Damper for a high pressure chamber of a variable valve train module

What is claimed is: 1. A variable valve train module, comprising: a driver configured to transfer motion from a cam which rotates on a camshaft; a pump which is configured to be driven by the driver; a hydraulic control unit that controls an engine valve, comprising: a high pressure chamber containing hydraulic fluid which is selectively pressurized by the pump, a control valve which is configured to depressurize the high pressure chamber, and a damper which increases an effective volume of the high pressure chamber when a pressure in the high pressure chamber exceeds a threshold value, and wherein the damper includes a guide, a piston slidably received in the guide, and a spring which biases the piston toward a closed position relative to the guide. 2. The variable valve train module of claim 1 , wherein the damper is fluidly connected to the high pressure chamber by an orifice which supplies the hydraulic fluid to the damper. 3. The variable valve train module of claim 2 , wherein the hydraulic fluid is configured to exert a force on the piston to move the piston to an open position relative to the guide when the force exceeds a force of the spring. 4. The variable valve train module of claim 3 , wherein an open space is formed when the piston is moved to the open position, and wherein the open space receives the hydraulic fluid. 5. The variable valve train module of claim 2 , wherein the orifice is fluidly connected to the damper by an inlet channel. 6. The variable valve train module of claim 5 , wherein the orifice includes a diameter within 25% of 1 mm and the inlet channel includes a length within 25% of 2-3 mm. 7. The variable valve train module of claim 1 , wherein the guide includes a first hollow portion and a second hollow portion which is wider than the first hollow portion such that a support surface is formed at a juncture between the first hollow portion and the second hollow portion. 8. The variable valve train module of claim 7 , wherein the piston includes a first portion and a second portion which is wider than the first portion such that a contact surface is formed, and the contact surface abuts the support surface when the damper is in the closed position. 9. The variable valve train module of claim 8 , wherein the damper is fluidly connected to the high pressure chamber such that the hydraulic fluid is configured to exert a force on the first portion of the piston, the force moves the piston to an open position relative to the guide when the pressure in the high pressure chamber is greater than the threshold value, and the contact surface is moved away from the support surface when the piston is moved to the open position. 10. The variable valve train module of claim 9 , wherein the force of the hydraulic fluid on the piston acts in an opposite direction of the biasing of the spring. 11. The variable valve train module of claim 8 , wherein the piston includes a resilient element which acts as a buffer between the contact surface and the support surface when the piston is in the closed position relative to the guide. 12. The variable valve train module of claim 11 , wherein the resilient element is an o-ring. 13. The variable valve train module of claim 1 , further including a retaining cap which positions the spring relative to the guide and the piston. 14. The variable valve train module of claim 1 , wherein the control valve selectively connects the high pressure chamber to an intermediate chamber. 15. The variable valve train module of claim 14 , wherein the intermediate chamber includes a hydraulic accumulator. 16. A variable valve train module, comprising: a drive element configured to be driven by a cam which rotates on a camshaft; a pump which is driven by the drive element; a hydraulic control unit configured to control an engine valve, comprising: a high pressure chamber containing hydraulic fluid which is selectively pressurized by the pump, a control valve which is configured to depressurize the high pressure chamber, and a damper which is configured to increase an effective volume of the high pressure chamber when a pressure in the high pressure chamber exceeds a threshold value, wherein the damper includes a guide, a piston slidably received in the guide, and a spring which biases the piston toward a closed position relative to the guide, wherein the guide includes a first hollow portion and a second hollow portion which is wider than the first hollow portion such that a support surface is formed at a juncture between the first hollow portion and the second hollow portion, and wherein the piston includes a first portion and a second portion which is wider than the first portion such that a contact surface is formed, and the contact surface abuts the support surface when the damper is in the closed position.