Method according to one of Claims 3 to 6, characterized in that the turbine speed is regulated by means of a throttle valve and a side flow. 530 5 '|' l 10. Process according to any one of claims 1-9, characterized in that the exotic energy is also used to produce steam.