Screw compressor configured to compress a process gas and dampen pulsation waves

The invention claimed is: 1. A screw compressor configured to compress a process gas, comprising: a compressor housing having a suction port and a pressure port, wherein the process gas to be compressed is fed to the compressor housing via the suction port and compressed process gas is discharged from the compressor housing via the pressure port; screw rotors mounted in the compressor housing and forming a rotor pair configured to compress the process gas; a pipe bend, which conducts the compressed process gas from the compressor housing in a direction of a silencer, comprising: a first connecting piece for fastening the pipe bend to the pressure port of the compressor housing at an inlet-side portion of the pipe bend, wherein the first connecting piece has a substantially planar surface; a second connecting piece for fastening the pipe bend to the silencer, an outlet-side portion of the pipe bend; and a flow channel extending between the first connecting piece and the second connecting piece, which is defined by an inner wall of the pipe bend; an insert on the inlet-side portion of the pipe bend that projects into the flow channel of the pipe bend at least in portions, wherein the insert comprises: a collar that projects out of the pipe bend on the inlet-side portion, and which delimits an introduction depth of the insert into the pipe bend on the inlet-side portion and a portion of the insert projects into the flow channel of the pipe bend, wherein the collar forms a first planar surface that faces the pressure port; and a second planar surface that faces the first connecting piece, the portion of the insert that projects into the flow channel extends longitudinally from the planar surface, wherein the portion of the insert that projects into the flow channel extends longitudinally from the planar surface and does not extend beyond the planar surface; an inner wall of the insert defines a nozzle facing the pressure port between the insert and the collar, and an outer wall of the insert projects into the flow channel of the pipe bend and a portion of the inner wall of the pipe bend enclosing the outer wall on an outside delimits a space acting as a resonator, which is coupled to the flow channel of the pipe bend. 2. The screw compressor according to claim 1 , wherein the flow channel of the pipe bend is substantially curved by 90° between the inlet-side portion and the outlet-side portion. 3. The screw compressor according to claim 2 , wherein the inner wall of the pipe bend on the inlet-side portion is contoured cylindrically, and the outer wall of the portion of the insert projecting into the flow channel of the pipe bend is contoured cylindrically. 4. The screw compressor according to claim 1 , wherein the space acting as the resonator is an annular space. 5. The screw compressor according to claim 1 , wherein the space forms a λ/4 resonator. 6. The screw compressor according to claim 5 , wherein a length of the portion of the insert projecting into the pipe bend on the inlet-side portion and thus the length of the space acting as the resonator is dependent on an expulsion frequency of the compressed process gas on the pressure port and on a sound velocity of the compressed process gas. 7. The screw compressor according to claim 6 , wherein the expulsion frequency of the compressed process gas is dependent on a rotational speed of the screw rotors and the sound velocity of the compressed process gas on a temperature of the compressed process gas. 8. The screw compressor according to claim 1 , wherein a length of a portion of the insert projecting into the pipe bend on the inlet-side portion is selected so that the space forms a λ/4 resonator. 9. The screw compressor according to claim 1 , wherein the collar of the insert is clamped between the pressure port of the compressor housing and the first connecting piece of the pipe bend.